The maximum safe dose of plain lidocaine is 3 mg per kilogram of body weight, with a maximum limit of 200 mg. However, when administered with adrenaline 1:200,000, the maximum safe dose increases to 7 mg per kilogram of body weight, with a maximum limit of 500 mg.

For example, if a patient weighs 70 kg, the maximum safe dose of lidocaine hydrochloride would be 210 mg. However, according to the British National Formulary (BNF), the maximum safe dose is actually 200 mg.

For more information on lidocaine hydrochloride, please refer to the BNF section dedicated to this medication.

Mycoplasma pneumoniae infection does not have a connection with infective endocarditis. However, it is associated with various extra-pulmonary complications. These include skin conditions such as erythema multiforme and Stevens-Johnson syndrome. In the central nervous system, it can lead to Guillain-Barre syndrome, meningitis, encephalitis, optic neuritis, cerebellar ataxia, and cranial nerve palsies. Gastrointestinal symptoms may include anorexia, nausea, diarrhea, hepatitis, and pancreatitis. Hematological complications can manifest as cold agglutinins, hemolytic anemia, thrombocytopenia, and disseminated intravascular coagulation. Mycoplasma pneumoniae infection can also cause pericarditis and myocarditis. Rheumatic symptoms such as arthralgia and arthritides may occur, and acute glomerulonephritis can affect the kidneys.

Anaemia can be categorized based on the size of red blood cells. Microcytic anaemia, characterized by a mean corpuscular volume (MCV) of less than 80 fl, can be caused by various factors such as iron deficiency, thalassaemia, anaemia of chronic disease (which can also be normocytic), sideroblastic anaemia (which can also be normocytic), lead poisoning, and aluminium toxicity (although this is now rare and mainly affects haemodialysis patients).

On the other hand, normocytic anaemia, with an MCV ranging from 80 to 100 fl, can be attributed to conditions like haemolysis, acute haemorrhage, bone marrow failure, anaemia of chronic disease (which can also be microcytic), mixed iron and folate deficiency, pregnancy, chronic renal failure, and sickle-cell disease.

Lastly, macrocytic anaemia, characterized by an MCV greater than 100 fl, can be caused by factors such as B12 deficiency, folate deficiency, hypothyroidism, reticulocytosis, liver disease, alcohol abuse, myeloproliferative disease, myelodysplastic disease, and certain drugs like methotrexate, hydroxyurea, and azathioprine.

It is important to understand the different causes of anaemia based on red cell size as this knowledge can aid in the diagnosis and management of this condition.

When furosemide and SSRI drugs are prescribed together, there is a higher chance of developing hyponatraemia, which is a condition characterized by low levels of sodium in the blood. Additionally, there is an increased risk of hypokalaemia, which can potentially lead to a dangerous heart rhythm disorder called torsades de pointes. It is important to note that co-prescribing furosemide with citalopram should be avoided due to these risks. For more information, you can refer to the section on furosemide interactions in the BNF.

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.

Bronchiolitis is a common respiratory infection that primarily affects infants. It typically occurs between the ages of 3-6 months and is most prevalent during the winter months from November to March. The main culprit behind bronchiolitis is the respiratory syncytial virus, accounting for about 70% of cases. However, other viruses like parainfluenza, influenza, adenovirus, coronavirus, and rhinovirus can also cause this infection.

The clinical presentation of bronchiolitis usually starts with symptoms resembling a common cold, which last for the first 2-3 days. Infants may experience poor feeding, rapid breathing (tachypnoea), nasal flaring, and grunting. Chest wall recessions, bilateral fine crepitations, and wheezing may also be observed. In severe cases, apnoea, a temporary cessation of breathing, can occur.

Bronchiolitis is a self-limiting illness, meaning it resolves on its own over time. Therefore, treatment mainly focuses on supportive care. However, infants with oxygen saturations below 92% may require oxygen administration. If an infant is unable to maintain oral intake or hydration, nasogastric feeding should be considered. Nasal suction is recommended to clear secretions in infants experiencing respiratory distress due to nasal blockage.

