Mitral stenosis is a condition characterized by a narrowing of the mitral valve, which can lead to various symptoms. One common symptom is a mid-late diastolic murmur, which can be heard during a physical examination. This murmur may also be described as mid-diastolic, late-diastolic, or mid-late diastolic. Additionally, patients with chronic mitral stenosis may not experience any symptoms, and the murmur may only be detected incidentally.

A significant risk associated with mitral stenosis is the development of atrial fibrillation (AF). When AF occurs in patients with mitral stenosis, it can trigger acute pulmonary edema. This happens because the left atrium, which is responsible for pumping blood across the narrowed mitral valve into the left ventricle, needs to generate higher pressure. However, when AF occurs, the atrial contraction becomes inefficient, leading to impaired emptying of the left atrium. This, in turn, causes increased back pressure in the pulmonary circulation.

The elevated pressure in the left atrium and pulmonary circulation can result in the rupture of bronchial veins, leading to the production of pink frothy sputum. This symptom is often observed in patients with mitral stenosis who develop acute pulmonary edema.

Further Reading:

Mitral Stenosis:
– Causes: Rheumatic fever, Mucopolysaccharidoses, Carcinoid, Endocardial fibroelastosis
– Features: Mid-late diastolic murmur, loud S1, opening snap, low volume pulse, malar flush, atrial fibrillation, signs of pulmonary edema, tapping apex beat
– Features of severe mitral stenosis: Length of murmur increases, opening snap becomes closer to S2
– Investigation findings: CXR may show left atrial enlargement, echocardiography may show reduced cross-sectional area of the mitral valve

Mitral Regurgitation:
– Causes: Mitral valve prolapse, Myxomatous degeneration, Ischemic heart disease, Rheumatic fever, Connective tissue disorders, Endocarditis, Dilated cardiomyopathy
– Features: pansystolic murmur radiating to left axilla, soft S1, S3, laterally displaced apex beat with heave
– Signs of acute MR: Decompensated congestive heart failure symptoms
– Signs of chronic MR: Leg edema, fatigue, arrhythmia (atrial fibrillation)
– Investigation findings: Doppler echocardiography to detect regurgitant flow and pulmonary hypertension, ECG may show signs of LA enlargement and LV hypertrophy, CXR may show LA and LV enlargement in chronic MR and pulmonary edema in acute MR.

Femoral shaft fractures are quite common among children and have a significant impact on both the child and their family. It is important to carefully examine children with these fractures for any associated injuries, such as soft-tissue injury, head trauma, or additional fractures. In fact, up to 40% of children who experience a femoral shaft fracture due to high-energy trauma may have these associated injuries. Additionally, a thorough neurovascular examination should be conducted.

Rapidly immobilizing the limb is crucial for managing pain and limiting further blood loss from the fracture. For distal femoral shaft fractures, well-padded long leg splints with split plaster casts can be applied. However, for more proximal shaft fractures, long leg splints alone may not provide adequate control. In these cases, skin traction is a better option. Skin traction involves attaching a large foam pad to the patient’s lower leg using spray adhesive. A weight, approximately 10% of the child’s body weight, is then applied to the foam pad and allowed to hang over the foot of the bed. This constant longitudinal traction helps keep the bone fragments aligned.

When children experience severe pain, it is important to manage it aggressively yet safely. Immobilizing the fracture can provide significant relief. The Royal College of Emergency Medicine recommends other pain control measures for children, such as intranasal diamorphine (0.1 mg/kg in 0.2 ml sterile water), intravenous morphine (0.1-0.2 mg/kg), and oral analgesia (e.g., paracetamol 20 mg/kg, max 1 g, and ibuprofen 10 mg/kg, max 400 mg).

Delirium is characterized by fluctuating symptoms of disturbed consciousness that typically develop over hours to days. During the day, lucid intervals may occur, while the worst disturbances are often experienced at night. In contrast, dementia has a gradual onset and does not involve fluctuations in mental state. Stroke, on the other hand, is associated with focal neurological deficits.

Further Reading:

Delirium is an acute syndrome that causes disturbances in consciousness, attention, cognition, and perception. It is also known as an acute confusional state. The DSM-IV criteria for diagnosing delirium include recent onset of fluctuating awareness, impairment of memory and attention, and disorganized thinking. Delirium typically develops over hours to days and may be accompanied by behavioral changes, personality changes, and psychotic features. It often occurs in individuals with predisposing factors, such as advanced age or multiple comorbidities, when exposed to new precipitating factors, such as medications or infection. Symptoms of delirium fluctuate throughout the day, with lucid intervals occurring during the day and worse disturbances at night. Falling and loss of appetite are often warning signs of delirium.

Delirium can be classified into three subtypes based on the person’s symptoms. Hyperactive delirium is characterized by inappropriate behavior, hallucinations, and agitation. Restlessness and wandering are common in this subtype. Hypoactive delirium is characterized by lethargy, reduced concentration, and appetite. The person may appear quiet or withdrawn. Mixed delirium presents with signs and symptoms of both hyperactive and hypoactive subtypes.

The exact pathophysiology of delirium is not fully understood, but it is believed to involve multiple mechanisms, including cholinergic deficiency, dopaminergic excess, and inflammation. The cause of delirium is usually multifactorial, with predisposing factors and precipitating factors playing a role. Predisposing factors include older age, cognitive impairment, frailty, significant injuries, and iatrogenic events. Precipitating factors include infection, metabolic or electrolyte disturbances, cardiovascular disorders, respiratory disorders, neurological disorders, endocrine disorders, urological disorders, gastrointestinal disorders, severe uncontrolled pain, alcohol intoxication or withdrawal, medication use, and psychosocial factors.

Delirium is highly prevalent in hospital settings, affecting up to 50% of inpatients aged over 65 and occurring in 30% of people aged over 65 presenting to the emergency department. Complications of delirium include increased risk of death, high in-hospital mortality rates, higher mortality rates following hospital discharge, increased length of stay in hospital, nosocomial infections, increased risk of admission to long-term care or re-admission to hospital, increased incidence of dementia, increased risk of falls and associated injuries, pressure sores.

The most likely cause of the fainting episode in this 25-year-old third year medical student is vasovagal syncope. Vasovagal syncope is a common type of fainting that occurs in response to certain triggers, such as emotional stress, pain, or seeing blood. In this case, the prolonged delivery and emergency C-section likely triggered the patient’s vasovagal response.

The patient’s symptoms of feeling warm and sweaty before fainting are consistent with vasovagal syncope. During a vasovagal episode, there is a sudden drop in blood pressure and heart rate, leading to a temporary loss of consciousness. The absence of loss of bladder or bowel control and tongue biting further support this diagnosis.

The physical examination findings of no focal neurological deficits and a normal cardiovascular examination also align with vasovagal syncope. Additionally, the blood pressure measurements of 122/74 mmHg when lying down and 120/72 mmHg when standing suggest orthostatic hypotension, which is commonly seen in vasovagal syncope.

Further Reading:

Blackouts, also known as syncope, are defined as a spontaneous transient loss of consciousness with complete recovery. They are most commonly caused by transient inadequate cerebral blood flow, although epileptic seizures can also result in blackouts. There are several different causes of blackouts, including neurally-mediated reflex syncope (such as vasovagal syncope or fainting), orthostatic hypotension (a drop in blood pressure upon standing), cardiovascular abnormalities, and epilepsy.

When evaluating a patient with blackouts, several key investigations should be performed. These include an electrocardiogram (ECG), heart auscultation, neurological examination, vital signs assessment, lying and standing blood pressure measurements, and blood tests such as a full blood count and glucose level. Additional investigations may be necessary depending on the suspected cause, such as ultrasound or CT scans for aortic dissection or other abdominal and thoracic pathology, chest X-ray for heart failure or pneumothorax, and CT pulmonary angiography for pulmonary embolism.

During the assessment, it is important to screen for red flags and signs of any underlying serious life-threatening condition. Red flags for blackouts include ECG abnormalities, clinical signs of heart failure, a heart murmur, blackouts occurring during exertion, a family history of sudden cardiac death at a young age, an inherited cardiac condition, new or unexplained breathlessness, and blackouts in individuals over the age of 65 without a prodrome. These red flags indicate the need for urgent assessment by an appropriate specialist.

There are several serious conditions that may be suggested by certain features. For example, myocardial infarction or ischemia may be indicated by a history of coronary artery disease, preceding chest pain, and ECG signs such as ST elevation or arrhythmia. Pulmonary embolism may be suggested by dizziness, acute shortness of breath, pleuritic chest pain, and risk factors for venous thromboembolism. Aortic dissection may be indicated by chest and back pain, abnormal ECG findings, and signs of cardiac tamponade include low systolic blood pressure, elevated jugular venous pressure, and muffled heart sounds. Other conditions that may cause blackouts include severe hypoglycemia, Addisonian crisis, and electrolyte abnormalities.

Blunt abdominal trauma often results in injury to the liver and spleen, which are the two organs most commonly affected. The liver, being the largest and located in a vulnerable position, is particularly prone to injury in such cases.

Further Reading:

Abdominal trauma can be classified into two categories: blunt trauma and penetrating trauma. Blunt trauma occurs when compressive or deceleration forces are applied to the abdomen, often resulting from road traffic accidents or direct blows during sports. The spleen and liver are the organs most commonly injured in blunt abdominal trauma. On the other hand, penetrating trauma involves injuries that pierce the skin and enter the abdominal cavity, such as stabbings, gunshot wounds, or industrial accidents. The bowel and liver are the organs most commonly affected in penetrating injuries.

When it comes to imaging in blunt abdominal trauma, there are three main modalities that are commonly used: focused assessment with sonography in trauma (FAST), diagnostic peritoneal lavage (DPL), and computed tomography (CT). FAST is a non-invasive and quick method used to detect free intraperitoneal fluid, aiding in the decision on whether a laparotomy is needed. DPL is also used to detect intraperitoneal blood and can be used in both unstable blunt abdominal trauma and penetrating abdominal trauma. However, it is more invasive and time-consuming compared to FAST and has largely been replaced by it. CT, on the other hand, is the gold standard for diagnosing intra-abdominal pathology and is used in stable abdominal trauma patients. It offers high sensitivity and specificity but requires a stable and cooperative patient. It also involves radiation and may have delays in availability.

In the case of penetrating trauma, it is important to assess these injuries with the help of a surgical team. Penetrating objects should not be removed in the emergency department as they may be tamponading underlying vessels. Ideally, these injuries should be explored in the operating theater.

In summary, abdominal trauma can be classified into blunt trauma and penetrating trauma. Blunt trauma is caused by compressive or deceleration forces and commonly affects the spleen and liver. Penetrating trauma involves injuries that pierce the skin and commonly affect the bowel and liver. Imaging modalities such as FAST, DPL, and CT are used to assess and diagnose abdominal trauma, with CT being the gold standard. Penetrating injuries should be assessed by a surgical team and should ideally be explored in the operating theater.

The BTS guidelines for acute asthma in children recommend administering oral steroids early in the treatment of asthma attacks. It is advised to give a dose of 20 mg prednisolone for children aged 2–5 years and a dose of 30–40 mg for children over 5 years old. If a child is already taking maintenance steroid tablets, they should receive 2 mg/kg prednisolone, up to a maximum dose of 60 mg. If a child vomits after taking the medication, the dose of prednisolone should be repeated. In cases where a child is unable to keep down orally ingested medication, intravenous steroids should be considered. Typically, treatment for up to three days is sufficient, but the duration of the course should be adjusted based on the time needed for recovery. Tapering off the medication is not necessary unless the steroid course exceeds 14 days. For more information, refer to the BTS/SIGN Guideline on the Management of Asthma.

This explanation suggests that the patient’s symptoms are consistent with a case of travellers diarrhoea, which is in line with their medical history. GBS typically occurs within 1-3 weeks after the initial viral or bacterial infection that caused it.

Further Reading:

Campylobacter jejuni is a common cause of gastrointestinal infections, particularly travellers diarrhoea. It is a gram-negative bacterium that appears as curved rods. The infection is transmitted through the feco-oral route, often through the ingestion of contaminated meat, especially poultry. The incubation period for Campylobacter jejuni is typically 1-7 days, and the illness usually lasts for about a week.

The main symptoms of Campylobacter jejuni infection include watery, and sometimes bloody, diarrhea accompanied by abdominal cramps, fever, malaise, and headache. In some cases, complications can arise from the infection. Guillain-Barre syndrome (GBS) is one such complication that is associated with Campylobacter jejuni. Approximately 30% of GBS cases are caused by this bacterium.

When managing Campylobacter jejuni infection, conservative measures are usually sufficient, with a focus on maintaining hydration. However, in cases where symptoms are severe, such as high fever, bloody diarrhea, or high-output diarrhea, or if the person is immunocompromised, antibiotics may be necessary. NICE recommends the use of clarithromycin, administered at a dose of 250-500 mg twice daily for 5-7 days, starting within 3 days of the onset of illness.

A 7-year-old girl is brought to the emergency department after being bitten by a bee. She is experiencing swelling in her arm and difficulty breathing, which are signs of anaphylaxis. To treat this condition, the most suitable dose of adrenaline to administer to the patient is 300 micrograms (0.3ml 1 in 1,000) by intramuscular injection.

Further Reading:

Anaphylaxis is a severe and life-threatening hypersensitivity reaction that can have sudden onset and progression. It is characterized by skin or mucosal changes and can lead to life-threatening airway, breathing, or circulatory problems. Anaphylaxis can be allergic or non-allergic in nature.

In allergic anaphylaxis, there is an immediate hypersensitivity reaction where an antigen stimulates the production of IgE antibodies. These antibodies bind to mast cells and basophils. Upon re-exposure to the antigen, the IgE-covered cells release histamine and other inflammatory mediators, causing smooth muscle contraction and vasodilation.

Non-allergic anaphylaxis occurs when mast cells degrade due to a non-immune mediator. The clinical outcome is the same as in allergic anaphylaxis.

The management of anaphylaxis is the same regardless of the cause. Adrenaline is the most important drug and should be administered as soon as possible. The recommended doses for adrenaline vary based on age. Other treatments include high flow oxygen and an IV fluid challenge. Corticosteroids and chlorpheniramine are no longer recommended, while non-sedating antihistamines may be considered as third-line treatment after initial stabilization of airway, breathing, and circulation.

Common causes of anaphylaxis include food (such as nuts, which is the most common cause in children), drugs, and venom (such as wasp stings). Sometimes it can be challenging to determine if a patient had a true episode of anaphylaxis. In such cases, serum tryptase levels may be measured, as they remain elevated for up to 12 hours following an acute episode of anaphylaxis.

The Resuscitation Council (UK) provides guidelines for the management of anaphylaxis, including a visual algorithm that outlines the recommended steps for treatment.

Croup, also known as laryngotracheobronchitis, is a respiratory infection that primarily affects infants and toddlers. It is characterized by a barking cough and can cause stridor (a high-pitched sound during breathing) and respiratory distress due to swelling of the larynx and excessive secretions. The majority of cases are caused by parainfluenza viruses 1 and 3. Croup is most common in children between 6 months and 3 years of age and tends to occur more frequently in the autumn.

The clinical features of croup include a barking cough that is worse at night, preceded by symptoms of an upper respiratory tract infection such as cough, runny nose, and congestion. Stridor, respiratory distress, and fever may also be present. The severity of croup can be graded using the NICE system, which categorizes it as mild, moderate, severe, or impending respiratory failure based on the presence of symptoms such as cough, stridor, sternal/intercostal recession, agitation, lethargy, and decreased level of consciousness. The Westley croup score is another commonly used tool to assess the severity of croup based on the presence of stridor, retractions, air entry, oxygen saturation levels, and level of consciousness.

In cases of severe croup with significant airway obstruction and impending respiratory failure, symptoms may include a minimal barking cough, harder-to-hear stridor, chest wall recession, fatigue, pallor or cyanosis, decreased level of consciousness, and tachycardia. A respiratory rate over 70 breaths per minute is also indicative of severe respiratory distress.

Children with moderate or severe croup, as well as those with certain risk factors such as chronic lung disease, congenital heart disease, neuromuscular disorders, immunodeficiency, age under 3 months, inadequate fluid intake, concerns about care at home, or high fever or a toxic appearance, should be admitted to the hospital. The mainstay of treatment for croup is corticosteroids, which are typically given orally. If the child is too unwell to take oral medication, inhaled budesonide or intramuscular dexamethasone may be used as alternatives. Severe cases may require high-flow oxygen and nebulized adrenaline.

When considering the differential diagnosis for acute stridor and breathing difficulty, non-infective causes such as inhaled foreign bodies

The Civil Contingencies Act 2004 establishes a framework for civil protection in the United Kingdom. This legislation categorizes local responders to major incidents into two groups, each with their own set of responsibilities.

Category 1 responders consist of organizations that play a central role in responding to most emergencies, such as the emergency services, local authorities, and NHS bodies. These Category 1 responders are obligated to fulfill a comprehensive range of civil protection duties. These duties include assessing the likelihood of emergencies occurring and using this information to inform contingency planning. They must also develop emergency plans, establish business continuity management arrangements, and ensure that information regarding civil protection matters is readily available to the public. Additionally, Category 1 responders are responsible for maintaining systems to warn, inform, and advise the public in the event of an emergency. They are expected to share information with other local responders to enhance coordination and efficiency. Furthermore, local authorities within this category are required to provide guidance and support to businesses and voluntary organizations regarding business continuity management.

On the other hand, Category 2 organizations, such as the Health and Safety Executive, transport companies, and utility companies, are considered co-operating bodies. While they may not be directly involved in the core planning work, they play a crucial role in incidents that impact their respective sectors. Category 2 responders have a more limited set of duties, primarily focused on cooperating and sharing relevant information with both Category 1 and Category 2 responders.

For more information on this topic, please refer to the Civil Contingencies Act 2004.

Alteplase (rt-pA) is recommended for the treatment of acute ischaemic stroke in adults if it is administered as soon as possible within 4.5 hours of the onset of stroke symptoms. It is important to exclude intracranial haemorrhage through appropriate imaging techniques before starting the treatment. The initial dose of alteplase is 0.9 mg/kg, with a maximum dose of 90 mg. This dose should be given intravenously over a period of 60 minutes. The first 10% of the dose should be administered through intravenous injection, while the remaining dose should be given through intravenous infusion. For a patient weighing 70 kg, the recommended dose would be 63 mg. For more information, please refer to the NICE guidelines on stroke and transient ischaemic attack in individuals over 16 years old.

When managing newly diagnosed atrial fibrillation, a rate control strategy is often used. In this approach, beta blockers are typically the first line of treatment. However, sotalol is not recommended, and instead, other beta blockers like atenolol, acebutolol, metoprolol, nadolol, oxprenolol, and propranolol are preferred. Among these options, atenolol is commonly chosen in NHS trusts due to its cost-effectiveness.

For patients with signs of hemodynamic instability or adverse features, rhythm control (cardioversion) may be considered if they present within 48 hours of likely onset. However, in the case of this patient, their symptoms started a week ago, and there are no indications of hemodynamic instability or adverse features.

Digoxin monotherapy is typically reserved for individuals who have limited physical activity or are unable to take other first-line rate control medications due to other health conditions or contraindications.

Further Reading:

Atrial fibrillation (AF) is the most common sustained cardiac arrhythmia, affecting around 5% of patients over the age of 70-75 years and 10% of patients aged 80-85 years. While AF can cause palpitations and inefficient cardiac function, the most important aspect of managing patients with AF is reducing the increased risk of stroke.

AF can be classified as first detected episode, paroxysmal, persistent, or permanent. First detected episode refers to the initial occurrence of AF, regardless of symptoms or duration. Paroxysmal AF occurs when a patient has 2 or more self-terminating episodes lasting less than 7 days. Persistent AF refers to episodes lasting more than 7 days that do not self-terminate. Permanent AF is continuous atrial fibrillation that cannot be cardioverted or if attempts to do so are deemed inappropriate. The treatment goals for permanent AF are rate control and anticoagulation if appropriate.

Symptoms of AF include palpitations, dyspnea, and chest pain. The most common sign is an irregularly irregular pulse. An electrocardiogram (ECG) is essential for diagnosing AF, as other conditions can also cause an irregular pulse.

Managing patients with AF involves two key parts: rate/rhythm control and reducing stroke risk. Rate control involves slowing down the irregular pulse to avoid negative effects on cardiac function. This is typically achieved using beta-blockers or rate-limiting calcium channel blockers. If one drug is not effective, combination therapy may be used. Rhythm control aims to restore and maintain normal sinus rhythm through pharmacological or electrical cardioversion. However, the majority of patients are managed with a rate control strategy.

Reducing stroke risk in patients with AF is crucial. Risk stratifying tools, such as the CHA2DS2-VASc score, are used to determine the most appropriate anticoagulation strategy. Anticoagulation is recommended for patients with a score of 2 or more. Clinicians can choose between warfarin and novel oral anticoagulants (NOACs) for anticoagulation.

Before starting anticoagulation, the patient’s bleeding risk should be assessed using tools like the HAS-BLED score or the ORBIT tool. These tools evaluate factors such as hypertension, abnormal renal or liver function, history of bleeding, age, and use of drugs that predispose to bleeding.

Wernicke’s encephalopathy is a sudden neurological condition that occurs due to a lack of thiamine (vitamin B1). It is characterized by symptoms such as confusion, difficulty with coordination, low body temperature, low blood pressure, involuntary eye movements, and vomiting.

Further Reading:

Alcoholic liver disease (ALD) is a spectrum of disease that ranges from fatty liver at one end to alcoholic cirrhosis at the other. Fatty liver is generally benign and reversible with alcohol abstinence, while alcoholic cirrhosis is a more advanced and irreversible form of the disease. Alcoholic hepatitis, which involves inflammation of the liver, can lead to the development of fibrotic tissue and cirrhosis.

Several factors can increase the risk of progression of ALD, including female sex, genetics, advanced age, induction of liver enzymes by drugs, and co-existent viral hepatitis, especially hepatitis C.

The development of ALD is multifactorial and involves the metabolism of alcohol in the liver. Alcohol is metabolized to acetaldehyde and then acetate, which can result in the production of damaging reactive oxygen species. Genetic polymorphisms and co-existing hepatitis C infection can enhance the pathological effects of alcohol metabolism.

Patients with ALD may be asymptomatic or present with non-specific symptoms such as abdominal discomfort, vomiting, or anxiety. Those with alcoholic hepatitis may have fever, anorexia, and deranged liver function tests. Advanced liver disease can manifest with signs of portal hypertension and cirrhosis, such as ascites, varices, jaundice, and encephalopathy.

Screening tools such as the AUDIT questionnaire can be used to assess alcohol consumption and identify hazardous or harmful drinking patterns. Liver function tests, FBC, and imaging studies such as ultrasound or liver biopsy may be performed to evaluate liver damage.

Management of ALD involves providing advice on reducing alcohol intake, administering thiamine to prevent Wernicke’s encephalopathy, and addressing withdrawal symptoms with benzodiazepines. Complications of ALD, such as intoxication, encephalopathy, variceal bleeding, ascites, hypoglycemia, and coagulopathy, require specialized interventions.

Heavy alcohol use can also lead to thiamine deficiency and the development of Wernicke Korsakoff’s syndrome, characterized by confusion, ataxia, hypothermia, hypotension, nystagmus, and vomiting. Prompt treatment is necessary to prevent progression to Korsakoff’s psychosis.

In summary, alcoholic liver disease is a spectrum of disease that can range from benign fatty liver to irreversible cirrhosis. Risk factors for progression include female sex, genetics, advanced age, drug-induced liver enzyme induction, and co-existing liver conditions.

Aortic dissection is a condition that occurs when the middle layer of the aorta, known as the tunica media, becomes weakened. This weakening leads to the development of cases of aortic dissection.

Further Reading:

Aortic dissection is a life-threatening condition in which blood flows through a tear in the innermost layer of the aorta, creating a false lumen. Prompt treatment is necessary as the mortality rate increases by 1-2% per hour. There are different classifications of aortic dissection, with the majority of cases being proximal. Risk factors for aortic dissection include hypertension, atherosclerosis, connective tissue disorders, family history, and certain medical procedures.

The presentation of aortic dissection typically includes sudden onset sharp chest pain, often described as tearing or ripping. Back pain and abdominal pain are also common, and the pain may radiate to the neck and arms. The clinical picture can vary depending on which aortic branches are affected, and complications such as organ ischemia, limb ischemia, stroke, myocardial infarction, and cardiac tamponade may occur. Common signs and symptoms include a blood pressure differential between limbs, pulse deficit, and a diastolic murmur.

Various investigations can be done to diagnose aortic dissection, including ECG, CXR, and CT with arterial contrast enhancement (CTA). CT is the investigation of choice due to its accuracy in diagnosis and classification. Other imaging techniques such as transoesophageal echocardiography (TOE), magnetic resonance imaging/angiography (MRI/MRA), and digital subtraction angiography (DSA) are less commonly used.

Management of aortic dissection involves pain relief, resuscitation measures, blood pressure control, and referral to a vascular or cardiothoracic team. Opioid analgesia should be given for pain relief, and resuscitation measures such as high flow oxygen and large bore IV access should be performed. Blood pressure control is crucial, and medications such as labetalol may be used to reduce systolic blood pressure. Hypotension carries a poor prognosis and may require careful fluid resuscitation. Treatment options depend on the type of dissection, with type A dissections typically requiring urgent surgery and type B dissections managed by thoracic endovascular aortic repair (TEVAR) and blood pressure control optimization.

If the patient is suffering from adrenal insufficiency, it is likely that she will have hyponatremia and hyperkalemia. Adrenal insufficiency occurs when the adrenal glands do not produce enough hormones, particularly cortisol. This can lead to imbalances in electrolytes, such as sodium and potassium. Hyponatremia refers to low levels of sodium in the blood, while hyperkalemia refers to high levels of potassium in the blood. These abnormalities can cause symptoms such as dizziness, weakness, abdominal discomfort, and muscle aches. Additionally, the patient’s reported weight loss and other symptoms are consistent with adrenal insufficiency.

Further Reading:

Addison’s disease, also known as primary adrenal insufficiency or hypoadrenalism, is a rare disorder caused by the destruction of the adrenal cortex. This leads to reduced production of glucocorticoids, mineralocorticoids, and adrenal androgens. The deficiency of cortisol results in increased production of adrenocorticotropic hormone (ACTH) due to reduced negative feedback to the pituitary gland. This condition can cause metabolic disturbances such as hyperkalemia, hyponatremia, hypercalcemia, and hypoglycemia.

The symptoms of Addison’s disease can vary but commonly include fatigue, weight loss, muscle weakness, and low blood pressure. It is more common in women and typically affects individuals between the ages of 30-50. The most common cause of primary hypoadrenalism in developed countries is autoimmune destruction of the adrenal glands. Other causes include tuberculosis, adrenal metastases, meningococcal septicaemia, HIV, and genetic disorders.

The diagnosis of Addison’s disease is often suspected based on low cortisol levels and electrolyte abnormalities. The adrenocorticotropic hormone stimulation test is commonly used for confirmation. Other investigations may include adrenal autoantibodies, imaging scans, and genetic screening.

Addisonian crisis is a potentially life-threatening condition that occurs when there is an acute deficiency of cortisol and aldosterone. It can be the first presentation of undiagnosed Addison’s disease. Precipitating factors of an Addisonian crisis include infection, dehydration, surgery, trauma, physiological stress, pregnancy, hypoglycemia, and acute withdrawal of long-term steroids. Symptoms of an Addisonian crisis include malaise, fatigue, nausea or vomiting, abdominal pain, fever, muscle pains, dehydration, confusion, and loss of consciousness.

There is no fixed consensus on diagnostic criteria for an Addisonian crisis, as symptoms are non-specific. Investigations may include blood tests, blood gas analysis, and septic screens if infection is suspected. Management involves administering hydrocortisone and fluids. Hydrocortisone is given parenterally, and the dosage varies depending on the age of the patient. Fluid resuscitation with saline is necessary to correct any electrolyte disturbances and maintain blood pressure. The underlying cause of the crisis should also be identified and treated. Close monitoring of sodium levels is important to prevent complications such as osmotic demyelination syndrome.

Radial nerve injuries often occur in conjunction with fractures of the humerus. The most common cause of a radial nerve palsy is external compression or trauma to the radial nerve as it passes through the spiral groove in the middle of the humerus.

There are several factors that can lead to damage of the radial nerve in the spiral groove. These include trauma, such as a fracture in the middle of the humerus, compression known as Saturday night palsy, and iatrogenic causes like injections.

When the radial nerve is injured within the spiral groove, it results in weakness of the wrist and metacarpophalangeal joints. However, elbow extension is not affected because the branches to the triceps and anconeus muscles originate before the spiral groove. The interphalangeal joints remain unaffected as well, as they are supplied by the median and ulnar nerves. Sensory loss will be experienced over the dorsal aspect of the forearm, extending from below the elbow to the 1st dorsal interosseous.

In contrast, injury to the radial nerve in the axilla will also cause weakness of elbow extension and sensory loss in the distribution of the more proximal cutaneous branches. This helps distinguish it from injury in the spiral groove.

In the forearm, the posterior interosseous branch of the radial nerve can also be damaged. This can occur due to injury to the radial head or entrapment in the supinator muscle under the arcade of Frohse. However, this type of injury can be easily distinguished from injury in the spiral groove because there is no sensory involvement and no wrist drop, thanks to the preservation of the extensor carpi radialis longus. Nonetheless, there will still be weakness in the wrist and fingers.

One of the clinical features of a tension pneumothorax is the deviation of the trachea away from the side where the pneumothorax is located. This particular feature is typically observed in cases of right-sided tension pneumothorax.

Further Reading:

A pneumothorax is an abnormal collection of air in the pleural cavity of the lung. It can be classified by cause as primary spontaneous, secondary spontaneous, or traumatic. Primary spontaneous pneumothorax occurs without any obvious cause in the absence of underlying lung disease, while secondary spontaneous pneumothorax occurs in patients with significant underlying lung diseases. Traumatic pneumothorax is caused by trauma to the lung, often from blunt or penetrating chest wall injuries.

Tension pneumothorax is a life-threatening condition where the collection of air in the pleural cavity expands and compresses normal lung tissue and mediastinal structures. It can be caused by any of the aforementioned types of pneumothorax. Immediate management of tension pneumothorax involves the ABCDE approach, which includes ensuring a patent airway, controlling the C-spine, providing supplemental oxygen, establishing IV access for fluid resuscitation, and assessing and managing other injuries.

Treatment of tension pneumothorax involves needle thoracocentesis as a temporary measure to provide immediate decompression, followed by tube thoracostomy as definitive management. Needle thoracocentesis involves inserting a 14g cannula into the pleural space, typically via the 4th or 5th intercostal space midaxillary line. If the patient is peri-arrest, immediate thoracostomy is advised.

The pathophysiology of tension pneumothorax involves disruption to the visceral or parietal pleura, allowing air to flow into the pleural space. This can occur through an injury to the lung parenchyma and visceral pleura, or through an entry wound to the external chest wall in the case of a sucking pneumothorax. Injured tissue forms a one-way valve, allowing air to enter the pleural space with inhalation but prohibiting air outflow. This leads to a progressive increase in the volume of non-absorbable intrapleural air with each inspiration, causing pleural volume and pressure to rise within the affected hemithorax.

During CPR of a hypothermic patient, it is important to follow specific guidelines. If the patient’s core temperature is below 30ºC, resuscitation drugs, such as adrenaline, should be withheld. Once the core temperature rises above 30ºC, cardiac arrest drugs can be administered. However, if the patient’s temperature is between 30-35ºC, the interval for administering cardiac arrest drugs should be doubled. For example, adrenaline should be given every 6-10 minutes instead of the usual 3-5 minutes for a normothermic patient.

Further Reading:

Hypothermic cardiac arrest is a rare situation that requires a tailored approach. Resuscitation is typically prolonged, but the prognosis for young, previously healthy individuals can be good. Hypothermic cardiac arrest may be associated with drowning. Hypothermia is defined as a core temperature below 35ºC and can be graded as mild, moderate, severe, or profound based on the core temperature. When the core temperature drops, basal metabolic rate falls and cell signaling between neurons decreases, leading to reduced tissue perfusion. Signs and symptoms of hypothermia progress as the core temperature drops, initially presenting as compensatory increases in heart rate and shivering, but eventually ceasing as the temperature drops into moderate hypothermia territory.

ECG changes associated with hypothermia include bradyarrhythmias, Osborn waves, prolonged PR, QRS, and QT intervals, shivering artifact, ventricular ectopics, and cardiac arrest. When managing hypothermic cardiac arrest, ALS should be initiated as per the standard ALS algorithm, but with modifications. It is important to check for signs of life, re-warm the patient, consider mechanical ventilation due to chest wall stiffness, adjust dosing or withhold drugs due to slowed drug metabolism, and correct electrolyte disturbances. The resuscitation of hypothermic patients is often prolonged and may continue for a number of hours.

Pulse checks during CPR may be difficult due to low blood pressure, and the pulse check is prolonged to 1 minute for this reason. Drug metabolism is slowed in hypothermic patients, leading to a build-up of potentially toxic plasma concentrations of administered drugs. Current guidance advises withholding drugs if the core temperature is below 30ºC and doubling the drug interval at core temperatures between 30 and 35ºC. Electrolyte disturbances are common in hypothermic patients, and it is important to interpret results keeping the setting in mind. Hypoglycemia should be treated, hypokalemia will often correct as the patient re-warms, ABG analyzers may not reflect the reality of the hypothermic patient, and severe hyperkalemia is a poor prognostic indicator.

Different warming measures can be used to increase the core body temperature, including external passive measures such as removal of wet clothes and insulation with blankets, external active measures such as forced heated air or hot-water immersion, and internal active measures such as inhalation of warm air, warmed intravenous fluids, gastric, bladder, peritoneal and/or pleural lavage and high volume renal haemofilter.

The most suitable approach for investigation in this case would be to send a blood test for Epstein-Barr virus (EBV) viral serology. Glandular fever, also known as infectious mononucleosis, is commonly caused by the Epstein-Barr virus. The symptoms described by the patient, including a sore throat, fever, and feeling unwell, are consistent with this condition. To confirm the diagnosis, a blood test for EBV viral serology can be performed. This test detects antibodies produced by the body in response to the virus. It is important to note that the Monospot test, which is another blood test for infectious mononucleosis, may not be as accurate in younger children. Therefore, the most appropriate option would be to send a blood test for EBV viral serology in 2-3 days time. This will allow for the detection of specific antibodies and provide a more accurate diagnosis.

Further Reading:

Glandular fever, also known as infectious mononucleosis or mono, is a clinical syndrome characterized by symptoms such as sore throat, fever, and swollen lymph nodes. It is primarily caused by the Epstein-Barr virus (EBV), with other viruses and infections accounting for the remaining cases. Glandular fever is transmitted through infected saliva and primarily affects adolescents and young adults. The incubation period is 4-8 weeks.

The majority of EBV infections are asymptomatic, with over 95% of adults worldwide having evidence of prior infection. Clinical features of glandular fever include fever, sore throat, exudative tonsillitis, lymphadenopathy, and prodromal symptoms such as fatigue and headache. Splenomegaly (enlarged spleen) and hepatomegaly (enlarged liver) may also be present, and a non-pruritic macular rash can sometimes occur.

Glandular fever can lead to complications such as splenic rupture, which increases the risk of rupture in the spleen. Approximately 50% of splenic ruptures associated with glandular fever are spontaneous, while the other 50% follow trauma. Diagnosis of glandular fever involves various investigations, including viral serology for EBV, monospot test, and liver function tests. Additional serology tests may be conducted if EBV testing is negative.

Management of glandular fever involves supportive care and symptomatic relief with simple analgesia. Antiviral medication has not been shown to be beneficial. It is important to identify patients at risk of serious complications, such as airway obstruction, splenic rupture, and dehydration, and provide appropriate management. Patients can be advised to return to normal activities as soon as possible, avoiding heavy lifting and contact sports for the first month to reduce the risk of splenic rupture.

Rare but serious complications associated with glandular fever include hepatitis, upper airway obstruction, cardiac complications, renal complications, neurological complications, haematological complications, chronic fatigue, and an increased risk of lymphoproliferative cancers and multiple sclerosis.

Protamine sulphate is a potent base that forms a stable salt complex with heparin, an acidic substance. This complex renders heparin inactive, making protamine sulphate a useful tool for neutralizing the effects of heparin. Additionally, protamine sulphate can be used to reverse the effects of LMWHs, although it is not as effective, providing only about two-thirds of the relative effect.

It is important to note that protamine sulphate also possesses its own weak intrinsic anticoagulant effect. This effect is believed to stem from its ability to inhibit the formation and activity of thromboplastin.

When administering protamine sulphate, it is typically done through slow intravenous injection. The dosage should be adjusted based on the amount of heparin that needs to be neutralized, the time that has passed since heparin administration, and the aPTT (activated partial thromboplastin time). As a general guideline, 1 mg of protamine can neutralize 100 IU of heparin. However, it is crucial to adhere to a maximum adult dose of 50 mg within a 10-minute period.

It is worth mentioning that protamine sulphate can have some adverse effects. It acts as a myocardial depressant, potentially leading to bradycardia (slow heart rate) and hypotension (low blood pressure). These effects may arise due to complement activation and leukotriene release.

Two types of tapeworms, Taenia solium and Taenia saginata, can infest humans. Infestation occurs when people consume meat from intermediate hosts that contain the parasite’s tissue stages. Tapeworms compete for nutrients and infestation is often without symptoms. However, in more severe cases, individuals may experience epigastric pain, diarrhea, and vomiting. Diagnosis involves identifying characteristic eggs in the patient’s stool.

Taenia solium infestation can also lead to a condition called cysticercosis. This occurs when larval cysts infiltrate and spread throughout the lung, liver, eye, or brain. Cysticercosis presents with neurological symptoms, seizures, and impaired vision. Confirmation of cysticercosis involves the presence of antibodies and imaging tests such as chest X-rays and CT brain scans.

The treatment for tapeworm infestation is highly effective and involves the use of medications like niclosamide or praziquantel. However, it is important to seek specialist advice when managing Taenia infections in the central nervous system, as severe inflammatory reactions can occur.

Henry’s law describes the correlation between the quantity of dissolved gas in a liquid and its partial pressure above the liquid. According to Henry’s law, the amount of gas dissolved in a liquid is directly proportional to the partial pressure of that gas above the liquid. In the case of nitrogen narcosis, as the patient descends deeper into the water, the pressure increases, causing more nitrogen to dissolve in the bloodstream. As the patient ascends, the pressure decreases, leading to a decrease in the amount of dissolved nitrogen and improvement in symptoms.

Further Reading:

Decompression illness (DCI) is a term that encompasses both decompression sickness (DCS) and arterial gas embolism (AGE). When diving underwater, the increasing pressure causes gases to become more soluble and reduces the size of gas bubbles. As a diver ascends, nitrogen can come out of solution and form gas bubbles, leading to decompression sickness or the bends. Boyle’s and Henry’s gas laws help explain the changes in gases during changing pressure.

Henry’s law states that the amount of gas that dissolves in a liquid is proportional to the partial pressure of the gas. Divers often use atmospheres (ATM) as a measure of pressure, with 1 ATM being the pressure at sea level. Boyle’s law states that the volume of gas is inversely proportional to the pressure. As pressure increases, volume decreases.

Decompression sickness occurs when nitrogen comes out of solution as a diver ascends. The evolved gas can physically damage tissue by stretching or tearing it as bubbles expand, or by provoking an inflammatory response. Joints and spinal nervous tissue are commonly affected. Symptoms of primary damage usually appear immediately or soon after a dive, while secondary damage may present hours or days later.

Arterial gas embolism occurs when nitrogen bubbles escape into the arterial circulation and cause distal ischemia. The consequences depend on where the embolism lodges, ranging from tissue ischemia to stroke if it lodges in the cerebral arterial circulation. Mechanisms for distal embolism include pulmonary barotrauma, right to left shunt, and pulmonary filter overload.

Clinical features of decompression illness vary, but symptoms often appear within six hours of a dive. These can include joint pain, neurological symptoms, chest pain or breathing difficulties, rash, vestibular problems, and constitutional symptoms. Factors that increase the risk of DCI include diving at greater depth, longer duration, multiple dives close together, problems with ascent, closed rebreather circuits, flying shortly after diving, exercise shortly after diving, dehydration, and alcohol use.

Diagnosis of DCI is clinical, and investigations depend on the presentation. All patients should receive high flow oxygen, and a low threshold for ordering a chest X-ray should be maintained. Hydration is important, and IV fluids may be necessary. Definitive treatment is recompression therapy in a hyperbaric oxygen chamber, which should be arranged as soon as possible. Entonox should not be given, as it will increase the pressure effect in air spaces.

Asthma can be categorized into three levels of severity: moderate exacerbation, acute severe asthma, and life-threatening asthma.

Moderate exacerbation is characterized by an increase in symptoms and a peak expiratory flow rate (PEFR) that is between 50-75% of the best or predicted value. There are no signs of acute severe asthma present.

Acute severe asthma is indicated by a PEFR that is between 33-50% of the best or predicted value. Additionally, the respiratory rate is higher than 25 breaths per minute and the heart rate is higher than 110 beats per minute. People experiencing acute severe asthma may have difficulty completing sentences in one breath.