It is important to note that there is no evidence supporting the use of antivirals (such as ribavirin), antibiotics, beta 2 agonists, anticholinergics, or corticosteroids in the management of bronchiolitis. These interventions are not recommended for this condition.

Chronic hepatitis B infection is characterized by the persistence of serum HbsAg for a duration exceeding six months.

Further Reading:

Hepatitis B is a viral infection that is transmitted through exposure to infected blood or body fluids. It can also be passed from mother to child during childbirth. The incubation period for hepatitis B is typically 6-20 weeks. Common symptoms of hepatitis B include fever, jaundice, and elevated liver transaminases.

Complications of hepatitis B infection can include chronic hepatitis, which occurs in 5-10% of cases, fulminant liver failure, hepatocellular carcinoma, glomerulonephritis, polyarteritis nodosa, and cryoglobulinemia.

Immunization against hepatitis B is recommended for various at-risk groups, including healthcare workers, intravenous drug users, sex workers, close family contacts of infected individuals, and those with chronic liver disease or kidney disease. The vaccine contains HBsAg adsorbed onto an aluminum hydroxide adjuvant and is prepared using recombinant DNA technology. Most vaccination schedules involve three doses of the vaccine, with a booster recommended after 5 years.

Around 10-15% of adults may not respond adequately to the vaccine. Risk factors for poor response include age over 40, obesity, smoking, alcohol excess, and immunosuppression. Testing for anti-HBs levels is recommended for healthcare workers and patients with chronic kidney disease. Interpretation of anti-HBs levels can help determine the need for further vaccination or testing for infection.

In terms of serology, the presence of HBsAg indicates acute disease if present for 1-6 months, and chronic disease if present for more than 6 months. Anti-HBs indicates immunity, either through exposure or immunization. Anti-HBc indicates previous or current infection, with IgM anti-HBc appearing during acute or recent infection and IgG anti-HBc persisting. HbeAg is a marker of infectivity.

Management of hepatitis B involves notifying the Health Protection Unit for surveillance and contact tracing. Patients should be advised to avoid alcohol and take precautions to minimize transmission to partners and contacts. Referral to a gastroenterologist or hepatologist is recommended for all patients. Symptoms such as pain, nausea, and itch can be managed with appropriate drug treatment. Pegylated interferon-alpha and other antiviral medications like tenofovir and entecavir may be used to suppress viral replication in chronic carriers.

It is recommended to obtain an arterial blood gas (ABG) sample from all patients who have experienced submersion (drowning) as even individuals without symptoms may have a surprising level of hypoxia. Draining the lungs is not effective and not recommended. There is no strong evidence to support the routine use of antibiotics as a preventive measure. Steroids have not been proven to be effective in treating drowning. All drowning patients, except those with normal oxygen levels, normal saturations, and normal lung sounds, should receive supplemental oxygen as significant hypoxia can occur without causing difficulty in breathing.

Further Reading:

Drowning is the process of experiencing respiratory impairment from submersion or immersion in liquid. It can be classified as cold-water or warm-water drowning. Risk factors for drowning include young age and male sex. Drowning impairs lung function and gas exchange, leading to hypoxemia and acidosis. It also causes cardiovascular instability, which contributes to metabolic acidosis and cell death.

When someone is submerged or immersed, they will voluntarily hold their breath to prevent aspiration of water. However, continued breath holding causes progressive hypoxia and hypercapnia, leading to acidosis. Eventually, the respiratory center sends signals to the respiratory muscles, forcing the individual to take an involuntary breath and allowing water to be aspirated into the lungs. Water entering the lungs stimulates a reflex laryngospasm that prevents further penetration of water. Aspirated water can cause significant hypoxia and damage to the alveoli, leading to acute respiratory distress syndrome (ARDS).

Complications of drowning include cardiac ischemia and infarction, infection with waterborne pathogens, hypothermia, neurological damage, rhabdomyolysis, acute tubular necrosis, and disseminated intravascular coagulation (DIC).