Life-threatening asthma is the most severe level and requires immediate medical attention. It is identified by a PEFR that is less than 33% of the best or predicted value. Oxygen saturations are below 92% when breathing regular air. The PaCO2 levels are within the normal range of 4.6-6.0 KPa, but the PaO2 levels are below 8 KPa. Other symptoms include a silent chest, cyanosis, feeble respiratory effort, bradycardia, arrhythmia, hypotension, and signs of exhaustion, confusion, or coma.

It is important to recognize the severity of asthma symptoms in order to provide appropriate medical care and intervention.

Patients who experience post-tonsillectomy bleeding, even if it stops, should be closely monitored and assessed by an ear, nose, and throat specialist before being discharged. It is important to note that minor bleeding episodes may occur before a more severe hemorrhage. Therefore, patients with post-tonsillectomy bleeds, even if they seem to have resolved, should be admitted to the hospital under the care of an ENT specialist.

Further Reading:

Tonsillectomy is a common procedure performed by ENT surgeons in the UK, with over 50,000 surgeries performed each year. While it is considered routine, there are risks of serious complications, including post-tonsillectomy bleeding. Approximately 5% of patients experience bleeding after the procedure, with most cases being self-limiting. However, severe bleeding can lead to hypovolemia and airway obstruction from clots, which can be life-threatening.

Post-tonsillectomy bleeding can be classified as primary (reactive) or secondary (delayed). Primary bleeding occurs within 24 hours of the procedure, while secondary bleeding occurs more than 24 hours post-procedure. Secondary bleeding is often caused by factors such as sloughing of eschar, trauma from solid food ingestion, tonsil bed infection, postoperative NSAID usage, or unknown causes.

Patients may present with symptoms such as vomiting blood, coughing up blood, tasting blood in the throat, finding blood on pillows or bed sheets, or excessive swallowing (especially in children). It is important for clinicians to assess the severity of blood loss, although it can be challenging to accurately estimate in children.

The ABCDE approach should be used to assess patients, with a focus on airway compromise, hemodynamic instability, and evidence of bleeding. Clinicians may use a head torch to identify any bleeding points, which may be actively bleeding or appear as fresh red clots. It is important to note that the tonsillar fossa may appear white or yellow, which is a normal postoperative finding.

Investigations such as a full blood count, coagulation profile, group and save, and venous blood gas may be performed to assess the patient’s condition. Senior support from ENT or anesthesiology should be called if there is active bleeding.

Management of post-tonsillectomy bleeding includes positioning the patient upright and keeping them calm, establishing intravenous access, administering fluids and blood products as needed, and administering tranexamic acid to stop bleeding. Bleeding points may require gentle suction removal of fresh clots, and topical medications such as Co-phenylcaine spray or topical adrenaline may be applied to the oropharynx. All patients with post-tonsillectomy bleeding should be assessed by ENT and observed for a prolonged period, typically 12-24 hours.

If bleeding remains uncontrolled, the patient should be kept nil by mouth in preparation for surgery, and early intervention.

The recommended dose of activated charcoal for adults and children aged 12 or over to prevent the absorption of poisons in the gastrointestinal tract is 50g.

Further Reading:

Paracetamol poisoning occurs when the liver is unable to metabolize paracetamol properly, leading to the production of a toxic metabolite called N-acetyl-p-benzoquinone imine (NAPQI). Normally, NAPQI is conjugated by glutathione into a non-toxic form. However, during an overdose, the liver’s conjugation systems become overwhelmed, resulting in increased production of NAPQI and depletion of glutathione stores. This leads to the formation of covalent bonds between NAPQI and cell proteins, causing cell death in the liver and kidneys.

Symptoms of paracetamol poisoning may not appear for the first 24 hours or may include abdominal symptoms such as nausea and vomiting. After 24 hours, hepatic necrosis may develop, leading to elevated liver enzymes, right upper quadrant pain, and jaundice. Other complications can include encephalopathy, oliguria, hypoglycemia, renal failure, and lactic acidosis.

The management of paracetamol overdose depends on the timing and amount of ingestion. Activated charcoal may be given if the patient presents within 1 hour of ingesting a significant amount of paracetamol. N-acetylcysteine (NAC) is used to increase hepatic glutathione production and is given to patients who meet specific criteria. Blood tests are taken to assess paracetamol levels, liver function, and other parameters. Referral to a medical or liver unit may be necessary, and psychiatric follow-up should be considered for deliberate overdoses.

In cases of staggered ingestion, all patients should be treated with NAC without delay. Blood tests are also taken, and if certain criteria are met, NAC can be discontinued. Adverse reactions to NAC are common and may include anaphylactoid reactions, rash, hypotension, and nausea. Treatment for adverse reactions involves medications such as chlorpheniramine and salbutamol, and the infusion may be stopped if necessary.

The prognosis for paracetamol poisoning can be poor, especially in cases of severe liver injury. Fulminant liver failure may occur, and liver transplant may be necessary. Poor prognostic indicators include low arterial pH, prolonged prothrombin time, high plasma creatinine, and hepatic encephalopathy.

All individuals diagnosed with stage 5 chronic kidney disease should be given the option to choose between haemodialysis or peritoneal dialysis. Peritoneal dialysis should be prioritized as the preferred treatment for the following groups of patients: those who still have some remaining kidney function, adult patients without major additional health conditions, and children who are two years old or younger.

Patients with myxoedema coma often exhibit several common ECG abnormalities. These include bradycardia, a prolonged QT interval, and T wave flattening or inversion. Additionally, severe hypothyroidism (myxoedema) is associated with other ECG findings such as low QRS voltage, conduction blocks, and T wave inversions without ST deviation.

Further Reading:

The thyroid gland is an endocrine organ located in the anterior neck. It consists of two lobes connected by an isthmus. The gland produces hormones called thyroxine (T4) and triiodothyronine (T3), which regulate energy use, protein synthesis, and the body’s sensitivity to other hormones. The production of T4 and T3 is stimulated by thyroid-stimulating hormone (TSH) secreted by the pituitary gland, which is in turn stimulated by thyrotropin-releasing hormone (TRH) from the hypothalamus.

Thyroid disorders can occur when there is an imbalance in the production or regulation of thyroid hormones. Hypothyroidism is characterized by a deficiency of thyroid hormones, while hyperthyroidism is characterized by an excess. The most common cause of hypothyroidism is autoimmune thyroiditis, also known as Hashimoto’s thyroiditis. It is more common in women and is often associated with goiter. Other causes include subacute thyroiditis, atrophic thyroiditis, and iodine deficiency. On the other hand, the most common cause of hyperthyroidism is Graves’ disease, which is also an autoimmune disorder. Other causes include toxic multinodular goiter and subacute thyroiditis.

The symptoms and signs of thyroid disorders can vary depending on whether the thyroid gland is underactive or overactive. In hypothyroidism, common symptoms include weight gain, lethargy, cold intolerance, and dry skin. In hyperthyroidism, common symptoms include weight loss, restlessness, heat intolerance, and increased sweating. Both hypothyroidism and hyperthyroidism can also affect other systems in the body, such as the cardiovascular, gastrointestinal, and neurological systems.

Complications of thyroid disorders can include dyslipidemia, metabolic syndrome, coronary heart disease, heart failure, subfertility and infertility, impaired special senses, and myxedema coma in severe cases of hypothyroidism. In hyperthyroidism, complications can include Graves’ orbitopathy, compression of the esophagus or trachea by goiter, thyrotoxic periodic paralysis, arrhythmias, osteoporosis, mood disorders, and increased obstetric complications.

Myxedema coma is a rare and life-threatening complication of severe hypothyroidism. It can be triggered by factors such as infection or physiological insult and presents with lethargy, bradycardia, hypothermia, hypotension, hypoventilation, altered mental state, seizures and/or coma.

Cellulitis is a common cause of swelling in one leg. It is characterized by red, hot, tender, and swollen skin, usually affecting the shin on one side. Other symptoms may include fever, fatigue, and chills. It is important to consider deep vein thrombosis (DVT) as a possible alternative diagnosis, as it can be associated with cellulitis or vice versa. Unlike cellulitis, DVT does not typically cause fever and affects the entire limb below the blood clot, resulting in swelling in the calf, ankle, and foot. Necrotizing fasciitis is a rare condition. Gout primarily affects the joints of the foot, particularly the first metatarsophalangeal joint. Erythema migrans usually produces a distinct target-shaped rash.

Further Reading:

Cellulitis is an inflammation of the skin and subcutaneous tissues caused by an infection, usually by Streptococcus pyogenes or Staphylococcus aureus. It commonly occurs on the shins and is characterized by symptoms such as erythema, pain, swelling, and heat. In some cases, there may also be systemic symptoms like fever and malaise.

The NICE Clinical Knowledge Summaries recommend using the Eron classification to determine the appropriate management of cellulitis. Class I cellulitis refers to cases without signs of systemic toxicity or uncontrolled comorbidities. Class II cellulitis involves either systemic illness or the presence of a co-morbidity that may complicate or delay the resolution of the infection. Class III cellulitis is characterized by significant systemic upset or limb-threatening infection due to vascular compromise. Class IV cellulitis involves sepsis syndrome or a severe life-threatening infection like necrotizing fasciitis.

According to the guidelines, patients with Eron Class III or Class IV cellulitis should be admitted for intravenous antibiotics. This also applies to patients with severe or rapidly deteriorating cellulitis, very young or frail individuals, immunocompromised patients, those with significant lymphedema, and those with facial or periorbital cellulitis (unless very mild). Patients with Eron Class II cellulitis may not require admission if the necessary facilities and expertise are available in the community to administer intravenous antibiotics and monitor the patient.

The recommended first-line treatment for mild to moderate cellulitis is flucloxacillin. For patients allergic to penicillin, clarithromycin or clindamycin is recommended. In cases where patients have failed to respond to flucloxacillin, local protocols may suggest the use of oral clindamycin. Severe cellulitis should be treated with intravenous benzylpenicillin and flucloxacillin.

Overall, the management of cellulitis depends on the severity of the infection and the presence of any systemic symptoms or complications. Prompt treatment with appropriate antibiotics is crucial to prevent further complications and promote healing.

The highest amount of Prilocaine that can be administered without adrenaline is 6 mg per kilogram of body weight. However, if Prilocaine is used in combination with adrenaline, the maximum dose increases to 8mg per kilogram.

Further Reading:

Local anaesthetics, such as lidocaine, bupivacaine, and prilocaine, are commonly used in the emergency department for topical or local infiltration to establish a field block. Lidocaine is often the first choice for field block prior to central line insertion. These anaesthetics work by blocking sodium channels, preventing the propagation of action potentials.

However, local anaesthetics can enter the systemic circulation and cause toxic side effects if administered in high doses. Clinicians must be aware of the signs and symptoms of local anaesthetic systemic toxicity (LAST) and know how to respond. Early signs of LAST include numbness around the mouth or tongue, metallic taste, dizziness, visual and auditory disturbances, disorientation, and drowsiness. If not addressed, LAST can progress to more severe symptoms such as seizures, coma, respiratory depression, and cardiovascular dysfunction.

The management of LAST is largely supportive. Immediate steps include stopping the administration of local anaesthetic, calling for help, providing 100% oxygen and securing the airway, establishing IV access, and controlling seizures with benzodiazepines or other medications. Cardiovascular status should be continuously assessed, and conventional therapies may be used to treat hypotension or arrhythmias. Intravenous lipid emulsion (intralipid) may also be considered as a treatment option.

If the patient goes into cardiac arrest, CPR should be initiated following ALS arrest algorithms, but lidocaine should not be used as an anti-arrhythmic therapy. Prolonged resuscitation may be necessary, and intravenous lipid emulsion should be administered. After the acute episode, the patient should be transferred to a clinical area with appropriate equipment and staff for further monitoring and care.

It is important to report cases of local anaesthetic toxicity to the appropriate authorities, such as the National Patient Safety Agency in the UK or the Irish Medicines Board in the Republic of Ireland. Additionally, regular clinical review should be conducted to exclude pancreatitis, as intravenous lipid emulsion can interfere with amylase or lipase assays.

For individuals with traumatic cardiac tamponade, thoracotomy is the recommended treatment. In the case of a trauma patient with a significant buildup of fluid around the heart and the potential for tamponade, it is advised to transfer stable patients to the operating room for thoracotomy instead of performing pericardiocentesis. Pericardiocentesis, when done correctly, is likely to be unsuccessful due to the presence of clotted blood in the pericardium. Additionally, performing pericardiocentesis would cause a delay in the thoracotomy procedure. If access to the operating room is not possible, pericardiocentesis may be considered as a temporary solution.

Further Reading:

Cardiac tamponade, also known as pericardial tamponade, occurs when fluid accumulates in the pericardial sac and compresses the heart, leading to compromised blood flow. Classic clinical signs of cardiac tamponade include distended neck veins, hypotension, muffled heart sounds, and pulseless electrical activity (PEA). Diagnosis is typically done through a FAST scan or an echocardiogram.

Management of cardiac tamponade involves assessing for other injuries, administering IV fluids to reduce preload, performing pericardiocentesis (inserting a needle into the pericardial cavity to drain fluid), and potentially performing a thoracotomy. It is important to note that untreated expanding cardiac tamponade can progress to PEA cardiac arrest.

Pericardiocentesis can be done using the subxiphoid approach or by inserting a needle between the 5th and 6th intercostal spaces at the left sternal border. Echo guidance is the gold standard for pericardiocentesis, but it may not be available in a resuscitation situation. Complications of pericardiocentesis include ST elevation or ventricular ectopics, myocardial perforation, bleeding, pneumothorax, arrhythmia, acute pulmonary edema, and acute ventricular dilatation.

It is important to note that pericardiocentesis is typically used as a temporary measure until a thoracotomy can be performed. Recent articles published on the RCEM learning platform suggest that pericardiocentesis has a low success rate and may delay thoracotomy, so it is advised against unless there are no other options available.

This patient is experiencing a condition called right-sided abducens nerve palsy, which means that their sixth cranial nerve is paralyzed. As a result, the lateral rectus muscle, which is responsible for moving the eye outward, is also paralyzed. This means that the patient’s right eye is unable to turn outward. This can lead to a condition called convergent strabismus, where the eyes are not aligned properly, and diplopia, which is double vision. To compensate for the double vision, patients often tilt their head towards the side of the paralyzed muscle.

The patient presents with a medical history and physical examination findings that are consistent with a diagnosis of Löfgren’s syndrome, which is a specific subtype of sarcoidosis. This syndrome is most commonly observed in women in their 30s and 40s, and it is more prevalent among individuals of Nordic and Irish descent.

Löfgren’s syndrome is typically characterized by a triad of clinical features, including bilateral hilar lymphadenopathy seen on chest X-ray, erythema nodosum, and arthralgia, with a particular emphasis on ankle involvement. Additionally, other symptoms commonly associated with sarcoidosis may also be present, such as a dry cough, breathlessness, fever, night sweats, malaise, weight loss, Achilles tendonitis, and uveitis.

In order to further evaluate this patient’s condition, it is recommended to refer them to a respiratory specialist for additional investigations. These investigations may include measuring the serum calcium level, as it may be elevated, and assessing the serum angiotensin-converting enzyme (ACE) level, which may also be elevated. A high-resolution CT scan can be performed to assess the extent of involvement and identify specific lymph nodes for potential biopsy. If there are any atypical features, a lymph node biopsy may be necessary. Lung function tests can be conducted to evaluate the patient’s vital capacity, and an MRI scan of the ankles may also be considered.

Fortunately, the prognosis for Löfgren’s syndrome is generally very good, and it is considered a self-limiting and benign condition. The patient can expect to recover within a timeframe of six months to two years.

The patient’s symptoms of nausea, muscle cramps, fatigue, and weakness are consistent with hyponatremia, which is a low sodium level in the blood. The blood test results show a low sodium level (Na+ 120 mmol/l) and normal potassium level (K+ 5.3 mmol/l), which is commonly seen in SIADH.

Additionally, the urine osmolality of 365 mosmol/kg indicates concentrated urine, which is contrary to what would be expected in diabetes insipidus. In diabetes insipidus, the urine would be dilute due to the inability to concentrate urine properly.

The patient’s blood pressure, pulse, respiration rate, and oxygen saturations are within normal range, which does not suggest a diagnosis of Addison’s disease or Conn’s syndrome.

Therefore, based on the symptoms, laboratory results, and urine osmolality, the most likely diagnosis for this patient is SIADH.

Further Reading:

Syndrome of inappropriate antidiuretic hormone (SIADH) is a condition characterized by low sodium levels in the blood due to excessive secretion of antidiuretic hormone (ADH). ADH, also known as arginine vasopressin (AVP), is responsible for promoting water and sodium reabsorption in the body. SIADH occurs when there is impaired free water excretion, leading to euvolemic (normal fluid volume) hypotonic hyponatremia.

There are various causes of SIADH, including malignancies such as small cell lung cancer, stomach cancer, and prostate cancer, as well as neurological conditions like stroke, subarachnoid hemorrhage, and meningitis. Infections such as tuberculosis and pneumonia, as well as certain medications like thiazide diuretics and selective serotonin reuptake inhibitors (SSRIs), can also contribute to SIADH.

The diagnostic features of SIADH include low plasma osmolality, inappropriately elevated urine osmolality, urinary sodium levels above 30 mmol/L, and euvolemic. Symptoms of hyponatremia, which is a common consequence of SIADH, include nausea, vomiting, headache, confusion, lethargy, muscle weakness, seizures, and coma.

Management of SIADH involves correcting hyponatremia slowly to avoid complications such as central pontine myelinolysis. The underlying cause of SIADH should be treated if possible, such as discontinuing causative medications. Fluid restriction is typically recommended, with a daily limit of around 1000 ml for adults. In severe cases with neurological symptoms, intravenous hypertonic saline may be used. Medications like demeclocycline, which blocks ADH receptors, or ADH receptor antagonists like tolvaptan may also be considered.

It is important to monitor serum sodium levels closely during treatment, especially if using hypertonic saline, to prevent rapid correction that can lead to central pontine myelinolysis. Osmolality abnormalities can help determine the underlying cause of hyponatremia, with increased urine osmolality indicating dehydration or renal disease, and decreased urine osmolality suggesting SIADH or overhydration.

The FeverPAIN score is a clinical scoring system that helps determine the probability of streptococcal infection and the necessity of antibiotic treatment. NICE recommends using either the CENTOR or FeverPAIN clinical scoring systems to assess the likelihood of streptococcal infection and the need for antibiotics. The RSI score is utilized to evaluate laryngopharyngeal reflux, while the CSMCPI is employed to predict clinical outcomes in patients with upper gastrointestinal bleeding. Lastly, the Mallampati score is used to assess the oropharyngeal space and predict the difficulty of endotracheal intubation.

Further Reading:

Pharyngitis and tonsillitis are common conditions that cause inflammation in the throat. Pharyngitis refers to inflammation of the oropharynx, which is located behind the soft palate, while tonsillitis refers to inflammation of the tonsils. These conditions can be caused by a variety of pathogens, including viruses and bacteria. The most common viral causes include rhinovirus, coronavirus, parainfluenza virus, influenza types A and B, adenovirus, herpes simplex virus type 1, and Epstein Barr virus. The most common bacterial cause is Streptococcus pyogenes, also known as Group A beta-hemolytic streptococcus (GABHS). Other bacterial causes include Group C and G beta-hemolytic streptococci and Fusobacterium necrophorum.

Group A beta-hemolytic streptococcus is the most concerning pathogen as it can lead to serious complications such as rheumatic fever and glomerulonephritis. These complications can occur due to an autoimmune reaction triggered by antigen/antibody complex formation or from cell damage caused by bacterial exotoxins.

When assessing a patient with a sore throat, the clinician should inquire about the duration and severity of the illness, as well as associated symptoms such as fever, malaise, headache, and joint pain. It is important to identify any red flags and determine if the patient is immunocompromised. Previous non-suppurative complications of Group A beta-hemolytic streptococcus infection should also be considered, as there is an increased risk of further complications with subsequent infections.

Red flags that may indicate a more serious condition include severe pain, neck stiffness, or difficulty swallowing. These symptoms may suggest epiglottitis or a retropharyngeal abscess, which require immediate attention.

To determine the likelihood of a streptococcal infection and the need for antibiotic treatment, two scoring systems can be used: CENTOR and FeverPAIN. The CENTOR criteria include tonsillar exudate, tender anterior cervical lymphadenopathy or lymphadenitis, history of fever, and absence of cough. The FeverPAIN criteria include fever, purulence, rapid onset of symptoms, severely inflamed tonsils, and absence of cough or coryza. Based on the scores from these criteria, the likelihood of a streptococcal infection can be estimated, and appropriate management can be undertaken. can

This patient has presented with symptoms and signs consistent with myopathy. Myopathy is characterized by muscle weakness, muscle atrophy, and reduced tone and reflexes. Hyperkalemia is a known biochemical cause for myopathy, while other metabolic causes include hypokalemia, hypercalcemia, hypomagnesemia, hyperthyroidism, hypothyroidism, diabetes mellitus, Cushing’s disease, and Conn’s syndrome. In this case, ACE inhibitors, such as ramipril, are a well-recognized cause of hyperkalemia and are likely responsible.