In children, the diving reflex helps reduce hypoxic injury during submersion. It causes apnea, bradycardia, and peripheral vasoconstriction, reducing cardiac output and myocardial oxygen demand while maintaining perfusion of the brain and vital organs.

Associated injuries with drowning include head and cervical spine injuries in patients rescued from shallow water. Investigations for drowning include arterial blood gases, chest X-ray, ECG and cardiac monitoring, core temperature measurement, and blood and sputum cultures if secondary infection is suspected.

Management of drowning involves extricating the patient from water in a horizontal position with spinal precautions if possible. Cardiovascular considerations should be taken into account when removing patients from water to prevent hypotension and circulatory collapse. Airway management, supplemental oxygen, and ventilation strategies are important in maintaining oxygenation and preventing further lung injury. Correcting hypotension, electrolyte disturbances, and hypothermia is also necessary. Attempting to drain water from the lungs is ineffective.

Patients without associated physical injury who are asymptomatic and have no evidence of respiratory compromise after six hours can be safely discharged home. Ventilation strategies aim to maintain oxygenation while minimizing ventilator-associated lung injury.

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.

Children with gastroenteritis who exhibit jittery movements, increased muscle tone, hyper-reflexia, or convulsions should be suspected of having hypernatraemic dehydration. This condition occurs when there is an excessive amount of sodium in the body. In this case, the patient’s history aligns with gastroenteritis, which puts them at risk for hypernatraemia. The presence of jittery movements, increased muscle tone, and hyper-reflexia further support this suspicion. To confirm the diagnosis, it is recommended to send a sample for urea and electrolyte testing to assess the patient’s sodium levels.

Further Reading:

Gastroenteritis is a common condition in children, particularly those under the age of 5. It is characterized by the sudden onset of diarrhea, with or without vomiting. The most common cause of gastroenteritis in infants and young children is rotavirus, although other viruses, bacteria, and parasites can also be responsible. Prior to the introduction of the rotavirus vaccine in 2013, rotavirus was the leading cause of gastroenteritis in children under 5 in the UK. However, the vaccine has led to a significant decrease in cases, with a drop of over 70% in subsequent years.

Norovirus is the most common cause of gastroenteritis in adults, but it also accounts for a significant number of cases in children. In England & Wales, there are approximately 8,000 cases of norovirus each year, with 15-20% of these cases occurring in children under 9.

When assessing a child with gastroenteritis, it is important to consider whether there may be another more serious underlying cause for their symptoms. Dehydration assessment is also crucial, as some children may require intravenous fluids. The NICE traffic light system can be used to identify the risk of serious illness in children under 5.

In terms of investigations, stool microbiological testing may be indicated in certain cases, such as when the patient has been abroad, if diarrhea lasts for more than 7 days, or if there is uncertainty over the diagnosis. U&Es may be necessary if intravenous fluid therapy is required or if there are symptoms and/or signs suggestive of hypernatremia. Blood cultures may be indicated if sepsis is suspected or if antibiotic therapy is planned.

Fluid management is a key aspect of treating children with gastroenteritis. In children without clinical dehydration, normal oral fluid intake should be encouraged, and oral rehydration solution (ORS) supplements may be considered. For children with dehydration, ORS solution is the preferred method of rehydration, unless intravenous fluid therapy is necessary. Intravenous fluids may be required for children with shock or those who are unable to tolerate ORS solution.

Antibiotics are generally not required for gastroenteritis in children, as most cases are viral or self-limiting. However, there are some exceptions, such as suspected or confirmed sepsis, Extraintestinal spread of bacterial infection, or specific infections like Clostridium difficile-associated pseudomembranous enterocolitis or giardiasis.

The most probable diagnosis in this case is septic arthritis, which occurs when an infectious agent invades a joint and causes pus formation. The clinical features of septic arthritis include pain in the affected joint, redness, warmth, and swelling of the joint, and difficulty in moving the joint. Patients may also experience fever and overall feeling of being unwell.

The most common cause of septic arthritis is Staphylococcus aureus, but other bacteria can also be responsible. These include Streptococcus spp., Haemophilus influenzae, Neisseria gonorrhoea (typically seen in sexually active young adults with macules or vesicles on the trunk), and Escherichia coli (common in intravenous drug users, the elderly, and seriously ill individuals).

According to the current recommendations by NICE (National Institute for Health and Care Excellence) and the BNF (British National Formulary), the treatment for septic arthritis involves using specific antibiotics. Flucloxacillin is the first-line choice, but if a patient is allergic to penicillin, clindamycin can be used instead. If there is suspicion of MRSA (Methicillin-resistant Staphylococcus aureus), vancomycin is recommended. In cases where gonococcal arthritis or Gram-negative infection is suspected, cefotaxime is the preferred antibiotic.

The suggested duration of treatment for septic arthritis is 4-6 weeks, although it may be longer if the infection is complicated.

The preferred diagnostic test for hyperaldosteronism is the plasma aldosterone-to-renin ratio (ARR). Hyperaldosteronism is also known as Conn’s syndrome and can be diagnosed by measuring aldosterone and renin levels. By calculating the aldosterone-to-renin ratio, an abnormal increase (>30 ng/dL per ng/mL/h) can indicate primary hyperaldosteronism. Adrenal insufficiency can be detected using the Synacthen test. To detect phaeochromocytoma, tests such as plasma metanephrines and urine vanillylmandelic acid are used. The dexamethasone suppression test is employed for diagnosing Cushing syndrome.

Further Reading:

Hyperaldosteronism is a condition characterized by excessive production of aldosterone by the adrenal glands. It can be classified into primary and secondary hyperaldosteronism. Primary hyperaldosteronism, also known as Conn’s syndrome, is typically caused by adrenal hyperplasia or adrenal tumors. Secondary hyperaldosteronism, on the other hand, is a result of high renin levels in response to reduced blood flow across the juxtaglomerular apparatus.

Aldosterone is the main mineralocorticoid steroid hormone produced by the adrenal cortex. It acts on the distal renal tubule and collecting duct of the nephron, promoting the reabsorption of sodium ions and water while secreting potassium ions.

The causes of hyperaldosteronism vary depending on whether it is primary or secondary. Primary hyperaldosteronism can be caused by adrenal adenoma, adrenal hyperplasia, adrenal carcinoma, or familial hyperaldosteronism. Secondary hyperaldosteronism can be caused by renal artery stenosis, reninoma, renal tubular acidosis, nutcracker syndrome, ectopic tumors, massive ascites, left ventricular failure, or cor pulmonale.

Clinical features of hyperaldosteronism include hypertension, hypokalemia, metabolic alkalosis, hypernatremia, polyuria, polydipsia, headaches, lethargy, muscle weakness and spasms, and numbness. It is estimated that hyperaldosteronism is present in 5-10% of patients with hypertension, and hypertension in primary hyperaldosteronism is often resistant to drug treatment.

Diagnosis of hyperaldosteronism involves various investigations, including U&Es to assess electrolyte disturbances, aldosterone-to-renin plasma ratio (ARR) as the gold standard diagnostic test, ECG to detect arrhythmia, CT/MRI scans to locate adenoma, fludrocortisone suppression test or oral salt testing to confirm primary hyperaldosteronism, genetic testing to identify familial hyperaldosteronism, and adrenal venous sampling to determine lateralization prior to surgery.

Treatment of primary hyperaldosteronism typically involves surgical adrenalectomy for patients with unilateral primary aldosteronism. Diet modification with sodium restriction and potassium supplementation may also be recommended.