Commonly encountered side effects of ACE inhibitors include renal impairment, persistent dry cough, angioedema (with delayed onset), rashes, upper respiratory tract symptoms (such as a sore throat), and gastrointestinal upset.

When determining the initial EPAP and IPAP pressure settings for this patient, it is important to consider their specific needs and condition. In general, the EPAP pressure should be set between 3-5 cmH2O, which helps to maintain positive pressure in the airways during exhalation, preventing them from collapsing. This can improve oxygenation and reduce the work of breathing.

The IPAP pressure, on the other hand, should be set between 10-15 cmH2O. This higher pressure during inhalation helps to overcome any resistance in the airways and ensures adequate ventilation. It also assists in improving the patient’s tidal volume and reducing carbon dioxide levels.

Therefore, the recommended initial EPAP and IPAP pressure settings for this patient would be EPAP 3-5 cmH2O / IPAP 10-15 cmH2O. These settings provide a balance between maintaining airway patency during exhalation and ensuring sufficient ventilation during inhalation. However, it is important to regularly assess the patient’s response to therapy and adjust the settings as needed to optimize their respiratory function.

Further Reading:

Mechanical ventilation is the use of artificial means to assist or replace spontaneous breathing. It can be invasive, involving instrumentation inside the trachea, or non-invasive, where there is no instrumentation of the trachea. Non-invasive mechanical ventilation (NIV) in the emergency department typically refers to the use of CPAP or BiPAP.

CPAP, or continuous positive airways pressure, involves delivering air or oxygen through a tight-fitting face mask to maintain a continuous positive pressure throughout the patient’s respiratory cycle. This helps maintain small airway patency, improves oxygenation, decreases airway resistance, and reduces the work of breathing. CPAP is mainly used for acute cardiogenic pulmonary edema.

BiPAP, or biphasic positive airways pressure, also provides positive airway pressure but with variations during the respiratory cycle. The pressure is higher during inspiration than expiration, generating a tidal volume that assists ventilation. BiPAP is mainly indicated for type 2 respiratory failure in patients with COPD who are already on maximal medical therapy.

The pressure settings for CPAP typically start at 5 cmH2O and can be increased to a maximum of 15 cmH2O. For BiPAP, the starting pressure for expiratory pressure (EPAP) or positive end-expiratory pressure (PEEP) is 3-5 cmH2O, while the starting pressure for inspiratory pressure (IPAP) is 10-15 cmH2O. These pressures can be titrated up if there is persisting hypoxia or acidosis.

In terms of lung protective ventilation, low tidal volumes of 5-8 ml/kg are used to prevent atelectasis and reduce the risk of lung injury. Inspiratory pressures (plateau pressure) should be kept below 30 cm of water, and permissible hypercapnia may be allowed. However, there are contraindications to lung protective ventilation, such as unacceptable levels of hypercapnia, acidosis, and hypoxemia.

Overall, mechanical ventilation, whether invasive or non-invasive, is used in various respiratory and non-respiratory conditions to support or replace spontaneous breathing and improve oxygenation and ventilation.

This patient is displaying symptoms consistent with a malabsorption syndrome, which is supported by the findings of subtotal villous atrophy in his small bowel biopsy. Based on this information, the possible causes can be narrowed down to tropical sprue, coeliac disease, and giardiasis.

Considering that the patient was previously healthy before his trip to Nepal, it is unlikely that he has coeliac disease. Additionally, tropical sprue is rare outside of the regions around the equator and is uncommon in Nepal. On the other hand, giardiasis is prevalent in Nepal and is the most probable cause of the patient’s symptoms.

Giardiasis is a chronic diarrheal illness caused by a parasite called Giardia lamblia. Infection occurs when individuals ingest cysts present in contaminated food or water. Common symptoms associated with giardiasis include chronic diarrhea, weakness, abdominal cramps, flatulence, smelly and greasy stools, nausea, vomiting, and weight loss.

Stool culture often yields negative results, so the preferred diagnostic test is a stool ova and parasite (O&P) examination. This test should be repeated three times for accuracy. Additionally, the small bowel biopsy should be re-evaluated to check for the presence of Giardia lamblia.

The standard treatment for giardiasis involves antibiotic therapy with a nitroimidazole antibiotic, such as metronidazole.

Patients with dental abscess should be evaluated for signs of spread into deep fascial planes. Infection of the sublingual space can lead to serious complications that can be life-threatening. Swelling in this area can cause the tongue to elevate, potentially obstructing the airway. Other complications include infections such as mediastinitis, necrotizing fasciitis, cavernous sinus thrombosis, sepsis, thoracic empyema, Lemierre’s syndrome, cerebral abscess, orbital abscess, and osteomyelitis.

There are certain indications that may require admission to the hospital for dental abscess. These include evidence of significant systemic disturbance, inability to control the infection with antibiotics, rapid spread of infection, stridor or compromised airway, swelling of the sublingual space or pharynx, difficulty swallowing or speaking, immunocompromised patients, abscess requiring drainage under general anesthesia.

Fever and pain are common symptoms of dental abscess but by themselves are not enough to warrant admission. Ideally, dental abscess should be managed through urgent dental review. However, if immediate dental review is not available, the patient may be treated with antibiotics as long as there are no signs of more severe infection.

Further Reading:

Dental abscess is a condition that usually occurs as a result of dental caries or following a dental procedure or trauma. Dental caries refers to the loss of enamel caused by acids produced by bacteria in the mouth. This allows bacteria to enter the pulp, root, and local tissues, leading to infection. The infection can then spread to surrounding tissues, causing conditions such as gingivitis or dental abscess. In severe cases, the infection can spread to deep fascial planes, resulting in conditions like retropharyngeal abscess or Ludwig’s angina.

A dental abscess is typically caused by a combination of gram-positive and gram-negative bacteria, such as Streptococcus, Staphylococcus, and Prevotella. When assessing a patient with a suspected dental abscess, a thorough history and inspection of the mouth, face, and neck are necessary. This helps confirm the diagnosis and assess the risk of serious complications, such as airway compromise or deep/spreading infection.

Some concerning features on history or examination include systemic upset (e.g., fever, vomiting), sublingual or pharyngeal swelling, stridor, dysphagia, dysphonia, dyspnea, and progression of illness despite current antibiotic treatment. It’s important to consider non-dental causes of mouth and jaw pain, such as trauma, referred sinus pain, cardiac pain radiating to the jaw, trigeminal neuralgia, otalgia radiating to the jaw, and parotid gland swelling.

Management of a dental abscess typically involves providing analgesia (NSAIDs and paracetamol) and facilitating early dental review. Antibiotics may be prescribed in certain cases, such as when the patient does not have immediate access to a dentist and is systemically unwell, shows signs of severe infection, or is a high-risk individual (e.g., immunocompromised or diabetic). The choice of antibiotics includes amoxicillin, phenoxymethylpenicillin, or clarithromycin (if penicillin allergic). In severe or spreading infections, metronidazole may be added. The typical course of antibiotics is 5 days.

Cardiac enzymes do not increase in unstable angina. However, if cardiac markers do rise, it is classified as a non-ST elevation myocardial infarction (NSTEMI). Both unstable angina and NSTEMI can have a normal ECG. An extended ventricular activation time indicates damage to the heart muscle. This occurs because infarcting myocardium conducts electrical impulses at a slower pace, resulting in a prolonged interval between the start of the QRS complex and the apex of the R wave. A positive troponin test indicates the presence of necrosis in cardiac myocytes.

Summary:
Marker | Initial Rise | Peak | Normal at
Creatine kinase | 4-8 hours | 18 hours 2-3 days | CK-MB = main cardiac isoenzyme
Myoglobin | 1-4 hours | 6-7 hours | 24 hours | Low specificity due to skeletal muscle damage
Troponin I | 3-12 hours | 24 hours | 3-10 days | Appears to be the most sensitive and specific
HFABP | 1-2 hours | 5-10 hours | 24 hours | HFABP = heart fatty acid binding protein
LDH | 10 hours | 24-48 hours | 14 days | Cardiac muscle mainly contains LDH

A recent audit conducted by the Royal College of Emergency Medicine (RCEM) in 2018 revealed a concerning decline in the standards of pain management for children with fractured limbs in Emergency Departments (EDs). The audit found that the majority of patients experienced longer waiting times for pain relief compared to previous years. Shockingly, more than 1 in 10 children who presented with significant pain due to a limb fracture did not receive any pain relief at all.

To address this issue, the Agency for Health Care Policy and Research (AHCPR) in the USA recommends following the ABCs of pain management for all patients, including children. This approach involves regularly asking about pain, systematically assessing it, believing the patient and their family in their reports of pain and what relieves it, choosing appropriate pain control options, delivering interventions in a timely and coordinated manner, and empowering patients and their families to have control over their pain management.

The RCEM has established standards that require a child’s pain to be assessed within 15 minutes of their arrival at the ED. This is considered a fundamental standard. Various rating scales are available for assessing pain in children, with the choice depending on the child’s age and ability to use the scale. These scales include the Wong-Baker Faces Pain Rating Scale, Numeric rating scale, and Behavioural scale.

To ensure timely administration of analgesia to children in acute pain, the RCEM has set specific standards. These standards state that 100% of patients in severe pain should receive appropriate analgesia within 60 minutes of their arrival or triage, whichever comes first. Additionally, 75% should receive analgesia within 30 minutes, and 50% within 20 minutes.

Atopic dermatitis is a long-lasting inflammatory skin condition that is linked to increased levels of IgE in the bloodstream. It is also characterized by sensitivity to various allergens found in the air, food, and microorganisms.

Further Reading:

Eczema is a chronic inflammatory skin disease characterized by dry, itchy skin with eczematous lesions. It often follows a chronic relapsing course and can lead to chronic skin changes such as lichenification and pigment changes. The term eczema is often used interchangeably with dermatitis, but strictly speaking, dermatitis refers to inflammation of the skin while eczema refers to specific conditions where skin inflammation is a feature.

Atopic eczema, also known as atopic dermatitis, is the most common type of eczema. It is usually first diagnosed in young children, with 90% of cases diagnosed before the age of 5. However, it can affect individuals of any age. Symptoms often improve as patients progress into their teens and adulthood. Around 10-20% of children are affected by atopic eczema, but only 3% of adults experience symptoms.

The exact cause of atopic eczema is not fully understood, but it is believed to be multifactorial, with both genetic and environmental factors playing a role. Genetic defects in genes that aid in the functioning of the skin barrier have been identified, which may predispose individuals to breaks in the skin barrier and increased exposure to antigens. Environmental factors such as pollution, allergen exposure, climate, and others also contribute to the development of the disease.

Diagnosing atopic eczema involves assessing the presence of key clinical features, such as pruritus (itching), eczema/dermatitis in a pattern appropriate for age, early age of onset, and personal or family history of atopy. Various diagnostic criteria have been established to aid in the diagnosis, including those set out by the American Academy of Dermatology and the UK working party.

The severity of atopic eczema can vary, and treatment options depend on the severity. Mild cases may be managed with emollients (moisturizers) and mild potency topical corticosteroids. Moderate cases may require moderate potency topical corticosteroids, topical calcineurin inhibitors, and bandages. Severe cases may necessitate the use of potent topical corticosteroids, topical calcineurin inhibitors, bandages, phototherapy, and systemic therapy.

In addition to medical treatment, identifying and avoiding triggers is an important aspect of managing atopic eczema. Common triggers include irritants, contact allergens, certain foods, skin infections, inhalant triggers, stress and infection.

The management of anaphylaxis involves several important steps. First and foremost, it is crucial to ensure proper airway management. Additionally, early administration of adrenaline is essential, preferably in the anterolateral aspect of the middle third of the thigh. Aggressive fluid resuscitation is also necessary. In severe cases, intubation may be required. However, it is important to note that the administration of chlorpheniramine and hydrocortisone should only be considered after early resuscitation has taken place.

Adrenaline is the most vital medication for treating anaphylactic reactions. It acts as an alpha-adrenergic receptor agonist, which helps reverse peripheral vasodilatation and reduce oedema. Furthermore, its beta-adrenergic effects aid in dilating the bronchial airways, increasing the force of myocardial contraction, and suppressing histamine and leukotriene release. Administering adrenaline as the first drug is crucial, and the intramuscular (IM) route is generally the most effective for most individuals.

The recommended doses of IM adrenaline for different age groups during anaphylaxis are as follows:

– Children under 6 years: 150 mcg (0.15 mL of 1:1000)
– Children aged 6-12 years: 300 mcg (0.3 mL of 1:1000)
– Children older than 12 years: 500 mcg (0.5 mL of 1:1000)
– Adults: 500 mcg (0.5 mL of 1:1000)

An elevated pH (normal range 7.34-7.45) suggests alkalosis. A low pCO2 (normal range 4.4-6.0 Kpa) indicates that the respiratory system is causing the alkalosis. The metabolic system, on the other hand, is not contributing to either alkalosis or acidosis as both the bicarbonate and base excess levels are within the normal ranges.

Further Reading:

Salicylate poisoning, particularly from aspirin overdose, is a common cause of poisoning in the UK. One important concept to understand is that salicylate overdose leads to a combination of respiratory alkalosis and metabolic acidosis. Initially, the overdose stimulates the respiratory center, leading to hyperventilation and respiratory alkalosis. However, as the effects of salicylate on lactic acid production, breakdown into acidic metabolites, and acute renal injury occur, it can result in high anion gap metabolic acidosis.

The clinical features of salicylate poisoning include hyperventilation, tinnitus, lethargy, sweating, pyrexia (fever), nausea/vomiting, hyperglycemia and hypoglycemia, seizures, and coma.

When investigating salicylate poisoning, it is important to measure salicylate levels in the blood. The sample should be taken at least 2 hours after ingestion for symptomatic patients or 4 hours for asymptomatic patients. The measurement should be repeated every 2-3 hours until the levels start to decrease. Other investigations include arterial blood gas analysis, electrolyte levels (U&Es), complete blood count (FBC), coagulation studies (raised INR/PTR), urinary pH, and blood glucose levels.

To manage salicylate poisoning, an ABC approach should be followed to ensure a patent airway and adequate ventilation. Activated charcoal can be administered if the patient presents within 1 hour of ingestion. Oral or intravenous fluids should be given to optimize intravascular volume. Hypokalemia and hypoglycemia should be corrected. Urinary alkalinization with intravenous sodium bicarbonate can enhance the elimination of aspirin in the urine. In severe cases, hemodialysis may be necessary.

Urinary alkalinization involves targeting a urinary pH of 7.5-8.5 and checking it hourly. It is important to monitor for hypokalemia as alkalinization can cause potassium to shift from plasma into cells. Potassium levels should be checked every 1-2 hours.

In cases where the salicylate concentration is high (above 500 mg/L in adults or 350 mg/L in children), sodium bicarbonate can be administered intravenously. Hemodialysis is the treatment of choice for severe poisoning and may be indicated in cases of high salicylate levels, resistant metabolic acidosis, acute kidney injury, pulmonary edema, seizures and coma.

The appropriate dose of adrenaline for treating anaphylaxis in children under 6 years old is 150 micrograms, which is equivalent to 0.15 ml of a 1 in 1,000 solution.

Further Reading:

Anaphylaxis is a severe and life-threatening allergic reaction that affects the entire body. It is characterized by a rapid onset and can lead to difficulty breathing, low blood pressure, and loss of consciousness. In paediatrics, anaphylaxis is often caused by food allergies, with nuts being the most common trigger. Other causes include drugs and insect venom, such as from a wasp sting.

When treating anaphylaxis, time is of the essence and there may not be enough time to look up medication doses. Adrenaline is the most important drug in managing anaphylaxis and should be administered as soon as possible. The recommended doses of adrenaline vary based on the age of the child. For children under 6 months, the dose is 150 micrograms, while for children between 6 months and 6 years, the dose remains the same. For children between 6 and 12 years, the dose is increased to 300 micrograms, and for adults and children over 12 years, the dose is 500 micrograms. Adrenaline can be repeated every 5 minutes if necessary.

The preferred site for administering adrenaline is the anterolateral aspect of the middle third of the thigh. This ensures quick absorption and effectiveness of the medication. It is important to follow the Resuscitation Council guidelines for anaphylaxis management, as they have recently been updated.

In some cases, it can be challenging to determine if a patient had a true episode of anaphylaxis. In such cases, serum tryptase levels may be measured, as they remain elevated for up to 12 hours following an acute episode of anaphylaxis. This can help confirm the diagnosis and guide further management.

Overall, prompt recognition and administration of adrenaline are crucial in managing anaphylaxis in paediatrics. Following the recommended doses and guidelines can help ensure the best outcomes for patients experiencing this severe allergic reaction.

An overdose of aspirin often leads to a combination of respiratory alkalosis and metabolic acidosis. Initially, the stimulation of the respiratory center causes hyperventilation and results in respiratory alkalosis. However, as the overdose progresses, the direct acidic effects of aspirin cause an increase in the anion gap and metabolic acidosis.

Here is a summary of common causes for different acid-base disorders:

Respiratory alkalosis can be caused by hyperventilation due to factors such as anxiety, pulmonary embolism, CNS disorders (such as stroke or encephalitis), altitude, pregnancy, and the early stages of aspirin overdose.

Respiratory acidosis can occur in individuals with chronic obstructive pulmonary disease (COPD), life-threatening asthma, pulmonary edema, sedative drug overdose (such as opioids or benzodiazepines), neuromuscular diseases, and obesity.

Metabolic alkalosis can be caused by vomiting, potassium depletion (often due to diuretic usage), Cushing’s syndrome, and Conn’s syndrome.

Metabolic acidosis with a raised anion gap can result from conditions such as lactic acidosis (caused by factors like hypoxemia, shock, sepsis, or tissue infarction), ketoacidosis (associated with diabetes, starvation, or excessive alcohol consumption), renal failure, and poisoning (including the late stages of aspirin overdose, methanol or ethylene glycol ingestion).

Metabolic acidosis with a normal anion gap can be seen in renal tubular acidosis, diarrhea, ammonium chloride ingestion, and adrenal insufficiency.

Mastoiditis occurs when a suppurative infection spreads from otitis media, affecting the middle ear, to the mastoid antrum. This infection causes inflammation in the mastoid and surrounding tissues, potentially leading to damage to the bone.

The mastoid antrum, also known as the tympanic antrum, is an air space located in the petrous part of the temporal bone. It connects to the mastoid cells at the back and the epitympanic recess through the aditus to the mastoid antrum.

The mastoid cells come in different types, varying in number and size. There are cellular cells with thin septa, diploeic cells that are marrow spaces with few air cells, and acellular cells that are neither cells nor marrow spaces.

These air spaces serve various functions, including acting as sound receptors, providing voice resonance, offering acoustic insulation and dissipation, protecting against physical damage, and reducing the weight of the cranium.

Overall, mastoiditis occurs when an infection from otitis media spreads to the mastoid antrum, causing inflammation and potential damage to the surrounding tissues and bone. The mastoid antrum and mastoid air cells within the temporal bone play important roles in sound reception, voice resonance, protection, and reducing cranial mass.

The Civil Contingencies Act 2004 establishes a framework for civil protection in the United Kingdom. This legislation categorizes local responders to major incidents into two groups, each with their own set of responsibilities.

Category 1 responders consist of organizations that play a central role in responding to most emergencies, such as the emergency services, local authorities, and NHS bodies. These Category 1 responders are obligated to fulfill a comprehensive range of civil protection duties. These duties include assessing the likelihood of emergencies occurring and using this information to inform contingency planning. They must also develop emergency plans, establish business continuity management arrangements, and ensure that information regarding civil protection matters is readily available to the public. Additionally, Category 1 responders are responsible for maintaining systems to warn, inform, and advise the public in the event of an emergency. They are expected to share information with other local responders to enhance coordination and efficiency. Furthermore, local authorities within this category are required to provide guidance and support to businesses and voluntary organizations regarding business continuity management.

On the other hand, Category 2 organizations, such as the Health and Safety Executive, transport companies, and utility companies, are considered co-operating bodies. While they may not be directly involved in the core planning work, they play a crucial role in incidents that impact their respective sectors. Category 2 responders have a more limited set of duties, primarily focused on cooperating and sharing relevant information with both Category 1 and Category 2 responders.

For more information on this topic, please refer to the Civil Contingencies Act 2004.

Distinguishing between unstable angina and other acute coronary syndromes can be determined by normal troponin results. Unstable angina is characterized by new onset angina or a sudden worsening of previously stable angina, often occurring at rest. This condition typically requires hospital admission. On the other hand, stable angina is predictable and occurs during physical exertion or emotional stress, lasting for a short duration of no more than 10 minutes and relieved within minutes of rest or sublingual nitrates.