Fragility fractures occur when a person experiences a fracture from a force that would not typically cause a fracture, such as a fall from a standing height or less. The most common areas for fragility fractures are the vertebrae, hip, and wrist. Osteoporosis is diagnosed when a patient’s bone mineral density, measured by a T-score on a DEXA scan, is -2.5 standard deviations or below. This T-score compares the patient’s bone density to the peak bone density of a population. In women over 75 years old, osteoporosis can be assumed without a DEXA scan. Osteopenia is diagnosed when a patient’s T-score is between -1 and -2.5 standard deviations below peak bone density. Risk factors for fractures include a family history of hip fractures, excessive alcohol consumption, and rheumatoid arthritis. Low bone mineral density can be indicated by a BMI below 22 kg/m2, untreated menopause, and conditions causing prolonged immobility or certain medical conditions. Medications used to prevent osteoporotic fractures in postmenopausal women include alendronate, risedronate, etidronate, and strontium ranelate. Raloxifene is not used for primary prevention. Alendronate is typically the first-choice medication and is recommended for women over 70 years old with confirmed osteoporosis and either a risk factor for fracture or low bone mineral density. Women over 75 years old with two risk factors or two indicators of low bone mineral density may be assumed to have osteoporosis without a DEXA scan. Other pharmacological interventions can be tried if alendronate is not tolerated.

It is unlikely that this patient has glandular fever, as school exclusion is not necessary for this condition. However, it is important to note that in the UK, school exclusion is not required for tonsillitis either. The only exception is if a child has tonsillitis and a rash consistent with scarlet fever, in which case exclusion is necessary for 24 hours after starting antibiotics. The child and parents should be provided with additional information about glandular fever (refer to the notes below).

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.

Cardiac tamponade is characterized by several classic clinical signs. These include distended neck veins, hypotension, and muffled heart sounds. These three signs are collectively known as Beck’s triad. Additionally, patients with cardiac tamponade may also experience pulseless electrical activity (PEA). It is important to recognize these signs as they can indicate the presence of cardiac tamponade.

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.

When treating diabetic foot ulcers that are infected, the severity of the ulcer is used to determine the appropriate antimicrobial therapy. In the case of a mild foot infection (PEDIS 2 grade), the first-line treatment is typically flucloxacillin. Based on the information provided, there is no indication that pseudomonas or MRSA should be suspected. For mild infections, it is reasonable to prescribe flucloxacillin at a dosage of 500 mg-1g four times a day for a duration of 7 days. It is important to reassess the patient at the end of the treatment course.

Further Reading:

Diabetic foot is a complication that can occur in individuals with diabetes due to long-standing high blood sugar levels. This leads to a process called glycation or glycosylation, where glucose binds to proteins and lipids in the body. Abnormal protein glycation can cause cellular dysfunction and various complications.

One of the main problems in diabetic foot is peripheral vascular disease and peripheral neuropathy. These conditions can result in significant foot issues, as trauma to the feet may go unnoticed and untreated. Vascular disease also impairs wound healing and increases the risk of developing ulcers.

Clinical features of diabetic foot include reduced sensation, especially to vibration, non-dermatomal sensory loss, foot deformities such as pes cavus and claw toes, and weak or absent foot pulses. It is important for diabetic patients to have their feet assessed regularly, at least annually, to identify any potential problems. Additional foot assessments should also be conducted during hospital admissions.

During a diabetic foot assessment, the healthcare provider should remove shoes, socks, and any bandages or dressings to examine both feet. They should assess for neuropathy using a 10 g monofilament to test foot sensation and check for limb ischemia by examining pulses and performing ankle brachial pressure index (ABPI) measurements. Any abnormal tissue, such as ulcers, calluses, infections, inflammation, deformities, or gangrene, should be documented. The risk of Charcot arthropathy should also be assessed.

The severity of foot ulcers in diabetic patients can be documented using standardized systems such as SINBAD or the University of Texas classification. The presence and severity of diabetic foot infection can be determined based on criteria such as local swelling, induration, erythema, tenderness, pain, warmth, and purulent discharge.