To diagnose unstable angina, it is crucial to consider the nature of the chest pain and negative cardiac enzyme testing. The presence or absence of chest pain at rest and the response to rest and treatment with GTN are the most useful descriptors in distinguishing between stable and unstable angina. It is important to note that patients with unstable angina may not exhibit any changes on an electrocardiogram (ECG).

If troponin results are abnormal, it indicates a myocardial infarction rather than unstable angina.

Further Reading:

Acute Coronary Syndromes (ACS) is a term used to describe a group of conditions that involve the sudden reduction or blockage of blood flow to the heart. This can lead to a heart attack or unstable angina. ACS includes ST segment elevation myocardial infarction (STEMI), non-ST segment elevation myocardial infarction (NSTEMI), and unstable angina (UA).

The development of ACS is usually seen in patients who already have underlying coronary heart disease. This disease is characterized by the buildup of fatty plaques in the walls of the coronary arteries, which can gradually narrow the arteries and reduce blood flow to the heart. This can cause chest pain, known as angina, during physical exertion. In some cases, the fatty plaques can rupture, leading to a complete blockage of the artery and a heart attack.

There are both non modifiable and modifiable risk factors for ACS. non modifiable risk factors include increasing age, male gender, and family history. Modifiable risk factors include smoking, diabetes mellitus, hypertension, hypercholesterolemia, and obesity.

The symptoms of ACS typically include chest pain, which is often described as a heavy or constricting sensation in the central or left side of the chest. The pain may also radiate to the jaw or left arm. Other symptoms can include shortness of breath, sweating, and nausea/vomiting. However, it’s important to note that some patients, especially diabetics or the elderly, may not experience chest pain.

The diagnosis of ACS is typically made based on the patient’s history, electrocardiogram (ECG), and blood tests for cardiac enzymes, specifically troponin. The ECG can show changes consistent with a heart attack, such as ST segment elevation or depression, T wave inversion, or the presence of a new left bundle branch block. Elevated troponin levels confirm the diagnosis of a heart attack.

The management of ACS depends on the specific condition and the patient’s risk factors. For STEMI, immediate coronary reperfusion therapy, either through primary percutaneous coronary intervention (PCI) or fibrinolysis, is recommended. In addition to aspirin, a second antiplatelet agent is usually given. For NSTEMI or unstable angina, the treatment approach may involve reperfusion therapy or medical management, depending on the patient’s risk of future cardiovascular events.

When treating adults with bradycardia, a maximum of 6 doses of atropine 500 mcg can be administered. Each dose is given intravenously every 3-5 minutes. The total dose should not exceed 3mg.

Further Reading:

Causes of Bradycardia:
– Physiological: Athletes, sleeping
– Cardiac conduction dysfunction: Atrioventricular block, sinus node disease
– Vasovagal & autonomic mediated: Vasovagal episodes, carotid sinus hypersensitivity
– Hypothermia
– Metabolic & electrolyte disturbances: Hypothyroidism, hyperkalaemia, hypermagnesemia
– Drugs: Beta-blockers, calcium channel blockers, digoxin, amiodarone
– Head injury: Cushing’s response
– Infections: Endocarditis
– Other: Sarcoidosis, amyloidosis

Presenting symptoms of Bradycardia:
– Presyncope (dizziness, lightheadedness)
– Syncope
– Breathlessness
– Weakness
– Chest pain
– Nausea

Management of Bradycardia:
– Assess and monitor for adverse features (shock, syncope, myocardial ischaemia, heart failure)
– Treat reversible causes of bradycardia
– Pharmacological treatment: Atropine is first-line, adrenaline and isoprenaline are second-line
– Transcutaneous pacing if atropine is ineffective
– Other drugs that may be used: Aminophylline, dopamine, glucagon, glycopyrrolate

Bradycardia Algorithm:
– Follow the algorithm for management of bradycardia, which includes assessing and monitoring for adverse features, treating reversible causes, and using appropriate medications or pacing as needed.
https://acls-algorithms.com/wp-content/uploads/2020/12/Website-Bradycardia-Algorithm-Diagram.pdf

The mortality rate linked to sepsis can vary depending on various factors such as the patient’s age, overall health, and the severity of the infection. However, on average, the mortality rate for sepsis is estimated to be around 30%.

Further Reading:

There are multiple definitions of sepsis, leading to confusion among healthcare professionals. The Sepsis 3 definition describes sepsis as life-threatening organ dysfunction caused by a dysregulated host response to infection. The Sepsis 2 definition includes infection plus two or more SIRS criteria. The NICE definition states that sepsis is a clinical syndrome triggered by the presence of infection in the blood, activating the body’s immune and coagulation systems. The Sepsis Trust defines sepsis as a dysregulated host response to infection mediated by the immune system, resulting in organ dysfunction, shock, and potentially death.

The confusion surrounding sepsis terminology is further compounded by the different versions of sepsis definitions, known as Sepsis 1, Sepsis 2, and Sepsis 3. The UK organizations RCEM and NICE have not fully adopted the changes introduced in Sepsis 3, causing additional confusion. While Sepsis 3 introduces the use of SOFA scores and abandons SIRS criteria, NICE and the Sepsis Trust have rejected the use of SOFA scores and continue to rely on SIRS criteria. This discrepancy creates challenges for emergency department doctors in both exams and daily clinical practice.

To provide some clarity, RCEM now recommends referring to national standards organizations such as NICE, SIGN, BTS, or others relevant to the area. The Sepsis Trust, in collaboration with RCEM and NICE, has published a toolkit that serves as a definitive reference point for sepsis management based on the sepsis 3 update.

There is a consensus internationally that the terms SIRS and severe sepsis are outdated and should be abandoned. Instead, the terms sepsis and septic shock should be used. NICE defines septic shock as a life-threatening condition characterized by low blood pressure despite adequate fluid replacement and organ dysfunction or failure. Sepsis 3 defines septic shock as persisting hypotension requiring vasopressors to maintain a mean arterial pressure of 65 mmHg or more, along with a serum lactate level greater than 2 mmol/l despite adequate volume resuscitation.

NICE encourages clinicians to adopt an approach of considering sepsis in all patients, rather than relying solely on strict definitions. Early warning or flag systems can help identify patients with possible sepsis.

Before performing arterial blood gas sampling, it is necessary to disinfect the skin. This is typically done using alcohol, which should be applied and given enough time to dry completely before proceeding with the skin puncture. In the UK, it is common to use solutions that combine alcohol with Chlorhexidine, such as Chloraprep® (2).

Further Reading:

Arterial blood gases (ABG) are an important diagnostic tool used to assess a patient’s acid-base status and respiratory function. When obtaining an ABG sample, it is crucial to prioritize safety measures to minimize the risk of infection and harm to the patient. This includes performing hand hygiene before and after the procedure, wearing gloves and protective equipment, disinfecting the puncture site with alcohol, using safety needles when available, and properly disposing of equipment in sharps bins and contaminated waste bins.

To reduce the risk of harm to the patient, it is important to test for collateral circulation using the modified Allen test for radial artery puncture. Additionally, it is essential to inquire about any occlusive vascular conditions or anticoagulation therapy that may affect the procedure. The puncture site should be checked for signs of infection, injury, or previous surgery. After the test, pressure should be applied to the puncture site or the patient should be advised to apply pressure for at least 5 minutes to prevent bleeding.

Interpreting ABG results requires a systematic approach. The core set of results obtained from a blood gas analyser includes the partial pressures of oxygen and carbon dioxide, pH, bicarbonate concentration, and base excess. These values are used to assess the patient’s acid-base status.

The pH value indicates whether the patient is in acidosis, alkalosis, or within the normal range. A pH less than 7.35 indicates acidosis, while a pH greater than 7.45 indicates alkalosis.

The respiratory system is assessed by looking at the partial pressure of carbon dioxide (pCO2). An elevated pCO2 contributes to acidosis, while a low pCO2 contributes to alkalosis.

The metabolic aspect is assessed by looking at the bicarbonate (HCO3-) level and the base excess. A high bicarbonate concentration and base excess indicate alkalosis, while a low bicarbonate concentration and base excess indicate acidosis.

Analyzing the pCO2 and base excess values can help determine the primary disturbance and whether compensation is occurring. For example, a respiratory acidosis (elevated pCO2) may be accompanied by metabolic alkalosis (elevated base excess) as a compensatory response.

The anion gap is another important parameter that can help determine the cause of acidosis. It is calculated by subtracting the sum of chloride and bicarbonate from the sum of sodium and potassium.

Hyperkalaemia, a condition characterized by high levels of potassium in the blood, can be identified through specific changes seen on an electrocardiogram (ECG). One of these changes is the tenting of T-waves, where the T-waves become tall and pointed. Additionally, the P-wave, which represents atrial depolarization, may widen and flatten. Other ECG changes associated with hyperkalaemia include a prolonged PR interval, flat P-waves, wide P-waves, widened QRS complex, the appearance of a sine wave pattern, and the possibility of heart block.

Further Reading:

Vasoactive drugs can be classified into three categories: inotropes, vasopressors, and unclassified. Inotropes are drugs that alter the force of muscular contraction, particularly in the heart. They primarily stimulate adrenergic receptors and increase myocardial contractility. Commonly used inotropes include adrenaline, dobutamine, dopamine, isoprenaline, and ephedrine.

Vasopressors, on the other hand, increase systemic vascular resistance (SVR) by stimulating alpha-1 receptors, causing vasoconstriction. This leads to an increase in blood pressure. Commonly used vasopressors include norepinephrine, metaraminol, phenylephrine, and vasopressin.

Electrolytes, such as potassium, are essential for proper bodily function. Solutions containing potassium are often given to patients to prevent or treat hypokalemia (low potassium levels). However, administering too much potassium can lead to hyperkalemia (high potassium levels), which can cause dangerous arrhythmias. It is important to monitor potassium levels and administer it at a controlled rate to avoid complications.

Hyperkalemia can be caused by various factors, including excessive potassium intake, decreased renal excretion, endocrine disorders, certain medications, metabolic acidosis, tissue destruction, and massive blood transfusion. It can present with cardiovascular, respiratory, gastrointestinal, and neuromuscular symptoms. ECG changes, such as tall tented T-waves, prolonged PR interval, flat P-waves, widened QRS complex, and sine wave, are also characteristic of hyperkalemia.

In summary, vasoactive drugs can be categorized as inotropes, vasopressors, or unclassified. Inotropes increase myocardial contractility, while vasopressors increase systemic vascular resistance. Electrolytes, particularly potassium, are important for bodily function, but administering too much can lead to hyperkalemia. Monitoring potassium levels and ECG changes is crucial in managing hyperkalemia.

An Addisonian crisis is characterized by several distinct features. These include experiencing pain in the legs and abdomen, as well as symptoms of vomiting and dehydration. Hypotension, or low blood pressure, is also commonly observed during an Addisonian crisis. Confusion and psychosis may also occur, along with the presence of a fever. In some cases, convulsions may be present as well. Additionally, individuals experiencing an Addisonian crisis may also exhibit hypoglycemia, hyponatremia, hyperkalemia, hypercalcemia, eosinophilia, and metabolic acidosis.

The ulnar nerve originates from the medial cord of the brachial plexus, specifically from the C8-T1 nerve roots. It may also carry fibers from C7 on occasion. This nerve has both motor and sensory functions.

In terms of motor function, the ulnar nerve innervates the muscles of the hand, excluding the thenar muscles and the lateral two lumbricals (which are supplied by the median nerve). It also innervates two muscles in the anterior forearm: the flexor carpi ulnaris and the medial half of the flexor digitorum profundus.

Regarding sensory function, the ulnar nerve provides innervation to the anterior and posterior surfaces of the medial one and a half fingers, as well as the associated palm and dorsal hand area. There are three sensory branches responsible for the cutaneous innervation of the ulnar nerve. Two of these branches arise in the forearm and travel into the hand: the palmar cutaneous branch, which innervates the skin of the medial half of the palm, and the dorsal cutaneous branch, which innervates the dorsal skin of the medial one and a half fingers and the associated dorsal hand. The third branch arises in the hand and is called the superficial branch, which innervates the palmar surface of the medial one and a half fingers.

When the ulnar nerve is damaged at the elbow, the flexor carpi ulnaris and the medial half of the flexor digitorum profundus muscles in the anterior forearm will be spared. However, if the ulnar nerve is injured at the wrist, these muscles will be affected. Additionally, when the ulnar nerve is damaged at the elbow, flexion of the wrist can still occur due to the intact median nerve, but it will be accompanied by abduction as the flexor carpi ulnaris adducts the hand. On the other hand, wrist flexion will be unaffected when the ulnar nerve is damaged at the wrist.

The sensory function also differs depending on the site of damage. When the ulnar nerve is damaged at the elbow, all three cutaneous branches will be affected, resulting in complete sensory loss in the areas innervated by the ulnar nerve. However, if the damage occurs at the wrist, the two branches that arise in the forearm may be spared.

Damage to the ulnar nerve at either the elbow or wrist leads to a characteristic claw hand appearance, characterized by hyperextension of the metacarpophalangeal joints and flexion of the distal and proximal interphalangeal joint of the little and ring fingers.

Addison’s disease is characterized by several classical biochemical features. One of these features is an increase in ACTH levels, which is a hormone that stimulates the production of cortisol. Additionally, individuals with Addison’s disease often have elevated serum renin levels, which is an enzyme involved in regulating blood pressure. Another common biochemical feature is hyponatremia, which refers to low levels of sodium in the blood. Hyperkalemia, or high levels of potassium, is also frequently observed in individuals with Addison’s disease. Furthermore, hypercalcemia, an excess of calcium in the blood, may be present. Hypoglycemia, or low blood sugar levels, is another characteristic feature. Lastly, metabolic acidosis, a condition where the body produces too much acid or cannot eliminate it properly, is often seen in individuals with Addison’s disease.

The normal intracranial pressure (ICP) for an adult lying down is typically between 5 and 15 mmHg.

Further Reading:

Intracranial pressure (ICP) refers to the pressure within the craniospinal compartment, which includes neural tissue, blood, and cerebrospinal fluid (CSF). Normal ICP for a supine adult is 5-15 mmHg. The body maintains ICP within a narrow range through shifts in CSF production and absorption. If ICP rises, it can lead to decreased cerebral perfusion pressure, resulting in cerebral hypoperfusion, ischemia, and potentially brain herniation.

The cranium, which houses the brain, is a closed rigid box in adults and cannot expand. It is made up of 8 bones and contains three main components: brain tissue, cerebral blood, and CSF. Brain tissue accounts for about 80% of the intracranial volume, while CSF and blood each account for about 10%. The Monro-Kellie doctrine states that the sum of intracranial volumes is constant, so an increase in one component must be offset by a decrease in the others.

There are various causes of raised ICP, including hematomas, neoplasms, brain abscesses, edema, CSF circulation disorders, venous sinus obstruction, and accelerated hypertension. Symptoms of raised ICP include headache, vomiting, pupillary changes, reduced cognition and consciousness, neurological signs, abnormal fundoscopy, cranial nerve palsy, hemiparesis, bradycardia, high blood pressure, irregular breathing, focal neurological deficits, seizures, stupor, coma, and death.

Measuring ICP typically requires invasive procedures, such as inserting a sensor through the skull. Management of raised ICP involves a multi-faceted approach, including antipyretics to maintain normothermia, seizure control, positioning the patient with a 30º head up tilt, maintaining normal blood pressure, providing analgesia, using drugs to lower ICP (such as mannitol or saline), and inducing hypocapnoeic vasoconstriction through hyperventilation. If these measures are ineffective, second-line therapies like barbiturate coma, optimised hyperventilation, controlled hypothermia, or decompressive craniectomy may be considered.

Altitude sickness is usually experienced at altitudes above 2,500 meters (8,000 ft), although some individuals may be affected at lower altitudes. It is important to note that climbers in the UK, where the highest peak is Ben Nevis at 1,345 meters, do not need to worry about altitude sickness.

Further Reading:

High Altitude Illnesses

Altitude & Hypoxia:
– As altitude increases, atmospheric pressure decreases and inspired oxygen pressure falls.
– Hypoxia occurs at altitude due to decreased inspired oxygen.
– At 5500m, inspired oxygen is approximately half that at sea level, and at 8900m, it is less than a third.

Acute Mountain Sickness (AMS):
– AMS is a clinical syndrome caused by hypoxia at altitude.
– Symptoms include headache, anorexia, sleep disturbance, nausea, dizziness, fatigue, malaise, and shortness of breath.
– Symptoms usually occur after 6-12 hours above 2500m.
– Risk factors for AMS include previous AMS, fast ascent, sleeping at altitude, and age <50 years old.
– The Lake Louise AMS score is used to assess the severity of AMS.
– Treatment involves stopping ascent, maintaining hydration, and using medication for symptom relief.
– Medications for moderate to severe symptoms include dexamethasone and acetazolamide.
– Gradual ascent, hydration, and avoiding alcohol can help prevent AMS.

High Altitude Pulmonary Edema (HAPE):
– HAPE is a progression of AMS but can occur without AMS symptoms.
– It is the leading cause of death related to altitude illness.
– Risk factors for HAPE include rate of ascent, intensity of exercise, absolute altitude, and individual susceptibility.
– Symptoms include dyspnea, cough, chest tightness, poor exercise tolerance, cyanosis, low oxygen saturations, tachycardia, tachypnea, crepitations, and orthopnea.
– Management involves immediate descent, supplemental oxygen, keeping warm, and medication such as nifedipine.

High Altitude Cerebral Edema (HACE):
– HACE is thought to result from vasogenic edema and increased vascular pressure.
– It occurs 2-4 days after ascent and is associated with moderate to severe AMS symptoms.
– Symptoms include headache, hallucinations, disorientation, confusion, ataxia, drowsiness, seizures, and manifestations of raised intracranial pressure.
– Immediate descent is crucial for management, and portable hyperbaric therapy may be used if descent is not possible.
– Medication for treatment includes dexamethasone and supplemental oxygen. Acetazolamide is typically used for prophylaxis.

From the moment a child is born, the mother is automatically granted parental responsibility. However, fathers must fulfill specific criteria in order to have the same rights. A father can provide consent on behalf of the child if he meets any of the following conditions: being married to the child’s mother, having been married to the child’s mother at the time of birth but subsequently divorced, being listed as the child’s father on the birth certificate, obtaining parental responsibility through a court order or a parental responsibility agreement with the mother, or legally adopting the child.

Further Reading:

Patients have the right to determine what happens to their own bodies, and for consent to be valid, certain criteria must be met. These criteria include the person being informed about the intervention, having the capacity to consent, and giving consent voluntarily and freely without any pressure or undue influence.

In order for a person to be deemed to have capacity to make a decision on a medical intervention, they must be able to understand the decision and the information provided, retain that information, weigh up the pros and cons, and communicate their decision.

Valid consent can only be provided by adults, either by the patient themselves, a person authorized under a Lasting Power of Attorney, or someone with the authority to make treatment decisions, such as a court-appointed deputy or a guardian with welfare powers.

In the UK, patients aged 16 and over are assumed to have the capacity to consent. If a patient is under 18 and appears to lack capacity, parental consent may be accepted. However, a young person of any age may consent to treatment if they are considered competent to make the decision, known as Gillick competence. Parental consent may also be given by those with parental responsibility.

The Fraser guidelines apply to the prescription of contraception to under 16’s without parental involvement. These guidelines allow doctors to provide contraceptive advice and treatment without parental consent if certain criteria are met, including the young person understanding the advice, being unable to be persuaded to inform their parents, and their best interests requiring them to receive contraceptive advice or treatment.

Competent adults have the right to refuse consent, even if it is deemed unwise or likely to result in harm. However, there are exceptions to this, such as compulsory treatment authorized by the mental health act or if the patient is under 18 and refusing treatment would put their health at serious risk.

In emergency situations where a patient is unable to give consent, treatment may be provided without consent if it is immediately necessary to save their life or prevent a serious deterioration of their condition. Any treatment decision made without consent must be in the patient’s best interests, and if a decision is time-critical and the patient is unlikely to regain capacity in time, a best interest decision should be made. The treatment provided should be the least restrictive on the patient’s future choices.

The flight of ideas observed in mania is considered a type of thought disorder. The primary clinical characteristics of mania include changes in mood, behavior, speech, and thought.

In terms of mood, individuals experiencing mania often exhibit an elated mood and a sense of euphoria. They may also display irritability and hostility instead of their usual amiability. Additionally, there is an increase in enthusiasm.

Regarding behavior, individuals in a manic state tend to be overactive and have heightened energy levels. They may lose their normal social inhibitions and engage in more risk-taking behaviors. This can also manifest as increased sexual promiscuity and libido, as well as an increased appetite.

In terms of speech, individuals with mania often speak in a pressured and rapid manner. Their conversations may be cheerful, and they may engage in rhyming or punning.