Management of foot ulcers involves offloading, control of foot infection, control of ischemia, wound debridement, and appropriate wound dressings. Antibiotics may be necessary depending on the severity of the infection. Diabetic patients with foot ulcers should undergo initial investigations including blood tests, wound swabs, and imaging to assess for possible osteomyelitis.

Charcot foot is a serious complication of diabetic peripheral neuropathy that results in progressive destructive arthropathy and foot deformity. Signs of Charcot foot include redness, swelling, warm skin, pain, and deformity. The hallmark deformity is midfoot collapse, known as the rocker-bottom foot.

Ketamine sedation in children should only be performed by a trained and competent clinician who is capable of managing complications, especially those related to the airway. The clinician should have completed the necessary training and have the appropriate skills for procedural sedation. It is important for the clinician to consider the length of the procedure before deciding to use ketamine sedation, as lengthy procedures may be more suitable for general anesthesia.

Examples of procedures where ketamine may be used in children include suturing, fracture reduction/manipulation, joint reduction, burn management, incision and drainage of abscess, tube thoracostomy placement, foreign body removal, and wound exploration/irrigation.

During the ketamine sedation procedure, a minimum of three staff members should be present: a doctor to manage the sedation and airway, a clinician to perform the procedure, and an experienced nurse to monitor and support the patient, family, and clinical staff. The child should be sedated and managed in a high dependency or resuscitation area with immediate access to resuscitation facilities. Monitoring should include sedation level, pain, ECG, blood pressure, respiration, pulse oximetry, and capnography, with observations taken and recorded every 5 minutes.

Prior to the procedure, consent should be obtained from the parent or guardian after discussing the proposed procedure and use of ketamine sedation. The risks and potential complications should be explained, including mild or moderate/severe agitation, rash, vomiting, transient clonic movements, and airway problems. The parent should also be informed that certain common side effects, such as nystagmus, random purposeless movements, muscle twitching, rash, and vocalizations, are of no clinical significance.

Topical anesthesia may be considered to reduce the pain of intravenous cannulation, but this step may not be advisable if the procedure is urgent. The clinician should also ensure that key resuscitation drugs are readily available and doses are calculated for the patient in case they are needed.

Before administering ketamine, the child should be prepared by encouraging the parents or guardians to talk to them about happy thoughts and topics to minimize unpleasant emergence phenomena. The dose of ketamine is typically 1.0 mg/kg by slow intravenous injection over at least one minute, with additional doses of 0.5 mg/kg administered as required after 5-10 minutes to achieve the desired dissociative state.

Based on the patient’s symptoms and medical history, the most likely organism responsible for this case of infective endocarditis is Streptococcus viridans. This is because the patient has a history of aortic stenosis, which is a risk factor for developing infective endocarditis. Additionally, the patient had a tooth extraction prior to the onset of symptoms, which can introduce bacteria into the bloodstream and increase the risk of infective endocarditis. Streptococcus viridans is a common cause of infective endocarditis, particularly in patients with underlying heart valve disease.

Further Reading:

Infective endocarditis (IE) is an infection that affects the innermost layer of the heart, known as the endocardium. It is most commonly caused by bacteria, although it can also be caused by fungi or viruses. IE can be classified as acute, subacute, or chronic depending on the duration of illness. Risk factors for IE include IV drug use, valvular heart disease, prosthetic valves, structural congenital heart disease, previous episodes of IE, hypertrophic cardiomyopathy, immune suppression, chronic inflammatory conditions, and poor dental hygiene.

The epidemiology of IE has changed in recent years, with Staphylococcus aureus now being the most common causative organism in most industrialized countries. Other common organisms include coagulase-negative staphylococci, streptococci, and enterococci. The distribution of causative organisms varies depending on whether the patient has a native valve, prosthetic valve, or is an IV drug user.

Clinical features of IE include fever, heart murmurs (most commonly aortic regurgitation), non-specific constitutional symptoms, petechiae, splinter hemorrhages, Osler’s nodes, Janeway’s lesions, Roth’s spots, arthritis, splenomegaly, meningism/meningitis, stroke symptoms, and pleuritic pain.