Lastly, in terms of thought, the flight of ideas is a prominent feature of mania and is classified as a thought disorder. Individuals may experience grandiose delusions and have an inflated sense of self-esteem. They may also struggle with poor attention and concentration.

Overall, mania is characterized by a range of symptoms that affect mood, behavior, speech, and thought.

Traumatic aortic rupture, also known as traumatic aortic disruption or transection, occurs when the aorta is torn or ruptured due to physical trauma. This condition often leads to sudden death because of severe bleeding. Motor vehicle accidents and falls from great heights are the most common causes of this injury.

The patients with the highest chances of survival are those who have an incomplete tear near the ligamentum arteriosum of the proximal descending aorta, close to where the left subclavian artery branches off. The presence of an intact adventitial layer or contained mediastinal hematoma helps maintain continuity and prevents immediate bleeding and death. If promptly identified and treated, survivors of these injuries can recover. In cases where traumatic aortic rupture leads to sudden death, approximately 50% of patients have damage at the aortic isthmus, while around 15% have damage in either the ascending aorta or the aortic arch.

Initial chest X-rays may show signs consistent with a traumatic aortic injury. However, false-positive and false-negative results can occur, and sometimes there may be no abnormalities visible on the X-ray. Some of the possible X-ray findings include a widened mediastinum, hazy left lung field, obliteration of the aortic knob, fractures of the 1st and 2nd ribs, deviation of the trachea to the right, presence of a pleural cap, elevation and rightward shift of the right mainstem bronchus, depression of the left mainstem bronchus, obliteration of the space between the pulmonary artery and aorta, and deviation of the esophagus or NG tube to the right.

A helical contrast-enhanced CT scan of the chest is the preferred initial investigation for suspected blunt aortic injury. It has proven to be highly accurate, with close to 100% sensitivity and specificity. CT scanning should be performed liberally, as chest X-ray findings can be unreliable. However, hemodynamically unstable patients should not be placed in a CT scanner. If the CT results are inconclusive, aortography or trans-oesophageal echo can be performed for further evaluation.

Immediate surgical intervention is necessary for these injuries. Endovascular repair is the most common method used and has excellent short-term outcomes. Open repair may also be performed depending on the circumstances. It is important to control heart rate and blood pressure during stabilization to reduce the risk of rupture. Pain should be managed with appropriate analgesic

The ATLS guidelines categorize chest injuries in trauma into two groups: life-threatening injuries that require immediate identification and treatment in the primary survey, and potentially life-threatening injuries that should be identified and treated in the secondary survey.

During the primary survey, the focus is on identifying and treating life-threatening thoracic injuries. These include airway obstruction, tracheobronchial tree injury, tension pneumothorax, open pneumothorax, massive haemothorax, and cardiac tamponade. Prompt recognition and intervention are crucial in order to prevent further deterioration and potential fatality.

In the secondary survey, attention is given to potentially life-threatening injuries that may not be immediately apparent. These include simple pneumothorax, haemothorax, flail chest, pulmonary contusion, blunt cardiac injury, traumatic aortic disruption, traumatic diaphragmatic injury, and blunt oesophageal rupture. These injuries may not pose an immediate threat to life, but they still require identification and appropriate management to prevent complications and ensure optimal patient outcomes.

By dividing chest injuries into these two categories and addressing them in a systematic manner, healthcare providers can effectively prioritize and manage trauma patients, ultimately improving their chances of survival and recovery.

After undergoing nasal cautery, it is recommended to follow these steps for proper treatment:

1. Gently dab the cauterized area with a clean cotton bud to remove any excess chemical or blood.
2. Apply a topical antiseptic preparation to the area.
3. As the first line of treatment, prescribe Naseptin® cream (containing chlorhexidine and neomycin) to be applied to the nostrils four times daily for a duration of 10 days. However, if the patient has allergies to neomycin, peanut, or soya, prescribe mupirocin nasal ointment instead. This should be applied to the nostrils two to three times a day for 5-7 days.
4. Advise the patient to avoid blowing their nose for a few hours.

These steps will help ensure proper healing and minimize any potential complications after nasal cautery.

Further Reading:

Epistaxis, or nosebleed, is a common condition that can occur in both children and older adults. It is classified as either anterior or posterior, depending on the location of the bleeding. Anterior epistaxis usually occurs in younger individuals and arises from the nostril, most commonly from an area called Little’s area. These bleeds are usually not severe and account for the majority of nosebleeds seen in hospitals. Posterior nosebleeds, on the other hand, occur in older patients with conditions such as hypertension and atherosclerosis. The bleeding in posterior nosebleeds is likely to come from both nostrils and originates from the superior or posterior parts of the nasal cavity or nasopharynx.

The management of epistaxis involves assessing the patient for signs of instability and implementing measures to control the bleeding. Initial measures include sitting the patient upright with their upper body tilted forward and their mouth open. Firmly pinching the cartilaginous part of the nose for 10-15 minutes without releasing the pressure can also help stop the bleeding. If these measures are successful, a cream called Naseptin or mupirocin nasal ointment can be prescribed for further treatment.

If bleeding persists after the initial measures, nasal cautery or nasal packing may be necessary. Nasal cautery involves using a silver nitrate stick to cauterize the bleeding point, while nasal packing involves inserting nasal tampons or inflatable nasal packs to stop the bleeding. In cases of posterior bleeding, posterior nasal packing or surgery to tie off the bleeding vessel may be considered.

Complications of epistaxis can include nasal bleeding, hypovolemia, anemia, aspiration, and even death. Complications specific to nasal packing include sinusitis, septal hematoma or abscess, pressure necrosis, toxic shock syndrome, and apneic episodes. Nasal cautery can lead to complications such as septal perforation and caustic injury to the surrounding skin.

In children under the age of 2 presenting with epistaxis, it is important to refer them for further investigation as an underlying cause is more likely in this age group.

In order to gain a comprehensive understanding of AF management, it is crucial to familiarize oneself with the terminology used to describe its various subtypes. These terms help categorize different episodes of AF based on their characteristics and outcomes.

Acute AF refers to any episode that occurs within the previous 48 hours. It can manifest with or without symptoms and may or may not recur. On the other hand, paroxysmal AF describes episodes that spontaneously end within 7 days, typically within 48 hours. While these episodes are often recurrent, they can progress into a sustained form of AF.

Recurrent AF is defined as experiencing two or more episodes of AF. If the episodes self-terminate, they are classified as paroxysmal AF. However, if the episodes do not self-terminate, they are categorized as persistent AF. Persistent AF lasts longer than 7 days or has occurred after a previous cardioversion. To terminate persistent AF, electrical or pharmacological intervention is required. In some cases, persistent AF can progress into permanent AF.

Permanent AF, also known as Accepted AF, refers to episodes that cannot be successfully terminated, have relapsed after termination, or where cardioversion is not pursued. This subtype signifies a more chronic and ongoing form of AF.

By understanding and utilizing these terms, healthcare professionals can effectively communicate and manage the different subtypes of AF.

Theophylline is a medication used to treat severe asthma. It is a bronchodilator that comes in modified-release forms, which can maintain therapeutic levels in the blood for 12 hours. Theophylline works by inhibiting phosphodiesterase and blocking the breakdown of cyclic AMP. It also competes with adenosine on A1 and A2 receptors.

Achieving the right dose of theophylline can be challenging because there is a narrow range between therapeutic and toxic levels. The half-life of theophylline can be influenced by various factors, further complicating dosage adjustments. It is recommended to aim for serum levels of 10-20 mg/l six to eight hours after the last dose.

Unlike many other medications, the specific brand of theophylline can significantly impact its effects. Therefore, it is important to prescribe theophylline by both its brand name and generic name.

Several factors can increase the half-life of theophylline, including heart failure, cirrhosis, viral infections, and certain drugs. Conversely, smoking, heavy drinking, and certain medications can decrease the half-life of theophylline.

There are several drugs that can either increase or decrease the plasma concentration of theophylline. Calcium channel blockers, cimetidine, fluconazole, macrolides, methotrexate, and quinolones can increase the concentration. On the other hand, carbamazepine, phenobarbitol, phenytoin, rifampicin, and St. John’s wort can decrease the concentration.

The clinical symptoms of theophylline toxicity are more closely associated with acute overdose rather than chronic overexposure. Common symptoms include headache, dizziness, nausea, vomiting, abdominal pain, rapid heartbeat, dysrhythmias, seizures, mild metabolic acidosis, low potassium, low magnesium, low phosphates, abnormal calcium levels, and high blood sugar.

Seizures are more prevalent in acute overdose cases, while chronic overdose typically presents with minimal gastrointestinal symptoms. Cardiac dysrhythmias are more common in chronic overdose situations compared to acute overdose.

Blood transfusion is a potentially life-saving treatment that can provide great clinical benefits. However, it also carries several risks and potential problems. These include immunological complications, administration errors, infections, and immune dilution. While there has been an increased awareness of these risks and improved reporting systems, transfusion errors and serious adverse reactions still occur and may go unreported.

One specific transfusion reaction is transfusion-associated circulatory overload (TACO), which occurs when a large volume of blood is rapidly infused. It is the second leading cause of transfusion-related deaths, accounting for about 20% of fatalities. TACO is more likely to occur in patients with diminished cardiac reserve or chronic anemia, particularly in the elderly, infants, and severely anemic patients.

The typical clinical features of TACO include acute respiratory distress, tachycardia, hypertension, acute or worsening pulmonary edema on chest X-ray, and evidence of positive fluid balance. The B-type natriuretic peptide (BNP) can be a useful diagnostic tool for TACO, with levels usually elevated to at least 1.5 times the pre-transfusion baseline.

In many cases, simply slowing the transfusion rate, placing the patient in an upright position, and administering diuretics can be sufficient for managing TACO. In more severe cases, the transfusion should be stopped, and non-invasive ventilation may be considered.

The most commonly identified causative pathogen in patients with spontaneous bacterial peritonitis (SBP) is Escherichia coli. SBP is a serious infection that occurs in individuals with liver cirrhosis, where bacteria from the gut migrate into the peritoneal cavity, leading to infection and inflammation. E. coli is a gram-negative bacterium commonly found in the intestines and is known to be a frequent cause of SBP. It is important to promptly diagnose and treat SBP to prevent further complications and improve patient outcomes.

Further Reading:

Cirrhosis is a condition where the liver undergoes structural changes, resulting in dysfunction of its normal functions. It can be classified as either compensated or decompensated. Compensated cirrhosis refers to a stage where the liver can still function effectively with minimal symptoms, while decompensated cirrhosis is when the liver damage is severe and clinical complications are present.

Cirrhosis develops over a period of several years due to repeated insults to the liver. Risk factors for cirrhosis include alcohol misuse, hepatitis B and C infection, obesity, type 2 diabetes, autoimmune liver disease, genetic conditions, certain medications, and other rare conditions.

The prognosis of cirrhosis can be assessed using the Child-Pugh score, which predicts mortality based on parameters such as bilirubin levels, albumin levels, INR, ascites, and encephalopathy. The score ranges from A to C, with higher scores indicating a poorer prognosis.

Complications of cirrhosis include portal hypertension, ascites, hepatic encephalopathy, variceal hemorrhage, increased infection risk, hepatocellular carcinoma, and cardiovascular complications.

Diagnosis of cirrhosis is typically done through liver function tests, blood tests, viral hepatitis screening, and imaging techniques such as transient elastography or acoustic radiation force impulse imaging. Liver biopsy may also be performed in some cases.

Management of cirrhosis involves treating the underlying cause, controlling risk factors, and monitoring for complications. Complications such as ascites, spontaneous bacterial peritonitis, oesophageal varices, and hepatic encephalopathy require specific management strategies.

Overall, cirrhosis is a progressive condition that requires ongoing monitoring and management to prevent further complications and improve outcomes for patients.

This patient has developed an acute auricular subchondral haematoma. It occurs when blood and serum collect in the space between the cartilage and the supporting perichondrium due to a shearing force that separates the perichondrium from the underlying cartilage.

It is important to differentiate this condition from cauliflower ear, which is a common complication that arises when an auricular haematoma is not treated. If a subchondral haematoma is left untreated, the damaged perichondrium forms a fibrocartilage plate, leading to scarring and cartilage regeneration. This results in an irregular and thickened pinna, typically along the helical rim.

The management of an auricular haematoma involves the following steps:

1. Infiltration with a local anaesthetic, such as 1% lidocaine.
2. Drainage or needle aspiration of the haematoma.
3. Application of firm packing and compression bandaging to prevent re-accumulation.
4. Administration of broad-spectrum antibiotics.

By following these management steps, the patient can effectively address and treat the auricular haematoma.

Status epilepticus is a condition characterized by continuous seizure activity lasting for 5 minutes or more without the return of consciousness, or recurrent seizures (2 or more) without a period of neurological recovery in between. In such cases, the next step in managing the patient would be to administer a second dose of benzodiazepine. Since the patient already has an intravenous line in place, this would be the most appropriate route to choose.

The management of status epilepticus involves several general measures, which are outlined in the following table:

1st stage (Early status, 0-10 minutes):
– Secure the airway and provide resuscitation
– Administer oxygen
– Assess cardiorespiratory function
– Establish intravenous access

2nd stage (0-30 minutes):
– Institute regular monitoring
– Consider the possibility of non-epileptic status
– Start emergency antiepileptic drug (AED) therapy
– Perform emergency investigations
– Administer glucose (50 ml of 50% solution) and/or intravenous thiamine as Pabrinex if there is any suggestion of alcohol abuse or impaired nutrition
– Treat severe acidosis if present

3rd stage (0-60 minutes):
– Determine the underlying cause of status epilepticus
– Alert the anaesthetist and intensive care unit (ITU)
– Identify and treat any medical complications
– Consider pressor therapy when appropriate

4th stage (30-90 minutes):
– Transfer the patient to the intensive care unit
– Establish intensive care and EEG monitoring
– Initiate intracranial pressure monitoring if necessary
– Start initial long-term, maintenance AED therapy

Emergency investigations for status epilepticus include blood tests for gases, glucose, renal and liver function, calcium and magnesium, full blood count (including platelets), blood clotting, and AED drug levels. Serum and urine samples should be saved for future analysis, including toxicology if the cause of the convulsive status epilepticus is uncertain. A chest radiograph may be performed to evaluate the possibility of aspiration. Additional investigations, such as brain imaging or lumbar puncture, depend on the clinical circumstances.

Monitoring during the management of status epilepticus involves regular neurological observations and measurements of pulse, blood pressure, and temperature. ECG, biochemistry, blood gases, clotting, and blood count should also be monitored.

Haloperidol, when administered during the third trimester of pregnancy, can lead to extrapyramidal symptoms in the newborn. These symptoms may include agitation, poor feeding, excessive sleepiness, and difficulty breathing. The severity of these side effects can vary, with some infants requiring intensive care and extended hospital stays. It is important to closely monitor exposed neonates for signs of extrapyramidal syndrome or withdrawal. Haloperidol should only be used during pregnancy if the benefits clearly outweigh the risks to the fetus.

Below is a list outlining commonly encountered drugs that have adverse effects during pregnancy:

ACE inhibitors (e.g. ramipril): If given during the second and third trimesters, these drugs can cause hypoperfusion, renal failure, and the oligohydramnios sequence.

Aminoglycosides (e.g. gentamicin): These drugs can cause ototoxicity and deafness in the fetus.

Aspirin: High doses of aspirin can lead to first-trimester abortions, delayed onset of labor, premature closure of the fetal ductus arteriosus, and fetal kernicterus. However, low doses (e.g. 75 mg) do not pose significant risks.

Benzodiazepines (e.g. diazepam): When administered late in pregnancy, these drugs can cause respiratory depression and a neonatal withdrawal syndrome.

Calcium-channel blockers: If given during the first trimester, these drugs can cause phalangeal abnormalities. If given during the second and third trimesters, they can result in fetal growth retardation.

Carbamazepine: This drug can lead to hemorrhagic disease of the newborn and neural tube defects.

Chloramphenicol: Administration of chloramphenicol can cause gray baby syndrome in newborns.

Corticosteroids: If given during the first trimester, corticosteroids may cause orofacial clefts in the fetus.

Danazol: When administered during the first trimester, danazol can cause masculinization of the female fetuses genitals.

Finasteride: Pregnant women should avoid handling finasteride as crushed or broken tablets can be absorbed through the skin and affect male sex organ development.

Haloperidol: If given during the first trimester, haloperidol may cause limb malformations. If given during the third trimester, there is an increased risk of extrapyramidal symptoms in the neonate.

A peptic ulcer is a condition where there is a hole or defect in the lining of the stomach or duodenum that is larger than 5mm in diameter. If left untreated, there is a risk that the ulcer may perforate, meaning it can create a rupture or tear in the lining. It is important to note that if the defect is smaller than 5mm, it is classified as an erosion rather than an ulcer.

Further Reading:

Peptic ulcer disease (PUD) is a condition characterized by a break in the mucosal lining of the stomach or duodenum. It is caused by an imbalance between factors that promote mucosal damage, such as gastric acid, pepsin, Helicobacter pylori infection, and NSAID drug use, and factors that maintain mucosal integrity, such as prostaglandins, mucus lining, bicarbonate, and mucosal blood flow.

The most common causes of peptic ulcers are H. pylori infection and NSAID use. Other factors that can contribute to the development of ulcers include smoking, alcohol consumption, certain medications (such as steroids), stress, autoimmune conditions, and tumors.

Diagnosis of peptic ulcers involves screening for H. pylori infection through breath or stool antigen tests, as well as upper gastrointestinal endoscopy. Complications of PUD include bleeding, perforation, and obstruction. Acute massive hemorrhage has a case fatality rate of 5-10%, while perforation can lead to peritonitis with a mortality rate of up to 20%.

The symptoms of peptic ulcers vary depending on their location. Duodenal ulcers typically cause pain that is relieved by eating, occurs 2-3 hours after eating and at night, and may be accompanied by nausea and vomiting. Gastric ulcers, on the other hand, cause pain that occurs 30 minutes after eating and may be associated with nausea and vomiting.

Management of peptic ulcers depends on the underlying cause and presentation. Patients with active gastrointestinal bleeding require risk stratification, volume resuscitation, endoscopy, and proton pump inhibitor (PPI) therapy. Those with perforated ulcers require resuscitation, antibiotic treatment, analgesia, PPI therapy, and urgent surgical review.

For stable patients with peptic ulcers, lifestyle modifications such as weight loss, avoiding trigger foods, eating smaller meals, quitting smoking, reducing alcohol consumption, and managing stress and anxiety are recommended. Medication review should be done to stop causative drugs if possible. PPI therapy, with or without H. pylori eradication therapy, is also prescribed. H. pylori testing is typically done using a carbon-13 urea breath test or stool antigen test, and eradication therapy involves a 7-day triple therapy regimen of antibiotics and PPI.

The CENTOR score is a clinical prediction rule used to assess the likelihood of a patient having a streptococcal infection, which is commonly associated with sore throat. It is based on the presence or absence of four clinical criteria: fever, tonsillar exudate, tender anterior cervical lymphadenopathy, and absence of cough. Each criterion is assigned one point, and the total score ranges from 0 to 4. In this case, the patient has a fever, tonsillar exudate, tender anterior cervical lymphadenopathy, and no cough, resulting in a CENTOR score of 4. A higher score indicates a higher likelihood of a streptococcal infection, and further diagnostic testing or treatment may be warranted.

Further Reading:

Pharyngitis and tonsillitis are common conditions that cause inflammation in the throat. Pharyngitis refers to inflammation of the oropharynx, which is located behind the soft palate, while tonsillitis refers to inflammation of the tonsils. These conditions can be caused by a variety of pathogens, including viruses and bacteria. The most common viral causes include rhinovirus, coronavirus, parainfluenza virus, influenza types A and B, adenovirus, herpes simplex virus type 1, and Epstein Barr virus. The most common bacterial cause is Streptococcus pyogenes, also known as Group A beta-hemolytic streptococcus (GABHS). Other bacterial causes include Group C and G beta-hemolytic streptococci and Fusobacterium necrophorum.

Group A beta-hemolytic streptococcus is the most concerning pathogen as it can lead to serious complications such as rheumatic fever and glomerulonephritis. These complications can occur due to an autoimmune reaction triggered by antigen/antibody complex formation or from cell damage caused by bacterial exotoxins.

When assessing a patient with a sore throat, the clinician should inquire about the duration and severity of the illness, as well as associated symptoms such as fever, malaise, headache, and joint pain. It is important to identify any red flags and determine if the patient is immunocompromised. Previous non-suppurative complications of Group A beta-hemolytic streptococcus infection should also be considered, as there is an increased risk of further complications with subsequent infections.

Red flags that may indicate a more serious condition include severe pain, neck stiffness, or difficulty swallowing. These symptoms may suggest epiglottitis or a retropharyngeal abscess, which require immediate attention.

To determine the likelihood of a streptococcal infection and the need for antibiotic treatment, two scoring systems can be used: CENTOR and FeverPAIN. The CENTOR criteria include tonsillar exudate, tender anterior cervical lymphadenopathy or lymphadenitis, history of fever, and absence of cough. The FeverPAIN criteria include fever, purulence, rapid onset of symptoms, severely inflamed tonsils, and absence of cough or coryza. Based on the scores from these criteria, the likelihood of a streptococcal infection can be estimated, and appropriate management can be undertaken. can

The most common sign of a foreign body (FB) in the nose in children is unilateral purulent nasal discharge. This discharge may have a foul smell. It is important to note that children often deny putting foreign bodies in their nose due to fear of getting in trouble. Purulent nasal discharge is more likely to occur with organic FBs, as they can absorb water and minerals, creating a breeding ground for bacterial colonization and infection. This type of discharge is more likely to occur after the FB has been in the nose for a few days.

Further Reading:

Foreign bodies in the ear or nose are a common occurrence, especially in children between the ages of 2 and 8. Foreign bodies in the ear are more common than those in the nose. Symptoms of foreign bodies in the ear may include ear pain, a feeling of fullness, impaired hearing, discharge, tinnitus, and vertigo. It is important to consider referral to an ENT specialist for the removal of potentially harmful foreign bodies such as glass, sharp objects, button batteries, and tightly wedged items. ENT involvement is also necessary if there is a perforation of the eardrum or if the foreign body is embedded in the eardrum.

When preparing a patient for removal, it is important to establish rapport and keep the patient relaxed, especially if they are a young child. The patient should be positioned comfortably and securely, and ear drops may be used to anesthetize the ear. Removal methods for foreign bodies in the ear include the use of forceps or a hook, irrigation (except for batteries, perforations, or organic material), suction, and magnets for ferrous metal foreign bodies. If there is an insect in the ear, it should be killed with alcohol, lignocaine, or mineral oil before removal.

After the foreign body is removed, it is important to check for any residual foreign bodies and to discharge the patient with appropriate safety net advice. Prophylactic antibiotic drops may be considered if there has been an abrasion of the skin.

Foreign bodies in the nose are less common but should be dealt with promptly due to the risk of posterior dislodgement into the airway. Symptoms of foreign bodies in the nose may include nasal discharge, sinusitis, nasal pain, epistaxis, or blood-stained discharge. Most nasal foreign bodies are found on the anterior or middle third of the nose and may not show up on x-rays.

Methods for removing foreign bodies from the nose include the mother’s kiss technique, suction, forceps, Jobson horne probe, and foley catheter. The mother’s kiss technique involves occluding the patent nostril and having a parent blow into the patient’s mouth. A foley catheter can be used by inserting it past the foreign body and inflating the balloon to gently push the foreign body out. ENT referral may be necessary if the foreign body cannot be visualized but there is a high suspicion, if attempts to remove the foreign body have failed, if the patient requires sed

Kiesselbach’s plexus, also known as Little’s area, is located in the front and lower part of the nasal septum. It is the most common site of bleeding in cases of anterior epistaxis. This plexus is formed by the convergence of four arteries: the anterior ethmoidal artery, the sphenopalatine artery, the greater palatine artery, and the septal branch of the superior labial artery. It is important to note that while the posterior ethmoidal artery supplies the septum of the nose, it does not contribute to Kiesselbach’s plexus.

Acute adrenal insufficiency, also known as Addisonian crisis, is a rare condition that can have catastrophic consequences if not diagnosed in a timely manner. It is more prevalent in women and typically occurs between the ages of 30 and 50.

Addison’s disease is caused by a deficiency in the production of steroid hormones by the adrenal glands, affecting glucocorticoid, mineralocorticoid, and sex steroid production. The main causes of Addison’s disease include autoimmune adrenalitis, bilateral adrenalectomy, Waterhouse-Friderichsen syndrome, tuberculosis, and congenital adrenal hyperplasia.

An Addisonian crisis can be triggered by the intentional or accidental withdrawal of steroid therapy, as well as factors such as infection, trauma, myocardial infarction, cerebral infarction, asthma, hypothermia, and alcohol abuse.

The clinical features of Addison’s disease include weakness, lethargy, hypotension (especially orthostatic hypotension), nausea, vomiting, weight loss, reduced axillary and pubic hair, depression, and hyperpigmentation in areas such as palmar creases, buccal mucosa, and exposed skin.

During an Addisonian crisis, the main symptoms are usually hypoglycemia and shock, characterized by tachycardia, peripheral vasoconstriction, hypotension, altered consciousness, and even coma.

Biochemical features that can confirm the diagnosis of Addison’s disease include increased ACTH levels, hyponatremia, hyperkalemia, hypercalcemia, hypoglycemia, and metabolic acidosis. Diagnostic investigations may involve the Synacthen test, plasma ACTH level measurement, plasma renin level measurement, and adrenocortical antibody testing.

Management of Addison’s disease should be overseen by an Endocrinologist. Treatment typically involves the administration of hydrocortisone, fludrocortisone, and dehydroepiandrosterone. Some patients may also require thyroxine if there is hypothalamic-pituitary disease present. Treatment is lifelong, and patients should carry a steroid card and MedicAlert bracelet to alert healthcare professionals of their condition and the potential for an Addisonian crisis.

The BTS guidelines for managing acute asthma in adults provide the following recommendations:

Oxygen:
– It is important to give supplementary oxygen to all patients with acute severe asthma who have low levels of oxygen in their blood (hypoxemia). The goal is to maintain a blood oxygen saturation level (SpO2) between 94-98%. Even if pulse oximetry is not available, oxygen should still be administered.

β2 agonists therapy:
– High-dose inhaled β2 agonists should be used as the first-line treatment for patients with acute asthma. It is important to administer these medications as early as possible.
– Intravenous β2 agonists should be reserved for patients who cannot reliably use inhaled therapy.
– For patients with life-threatening asthma symptoms, nebulized β2 agonists driven by oxygen are recommended.
– In cases of severe asthma that does not respond well to an initial dose of β2 agonist, continuous nebulization with an appropriate nebulizer may be considered.

Ipratropium bromide:
– Nebulized ipratropium bromide (0.5 mg every 4-6 hours) should be added to β2 agonist treatment for patients with acute severe or life-threatening asthma, or those who do not respond well to initial β2 agonist therapy.

Steroid therapy:
– Steroids should be given in adequate doses for all cases of acute asthma attacks.
– Prednisolone should be continued at a dose of 40-50 mg daily for at least five days or until the patient recovers.

Other therapies:
– Nebulized magnesium is not recommended for the treatment of acute asthma in adults.
– A single dose of intravenous magnesium sulfate may be considered for patients with acute severe asthma (peak expiratory flow rate <50% of the best or predicted value) who do not respond well to inhaled bronchodilator therapy. However, this should only be done after consulting with senior medical staff.
– Routine prescription of antibiotics is not necessary for patients with acute asthma.

For more information, please refer to the BTS/SIGN Guideline on the Management of Asthma.

Salicylate poisoning is a fairly common form of poisoning that can lead to organ damage and death if not treated promptly. The symptoms of salicylate poisoning include nausea, vomiting, ringing in the ears, hearing loss, excessive sweating, dehydration, rapid breathing, flushed skin, and high fever in children. In severe cases, convulsions, swelling of the brain, coma, kidney failure, fluid in the lungs, and unstable heart function can occur.

The treatment for salicylate poisoning involves stabilizing the patient’s airway, breathing, and circulation as needed, preventing further absorption of the poison, enhancing its elimination from the body, correcting any metabolic abnormalities, and providing supportive care. Unfortunately, there is no specific antidote available for salicylates. If a large amount of salicylate has been ingested within the past hour (more than 4.5 grams in adults or more than 2 grams in children), gastric lavage (stomach pumping) and administration of activated charcoal (50 grams) are recommended to reduce absorption and increase elimination.

Medical investigations for salicylate poisoning should include measuring the level of salicylate in the blood, analyzing arterial blood gases, performing an electrocardiogram (ECG), checking blood glucose levels, assessing kidney function and electrolyte levels, and evaluating blood clotting. ECG abnormalities that may be present include widening of the QRS complex, AV block, and ventricular arrhythmias.

The severity of salicylate poisoning is determined by the level of salicylate in the blood. Mild poisoning is defined as a salicylate level below 450 mg/L, moderate poisoning is between 450-700 mg/L, and severe poisoning is above 700 mg/L. In severe cases, aggressive intravenous fluid therapy is necessary to correct dehydration, and administration of 1.26% sodium bicarbonate can help eliminate the salicylate from the body. It is important to maintain a urine pH of greater than 7.5, ideally between 8.0-8.5. However, forced alkaline diuresis is no longer recommended. Life-threatening cases may require admission to the intensive care unit, intubation and ventilation, and possibly hemodialysis.

The post-cardiac arrest syndrome consists of four components. The first component is post-cardiac arrest brain injury, which refers to any damage or impairment to the brain that occurs after a cardiac arrest. The second component is post-cardiac arrest myocardial dysfunction, which is a condition where the heart muscle does not function properly after a cardiac arrest.

Further Reading:

Cardiopulmonary arrest is a serious event with low survival rates. In non-traumatic cardiac arrest, only about 20% of patients who arrest as an in-patient survive to hospital discharge, while the survival rate for out-of-hospital cardiac arrest is approximately 8%. The Resus Council BLS/AED Algorithm for 2015 recommends chest compressions at a rate of 100-120 per minute with a compression depth of 5-6 cm. The ratio of chest compressions to rescue breaths is 30:2.

After a cardiac arrest, the goal of patient care is to minimize the impact of post cardiac arrest syndrome, which includes brain injury, myocardial dysfunction, the ischaemic/reperfusion response, and the underlying pathology that caused the arrest. The ABCDE approach is used for clinical assessment and general management. Intubation may be necessary if the airway cannot be maintained by simple measures or if it is immediately threatened. Controlled ventilation is aimed at maintaining oxygen saturation levels between 94-98% and normocarbia. Fluid status may be difficult to judge, but a target mean arterial pressure (MAP) between 65 and 100 mmHg is recommended. Inotropes may be administered to maintain blood pressure. Sedation should be adequate to gain control of ventilation, and short-acting sedating agents like propofol are preferred. Blood glucose levels should be maintained below 8 mmol/l. Pyrexia should be avoided, and there is some evidence for controlled mild hypothermia but no consensus on this.

Post ROSC investigations may include a chest X-ray, ECG monitoring, serial potassium and lactate measurements, and other imaging modalities like ultrasonography, echocardiography, CTPA, and CT head, depending on availability and skills in the local department. Treatment should be directed towards the underlying cause, and PCI or thrombolysis may be considered for acute coronary syndrome or suspected pulmonary embolism, respectively.

Patients who are comatose after ROSC without significant pre-arrest comorbidities should be transferred to the ICU for supportive care. Neurological outcome at 72 hours is the best prognostic indicator of outcome.

During Bier’s block, the cuff is inflated to a pressure that is 100 mmHg higher than the patient’s systolic blood pressure. For example, if the systolic blood pressure is 150 mmHg, the cuff would be inflated to 250 mmHg. It is important to note that Bier’s block should not be performed if the systolic blood pressure is greater than 200 mmHg, as this is considered a contraindication. Therefore, the maximum pressure ever used during Bier’s block is 300mmHg.

Further Reading:

Bier’s block is a regional intravenous anesthesia technique commonly used for minor surgical procedures of the forearm or for reducing distal radius fractures in the emergency department (ED). It is recommended by NICE as the preferred anesthesia block for adults requiring manipulation of distal forearm fractures in the ED.

Before performing the procedure, a pre-procedure checklist should be completed, including obtaining consent, recording the patient’s weight, ensuring the resuscitative equipment is available, and monitoring the patient’s vital signs throughout the procedure. The air cylinder should be checked if not using an electronic machine, and the cuff should be checked for leaks.

During the procedure, a double cuff tourniquet is placed on the upper arm, and the arm is elevated to exsanguinate the limb. The proximal cuff is inflated to a pressure 100 mmHg above the systolic blood pressure, up to a maximum of 300 mmHg. The time of inflation and pressure should be recorded, and the absence of the radial pulse should be confirmed. 0.5% plain prilocaine is then injected slowly, and the time of injection is recorded. The patient should be warned about the potential cold/hot sensation and mottled appearance of the arm. After injection, the cannula is removed and pressure is applied to the venipuncture site to prevent bleeding. After approximately 10 minutes, the patient should have anesthesia and should not feel pain during manipulation. If anesthesia is successful, the manipulation can be performed, and a plaster can be applied by a second staff member. A check x-ray should be obtained with the arm lowered onto a pillow. The tourniquet should be monitored at all times, and the cuff should be inflated for a minimum of 20 minutes and a maximum of 45 minutes. If rotation of the cuff is required, it should be done after the manipulation and plaster application. After the post-reduction x-ray is satisfactory, the cuff can be deflated while observing the patient and monitors. Limb circulation should be checked prior to discharge, and appropriate follow-up and analgesia should be arranged.

There are several contraindications to performing Bier’s block, including allergy to local anesthetic, hypertension over 200 mm Hg, infection in the limb, lymphedema, methemoglobinemia, morbid obesity, peripheral vascular disease, procedures needed in both arms, Raynaud’s phenomenon, scleroderma, severe hypertension and sickle cell disease.

Corneal microdeposits are found in almost all individuals (over 90%) who have been taking amiodarone for more than six months, particularly at doses higher than 400 mg/day. These deposits generally do not cause any symptoms, although approximately 10% of patients may experience a perception of a ‘bluish halo’ around objects they see.

Amiodarone can also have other effects on the eye, but these are much less common, occurring in only 1-2% of patients. These effects include optic neuropathy, nonarteritic anterior ischemic optic neuropathy (N-AION), optic disc swelling, and visual field defects.

Bronchiolitis is a respiratory infection that primarily affects infants aged 2 to 6 months. It is typically caused by a viral infection, with respiratory syncytial virus (RSV) being the most common culprit. RSV infections are most prevalent during the winter months, from November to March. In fact, bronchiolitis is the leading cause of hospitalization among infants in the UK.

The symptoms of bronchiolitis include poor feeding (consuming less than 50% of their usual intake in the past 24 hours), lethargy, a history of apnea, a respiratory rate exceeding 70 breaths per minute, nasal flaring or grunting, severe chest wall recession, cyanosis (bluish discoloration of the skin), and low oxygen saturation levels. For children aged 6 weeks and older, oxygen saturation levels below 90% indicate a need for medical attention. For babies under 6 weeks or those with underlying health conditions, oxygen saturation levels below 92% require medical attention.

To confirm the diagnosis of bronchiolitis, a nasopharyngeal aspirate can be taken for rapid testing of RSV. This test is useful in preventing unnecessary further testing and allows for the isolation of the infected infant.

Most infants with bronchiolitis experience a mild, self-limiting illness that does not require hospitalization. Treatment primarily focuses on supportive measures, such as ensuring adequate fluid and nutritional intake and controlling the infant’s temperature. The illness typically lasts for 7 to 10 days.

However, hospital referral and admission are recommended in cases of poor feeding, lethargy, a history of apnea, a respiratory rate exceeding 70 breaths per minute, nasal flaring or grunting, severe chest wall recession, cyanosis, and oxygen saturation levels below 94%. If hospitalization is necessary, treatment involves supportive measures, supplemental oxygen, and nasogastric feeding as needed. There is limited or no evidence supporting the use of antibiotics, antivirals, bronchodilators, corticosteroids, hypertonic saline, or adrenaline nebulizers for the treatment of bronchiolitis.

Placental abruption, also known as abruptio placentae, occurs when the placental lining separates from the wall of the uterus before delivery and after 20 weeks of gestation.

In the early stages, there may be no symptoms, but typically abdominal pain and vaginal bleeding develop. Approximately 20% of patients experience a concealed placental abruption, where the haemorrhage is confined within the uterine cavity and the amount of blood loss can be significantly underestimated.

The clinical features of placental abruption include sudden onset abdominal pain (which can be severe), variable vaginal bleeding, severe or continuous contractions, abdominal tenderness, and an enlarged, tense uterus. The foetus often shows signs of distress, such as reduced movements, increased or decreased fetal heart rate, decreased variability of fetal heart rate, and late decelerations.

In contrast, placenta praevia is painless and the foetal heart is generally normal. The degree of obstetric shock is usually proportional to the amount of vaginal blood loss. Another clue that the cause of bleeding is placenta praevia rather than placental abruption is that the foetus may have an abnormal presentation or lie.

SIADH is characterized by hyponatremia, which is a condition where there is a low level of sodium in the blood. This occurs because the body is unable to properly excrete excess water, leading to a dilution of sodium levels. SIADH is specifically classified as euvolemic, meaning that there is a normal amount of fluid in the body, and hypotonic, indicating that the concentration of solutes in the blood is lower than normal.

Further Reading:

Syndrome of inappropriate antidiuretic hormone (SIADH) is a condition characterized by low sodium levels in the blood due to excessive secretion of antidiuretic hormone (ADH). ADH, also known as arginine vasopressin (AVP), is responsible for promoting water and sodium reabsorption in the body. SIADH occurs when there is impaired free water excretion, leading to euvolemic (normal fluid volume) hypotonic hyponatremia.

There are various causes of SIADH, including malignancies such as small cell lung cancer, stomach cancer, and prostate cancer, as well as neurological conditions like stroke, subarachnoid hemorrhage, and meningitis. Infections such as tuberculosis and pneumonia, as well as certain medications like thiazide diuretics and selective serotonin reuptake inhibitors (SSRIs), can also contribute to SIADH.

The diagnostic features of SIADH include low plasma osmolality, inappropriately elevated urine osmolality, urinary sodium levels above 30 mmol/L, and euvolemic. Symptoms of hyponatremia, which is a common consequence of SIADH, include nausea, vomiting, headache, confusion, lethargy, muscle weakness, seizures, and coma.

Management of SIADH involves correcting hyponatremia slowly to avoid complications such as central pontine myelinolysis. The underlying cause of SIADH should be treated if possible, such as discontinuing causative medications. Fluid restriction is typically recommended, with a daily limit of around 1000 ml for adults. In severe cases with neurological symptoms, intravenous hypertonic saline may be used. Medications like demeclocycline, which blocks ADH receptors, or ADH receptor antagonists like tolvaptan may also be considered.

It is important to monitor serum sodium levels closely during treatment, especially if using hypertonic saline, to prevent rapid correction that can lead to central pontine myelinolysis. Osmolality abnormalities can help determine the underlying cause of hyponatremia, with increased urine osmolality indicating dehydration or renal disease, and decreased urine osmolality suggesting SIADH or overhydration.

The Gold-Silver-bronze Hierarchy is utilized to establish the chain of command at the site of a significant incident in the United Kingdom.

Gold (Strategic):
The Gold Commander assumes overall control of their organization’s resources at the incident. They are situated at a remote location known as the Gold Command. Ideally, the Gold Commanders for each organization should be co-located, but if that is not feasible, they must maintain constant communication with each other.

Silver (Tactical):
The Silver Commander for each organization is the highest-ranking member of each service present at the scene of the major incident. Their responsibility is to manage the available resources at the scene in order to achieve the strategic objectives set by the Gold Commander. They work closely with the Silver Commanders of other organizations and are not directly involved in dealing with the incident itself.

Bronze (Operational):
The Bronze Commander directly oversees their organization’s resources at the incident. They collaborate with their staff on the scene of the incident. In cases where the incident is geographically widespread, multiple Bronze commanders may assume responsibility for different areas. In complex incidents, Bronze commanders may share tasks or responsibilities.

At the scene of the major incident, the Police and Fire Service establish a cordon to restrict access, requiring permission from the appropriate officer to enter. The Silver and Bronze areas are designated within the scene.

The Silver area is situated within an outer cordon that surrounds the inner cordon. It houses the Casualty Clearing Station (CCS), Ambulance Parking Point, and the service incident commanders for each organization. Medical personnel are only allowed to enter the Silver area if instructed to do so by the MIO (Medical Incident Officer) and if authorized by the service responsible for safety at the scene, typically the Fire Service. Primary triage, evacuation of casualties, and treatment of trapped casualties take place in this area.

The Bronze area is located within an inner cordon that surrounds the scene of the incident. All medical activities within the Bronze area are directed by the MIO and AIO (Ambulance Incident Officer), who work together. Doctors operate under the command of the MIO, while ambulance personnel are under the command of the AIO.

The most suitable dosage of epinephrine for a patient experiencing anaphylaxis after a flu vaccination is 500 micrograms (0.5ml 1 in 1,000) adrenaline by intramuscular injection.

Anaphylaxis is a severe and life-threatening hypersensitivity reaction that can have sudden onset and progression. It is characterized by skin or mucosal changes and can lead to life-threatening airway, breathing, or circulatory problems. Anaphylaxis can be allergic or non-allergic in nature.

In allergic anaphylaxis, there is an immediate hypersensitivity reaction where an antigen stimulates the production of IgE antibodies. These antibodies bind to mast cells and basophils. Upon re-exposure to the antigen, the IgE-covered cells release histamine and other inflammatory mediators, causing smooth muscle contraction and vasodilation.

Non-allergic anaphylaxis occurs when mast cells degrade due to a non-immune mediator. The clinical outcome is the same as in allergic anaphylaxis.

The management of anaphylaxis is the same regardless of the cause. Adrenaline is the most important drug and should be administered as soon as possible. The recommended doses for adrenaline vary based on age. Other treatments include high flow oxygen and an IV fluid challenge. Corticosteroids and chlorpheniramine are no longer recommended, while non-sedating antihistamines may be considered as third-line treatment after initial stabilization of airway, breathing, and circulation.

Common causes of anaphylaxis include food (such as nuts, which is the most common cause in children), drugs, and venom (such as wasp stings). Sometimes it can be challenging to determine if a patient had a true episode of anaphylaxis. In such cases, serum tryptase levels may be measured, as they remain elevated for up to 12 hours following an acute episode of anaphylaxis.

The Resuscitation Council (UK) provides guidelines for the management of anaphylaxis, including a visual algorithm that outlines the recommended steps for treatment.
https://www.resus.org.uk/sites/default/files/2021-05/Emergency%20Treatment%20of%20Anaphylaxis%20May%202021_0.pdf

When assessing a patient with epistaxis (nosebleed), it is important to start with a standard ABC assessment, focusing on the airway and hemodynamic status. Even if the bleeding appears to have stopped, it is crucial to evaluate the patient’s airway and circulation.

If active bleeding is still present and there are signs of hemodynamic compromise, immediate resuscitative and first aid measures should be initiated. Epistaxis should be treated as a circulatory emergency, especially in elderly patients, those with clotting disorders or bleeding tendencies, and individuals taking anticoagulants. In these cases, it is necessary to establish intravenous access using at least an 18-gauge (green) cannula and collect blood samples for tests such as full blood count, urea and electrolytes, clotting studies, and blood typing and crossmatching (depending on the amount of blood loss). These patients should be closely monitored in a majors area or a designated observation area, as dislodgement of a blood clot can lead to severe bleeding.

First aid measures to control bleeding include the following steps:
1. The patient should be seated upright with their body tilted forward and their mouth open. Lying down should be avoided, unless the patient feels faint or there are signs of hemodynamic compromise. Leaning forward helps reduce the flow of blood into the back of the throat.
2. The patient should be encouraged to spit out any blood that enters the throat and advised not to swallow it.
3. Firmly pinch the soft, cartilaginous part of the nose, compressing the nostrils for 10-15 minutes. Pressure should not be released, and the patient should breathe through their mouth.
4. If the patient is unable to comply with pinching their own nose, an alternative technique is to ask a relative or staff member to apply external pressure using a device like a swimmer’s nose clip.
5. It is important to dispel the misconception that compressing the bones of the nose will help stop the bleeding. Applying ice to the neck or forehead has not been proven to affect nasal blood flow. However, sucking on an ice cube or applying an ice pack directly to the nose may help reduce nasal blood flow.

If bleeding stops with first aid measures, it may be beneficial to apply a topical antiseptic preparation to reduce crusting and inflammation. Naseptin cream (containing chlorhexidine and neomycin) is commonly used and should be applied to the nostrils four times daily for 10 days.

Whooping cough, also known as pertussis, is a respiratory infection caused by the bacteria Bordetella pertussis. It is transmitted through respiratory droplets and has an incubation period of about 7-21 days. This highly contagious disease can be passed on to around 90% of close household contacts.

To prevent the spread of whooping cough, Public Health England advises that children with the illness should stay away from school, nursery, or childminders for 48 hours after starting antibiotic treatment. If no antibiotic treatment is given, they should be kept away for 21 days from the onset of the illness. It’s important to note that even after treatment, non-infectious coughing may persist for several weeks.

For more information on how to control infections in schools and other childcare settings, you can refer to the guidance provided by Public Health England.

Spondyloarthritis is a term that encompasses various inflammatory conditions affecting both the joints and the entheses, which are the attachment sites of ligaments and tendons to the bones. The primary cause of spondyloarthritis is ankylosing spondylitis, but it can also be triggered by reactive arthritis, psoriatic arthritis, and enteropathic arthropathies.

If individuals below the age of 45 experience four or more of the following symptoms, they should be referred for a potential diagnosis of spondyloarthritis:

– Presence of low back pain and being younger than 35 years old
– Waking up in the second half of the night due to pain
– Buttock pain
– Pain that improves with movement or within 48 hours of using nonsteroidal anti-inflammatory drugs (NSAIDs)
– Having a first-degree relative with spondyloarthritis
– History of current or past arthritis, psoriasis, or enthesitis.

Amiodarone is a medication that is recommended to be administered after the third shock in a shockable cardiac arrest (Vf/pVT) while chest compressions are being performed. The prescribed dose is 300 mg, given as an intravenous bolus that is diluted in 5% dextrose to a volume of 20 mL. It is important to note that amiodarone is not suitable for treating PEA or asystole.

In cases where VF/pVT persists after five defibrillation attempts, an additional dose of 150 mg of amiodarone should be given. However, if amiodarone is not available, lidocaine can be used as an alternative. The recommended dose of lidocaine is 1 mg/kg. It is crucial to avoid administering lidocaine if amiodarone has already been given.

Amiodarone is classified as a membrane-stabilizing antiarrhythmic drug. It works by prolonging the duration of the action potential and the refractory period in both the atrial and ventricular myocardium. This medication also slows down atrioventricular conduction and has a similar effect on accessory pathways.

Additionally, amiodarone has a mild negative inotropic action, meaning it weakens the force of heart contractions. It also causes peripheral vasodilation through non-competitive alpha-blocking effects.

It is important to note that while there is no evidence of long-term benefits from using amiodarone, it may improve short-term survival rates, which justifies its continued use.

When managing a first episode of acute venous thromboembolism (VTE), it is recommended to start warfarin in combination with a parenteral anticoagulant, such as unfractionated heparin, low-molecular-weight heparin, or fondaparinux. The parental anticoagulant should be continued for a minimum of 5 days and ideally until the international normalized ratio (INR) is above 2 for at least 24 hours.

To prevent the extension of the blood clot and recurrence in calf deep vein thrombosis (DVT), at least 6 weeks of anticoagulant therapy is necessary. For proximal DVT, a minimum of 3 months of anticoagulant therapy is required.

For first episodes of VTE, the ideal target INR is 2.5. However, in cases where patients experience recurrent VTE while being anticoagulated within the therapeutic range, the target INR should be increased to 3.5.

This patient presents with a noticeable mass at the top of the right lung, which is clearly visible on the chest X-ray. Based on the symptoms and clinical presentation, it is highly likely that this is a Pancoast tumor, and the overall diagnosis is Pancoast syndrome.

A Pancoast tumor is a type of tumor that develops at the apex of either the right or left lung. It typically spreads to nearby tissues such as the ribs and vertebrae. The majority of Pancoast tumors are classified as non-small cell cancers.

Pancoast syndrome occurs when the tumor invades various structures and tissues around the thoracic inlet. This includes the invasion of the cervical sympathetic plexus on the same side as the tumor, leading to the development of Horner’s syndrome. Additionally, there may be reflex sympathetic dystrophy in the arm on the affected side, resulting in increased sensitivity to touch and changes in the skin.

Patients with Pancoast syndrome may also experience shoulder and arm pain due to the tumor invading the brachial plexus roots C8-T1. This can lead to muscle wasting in the hand and tingling sensations in the inner side of the arm. In some cases, there may be involvement of the unilateral recurrent laryngeal nerve, causing unilateral vocal cord paralysis and resulting in a hoarse voice and/or a bovine cough. Phrenic nerve involvement is less common but can also occur.

Horner’s syndrome, which is a key feature of Pancoast syndrome, is caused by compression of the sympathetic chain from the hypothalamus to the orbit. The three main symptoms of Horner’s syndrome are drooping of the eyelid (ptosis), constriction of the pupil (pupillary miosis), and lack of sweating on the forehead (anhydrosis).

The diagnosis in this particular case is malignant (accelerated) hypertension. The patient’s blood pressure is greater than 220/110, and they also have retinal haemorrhages and papilloedema. During the examination, it is important to look for other features such as the presence of a 3rd heart sound, ankle oedema, bilateral basal crepitations, and any focal neurological deficit.

Standard pain relievers are generally not effective in treating cluster headaches. They take too long to work, and by the time they start to relieve the pain, the headache has usually already gone away. It is not recommended to use opioids for cluster headaches as they may actually make the headaches worse, and using them for a long time can lead to dependency.

However, there are other options that can be effective in treating cluster headaches. One option is to use subcutaneous sumatriptan, which is a medication that works by stimulating a specific receptor in the brain. This can help reduce the inflammation in the blood vessels that is associated with migraines and cluster headaches. Most people find that subcutaneous sumatriptan starts to work within 10-15 minutes of being administered.

Another option is to use zolmitriptan nasal spray, which is also a medication that works in a similar way to sumatriptan. However, it may take a bit longer for the nasal spray to start working compared to the subcutaneous injection.

In addition to medication, high-flow oxygen can also be used as an alternative therapy for cluster headaches. This involves breathing in oxygen at a high flow rate, which can help relieve the pain and other symptoms of a cluster headache.

Lastly, octreotide can be administered subcutaneously and has been shown to be more effective than a placebo in treating acute cluster headache attacks.

During the first trimester of pregnancy, the use of warfarin can lead to a condition known as fetal warfarin syndrome. This condition is characterized by nasal hypoplasia, bone stippling, bilateral optic atrophy, and intellectual disability in the baby. However, if warfarin is taken during the second or third trimester, it can cause optic atrophy, cataracts, microcephaly, microphthalmia, intellectual disability, and both fetal and maternal hemorrhage.

There are several other drugs that can have adverse effects during pregnancy. For example, ACE inhibitors like ramipril can cause hypoperfusion, renal failure, and the oligohydramnios sequence if taken during the second and third trimesters. Aminoglycosides such as gentamicin can lead to ototoxicity and deafness in the baby. High doses of aspirin can result in first trimester abortions, delayed onset labor, premature closure of the fetal ductus arteriosus, and fetal kernicterus. However, low doses of aspirin (e.g. 75 mg) do not pose significant risks.

Benzodiazepines like diazepam, when taken late in pregnancy, can cause respiratory depression and a neonatal withdrawal syndrome. Calcium-channel blockers, if taken during the first trimester, can cause phalangeal abnormalities, while their use in the second and third trimesters can lead to fetal growth retardation. Carbamazepine can result in hemorrhagic disease of the newborn and neural tube defects. Chloramphenicol can cause gray baby syndrome. Corticosteroids, if taken during the first trimester, may cause orofacial clefts.

Danazol, if taken during the first trimester, can cause masculinization of the female fetuses genitals. Finasteride should not be handled by pregnant women as crushed or broken tablets can be absorbed through the skin and affect male sex organ development. Haloperidol, if taken during the first trimester, may cause limb malformations, while its use in the third trimester increases the risk of extrapyramidal symptoms in the newborn.

Heparin can lead to maternal bleeding and thrombocytopenia. Isoniazid can cause maternal liver damage and neuropathy and seizures in the baby. Isotretinoin carries a high risk of teratogenicity, including multiple congenital malformations and spontaneous abortion.

Methaemoglobinaemia is a condition that can be caused by nitrates, including amyl nitrite.

Further Reading:

Methaemoglobinaemia is a condition where haemoglobin is oxidised from Fe2+ to Fe3+. This process is normally regulated by NADH methaemoglobin reductase, which transfers electrons from NADH to methaemoglobin, converting it back to haemoglobin. In healthy individuals, methaemoglobin levels are typically less than 1% of total haemoglobin. However, an increase in methaemoglobin can lead to tissue hypoxia as Fe3+ cannot bind oxygen effectively.

Methaemoglobinaemia can be congenital or acquired. Congenital causes include haemoglobin chain variants (HbM, HbH) and NADH methaemoglobin reductase deficiency. Acquired causes can be due to exposure to certain drugs or chemicals, such as sulphonamides, local anaesthetics (especially prilocaine), nitrates, chloroquine, dapsone, primaquine, and phenytoin. Aniline dyes are also known to cause methaemoglobinaemia.

Clinical features of methaemoglobinaemia include slate grey cyanosis (blue to grey skin coloration), chocolate blood or chocolate cyanosis (brown color of blood), dyspnoea, low SpO2 on pulse oximetry (which often does not improve with supplemental oxygen), and normal PaO2 on arterial blood gas (ABG) but low SaO2. Patients may tolerate hypoxia better than expected. Severe cases can present with acidosis, arrhythmias, seizures, and coma.

Diagnosis of methaemoglobinaemia is made by directly measuring the level of methaemoglobin using a co-oximeter, which is present in most modern blood gas analysers. Other investigations, such as a full blood count (FBC), electrocardiogram (ECG), chest X-ray (CXR), and beta-human chorionic gonadotropin (bHCG) levels (in pregnancy), may be done to assess the extent of the condition and rule out other contributing factors.

Active treatment is required if the methaemoglobin level is above 30% or if it is below 30% but the patient is symptomatic or shows evidence of tissue hypoxia. Treatment involves maintaining the airway and delivering high-flow oxygen, removing the causative agents, treating toxidromes and consider giving IV dextrose 5%.

Warfarin has been found to elevate the likelihood of bleeding events when taken in conjunction with NSAIDs like ibuprofen. Consequently, it is advisable to refrain from co-prescribing warfarin with ibuprofen. For more information on this topic, please refer to the BNF section on warfarin interactions.

Patients who have bradycardia and show ventricular pauses longer than 3 seconds on an electrocardiogram (ECG) are at a high risk of developing asystole. The following characteristics are indicators of a high risk for asystole: recent episodes of asystole, Mobitz II AV block, third-degree AV block (also known as complete heart block) with a broad QRS complex, and ventricular pauses longer than 3 seconds.

Further Reading:

Causes of Bradycardia:
– Physiological: Athletes, sleeping
– Cardiac conduction dysfunction: Atrioventricular block, sinus node disease
– Vasovagal & autonomic mediated: Vasovagal episodes, carotid sinus hypersensitivity
– Hypothermia
– Metabolic & electrolyte disturbances: Hypothyroidism, hyperkalaemia, hypermagnesemia
– Drugs: Beta-blockers, calcium channel blockers, digoxin, amiodarone
– Head injury: Cushing’s response
– Infections: Endocarditis
– Other: Sarcoidosis, amyloidosis

Presenting symptoms of Bradycardia:
– Presyncope (dizziness, lightheadedness)
– Syncope
– Breathlessness
– Weakness
– Chest pain
– Nausea

Management of Bradycardia:
– Assess and monitor for adverse features (shock, syncope, myocardial ischaemia, heart failure)
– Treat reversible causes of bradycardia
– Pharmacological treatment: Atropine is first-line, adrenaline and isoprenaline are second-line
– Transcutaneous pacing if atropine is ineffective
– Other drugs that may be used: Aminophylline, dopamine, glucagon, glycopyrrolate

Bradycardia Algorithm:
– Follow the algorithm for management of bradycardia, which includes assessing and monitoring for adverse features, treating reversible causes, and using appropriate medications or pacing as needed.
https://acls-algorithms.com/wp-content/uploads/2020/12/Website-Bradycardia-Algorithm-Diagram.pdf

Acute kidney injury (AKI), previously known as acute renal failure, is a sudden decline in kidney function. This leads to the accumulation of urea and other waste products in the body, as well as disturbances in fluid balance and electrolyte levels. AKI can occur in individuals with previously normal kidney function or those with pre-existing kidney disease, known as acute-on-chronic kidney disease. It is a relatively common condition, with approximately 15% of adults admitted to hospitals in the UK developing AKI.

AKI is categorized into three stages based on specific criteria. In stage 1, there is a rise in creatinine levels of 26 micromol/L or more within 48 hours, or a rise of 50-99% from baseline within 7 days (1.5-1.99 times the baseline). Additionally, a urine output of less than 0.5 mL/kg/hour for more than 6 hours is indicative of stage 1 AKI.

Stage 2 AKI is characterized by a creatinine rise of 100-199% from baseline within 7 days (2.0-2.99 times the baseline), or a urine output of less than 0.5 mL/kg/hour for more than 12 hours.

In stage 3 AKI, there is a creatinine rise of 200% or more from baseline within 7 days (3.0 or more times the baseline). Alternatively, a creatinine rise to 354 micromol/L or more with an acute rise of 26 micromol/L or more within 48 hours, or a rise of 50% or more within 7 days, is indicative of stage 3 AKI. Additionally, a urine output of less than 0.3 mL/kg/hour for 24 hours or anuria (no urine output) for 12 hours also falls under stage 3 AKI.

The intravascular volume of an infant is approximately 80 ml/kg, while in older children it is around 70 ml/kg. Dehydration itself does not lead to death, but shock can occur when there is a loss of 20 ml/kg from the intravascular space. Clinical dehydration becomes evident only after total losses greater than 25 ml/kg.

The table below summarizes the maintenance fluid requirements for well and normal children:

Bodyweight: First 10 kg
Daily fluid requirement: 100 ml/kg
Hourly fluid requirement: 4 ml/kg

Bodyweight: Second 10 kg
Daily fluid requirement: 50 ml/kg
Hourly fluid requirement: 2 ml/kg

Bodyweight: Subsequent kg
Daily fluid requirement: 20 ml/kg
Hourly fluid requirement: 1 ml/kg

For a well and normal child weighing less than 10 kg, the hourly maintenance fluid requirement is 4 ml/kg. Therefore, for this child, the hourly maintenance fluid requirement would be:

9 x 4 ml/hour = 36 ml/hour

This patient is displaying symptoms and signs that are consistent with a diagnosis of biliary colic. Biliary colic occurs when a gallstone temporarily blocks either the cystic duct or Hartmann’s pouch, leading to contractions in the gallbladder. The blockage is relieved when the stone either falls back into the gallbladder or passes through the duct.

Patients with biliary colic typically experience colicky pain in the upper right quadrant of their abdomen. This pain can last anywhere from 15 minutes to 24 hours and is often accompanied by feelings of nausea and vomiting. It is not uncommon for the pain to radiate into the right scapula area.

Eating fatty foods can exacerbate the pain as they stimulate the release of cholecystokinin, which in turn causes the gallbladder to contract.

Given the patient’s symptoms and physical findings, the most appropriate initial treatment would be to administer Furosemide 40 mg intravenously. Furosemide is a loop diuretic that helps remove excess fluid from the body, which can alleviate symptoms of fluid overload such as shortness of breath and edema. By reducing fluid volume, Furosemide can help improve the patient’s breathing and relieve the strain on the heart.

Further Reading:

Cardiac failure, also known as heart failure, is a clinical syndrome characterized by symptoms and signs resulting from abnormalities in the structure or function of the heart. This can lead to reduced cardiac output or high filling pressures at rest or with stress. Heart failure can be caused by various problems such as myocardial, valvular, pericardial, endocardial, or arrhythmic issues.

The most common causes of heart failure in the UK are coronary heart disease and hypertension. However, there are many other possible causes, including valvular heart disease, structural heart disease, cardiomyopathies, certain drugs or toxins, endocrine disorders, nutritional deficiencies, infiltrative diseases, infections, and arrhythmias. Conditions that increase peripheral demand on the heart, such as anemia, pregnancy, sepsis, hyperthyroidism, Paget’s disease of bone, arteriovenous malformations, and beriberi, can also lead to high-output cardiac failure.

Signs and symptoms of heart failure include edema, lung crepitations, tachycardia, tachypnea, hypotension, displaced apex beat, right ventricular heave, elevated jugular venous pressure, cyanosis, hepatomegaly, ascites, pleural effusions, breathlessness, fatigue, orthopnea, paroxysmal nocturnal dyspnea, nocturnal cough or wheeze, and Presyncope.

To diagnose heart failure, NICE recommends three key tests: N-terminal pro-B-type natriuretic peptide (NT‑proBNP), transthoracic echocardiography, and ECG. Additional tests may include chest X-ray, blood tests (U&Es, thyroid function, LFT’s, lipid profile, HbA1C, FBC), urinalysis, and peak flow or spirometry.

Management of cardiogenic pulmonary edema, a complication of heart failure, involves ensuring a patent airway, optimizing breathing with supplemental oxygen and non-invasive ventilation if necessary, and addressing circulation with loop diuretics to reduce preload, vasodilators to reduce preload and afterload, and inotropes if hypotension or signs of end organ hypoperfusion persist.

In summary, cardiac failure is a clinical syndrome resulting from abnormalities in cardiac function. It can have various causes and is characterized by specific signs and symptoms. Diagnosis involves specific tests, and management focuses on addressing