The diagnosis of IE is based on the modified Duke criteria, which require the presence of certain major and minor criteria. Major criteria include positive blood cultures with typical microorganisms and positive echocardiogram findings. Minor criteria include fever, vascular phenomena, immunological phenomena, and microbiological phenomena. Blood culture and echocardiography are key tests for diagnosing IE.

In summary, infective endocarditis is an infection of the innermost layer of the heart that is most commonly caused by bacteria. It can be classified as acute, subacute, or chronic and can be caused by a variety of risk factors. Staphylococcus aureus is now the most common causative organism in most industrialized countries. Clinical features include fever, heart murmurs, and various other symptoms. The diagnosis is based on the modified Duke criteria, which require the presence of certain major and minor criteria. Blood culture and echocardiography are important tests for diagnosing IE.

Addison’s disease, a condition characterized by insufficient production of hormones by the adrenal glands, has different causes depending on the geographical location. Tuberculosis is the leading cause of Addison’s disease globally, while autoimmune adrenalitis is the most common cause in developed countries like the UK.

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.

Acne conglobata is an extremely severe form of acne where acne nodules come together and create sinuses. Acne fulminans, on the other hand, is a rare and severe complication of acne conglobata that is accompanied by systemic symptoms. It is linked to elevated levels of androgenic hormones, specific autoimmune conditions, and a genetic predisposition.

The typical clinical characteristics of acne fulminans are as follows:

– Sudden and abrupt onset
– Inflammatory and ulcerated nodular acne primarily found on the chest and back
– Often painful lesions
– Ulcers on the upper trunk covered with bleeding crusts
– Severe acne scarring
– Fluctuating fever
– Painful joints and arthropathy
– General feeling of illness (malaise)
– Loss of appetite and weight loss
– Enlarged liver and spleen (hepatosplenomegaly)

It is crucial to refer patients immediately for a specialist evaluation and hospital admission. Treatment options for acne fulminans include systemic corticosteroids, dapsone, ciclosporin, and high-dose intravenous antibiotics.

Thyroid storm is a rare condition that affects only 1-2% of patients with hyperthyroidism. However, it is crucial to diagnose it promptly because it has a high mortality rate of approximately 10%. Thyroid storm is often triggered by a physiological stressor, such as stopping antithyroid therapy prematurely, recent surgery or radio-iodine treatment, infections (especially chest infections), trauma, diabetic ketoacidosis or hyperosmolar diabetic crisis, thyroid hormone overdose, pre-eclampsia. It typically occurs in patients with Graves’ disease or toxic multinodular goitre and presents with sudden and severe hyperthyroidism. Symptoms include high fever (over 41°C), dehydration, rapid heart rate (greater than 140 beats per minute) with or without irregular heart rhythms, low blood pressure, congestive heart failure, nausea, jaundice, vomiting, diarrhea, abdominal pain, confusion, agitation, delirium, psychosis, seizures, or coma.

To diagnose thyroid storm, various blood tests should be conducted, including a full blood count, urea and electrolytes, blood glucose, coagulation screen, CRP, and thyroid profile (T4/T3 and TSH). A bone profile/calcium test should also be done as 10% of patients develop hypocalcemia. Blood cultures should be taken as well. Other important investigations include a urine dipstick/MC&S, chest X-ray, and ECG.

The management of thyroid storm involves several steps. Intravenous fluids, such as 1-2 liters of 0.9% saline, should be administered. Airway support and management should be provided as necessary. A nasogastric tube should be inserted if the patient is vomiting. Urgent referral for inpatient management is essential. Paracetamol (1 g PO/IV) can be given to reduce fever. Benzodiazepines, such as diazepam (5-20 mg PO/IV), can be used for sedation. Steroids, like hydrocortisone (100 mg IV), may be necessary if there is co-existing adrenal suppression. Antibiotics should be prescribed if there is an intercurrent infection. Beta-blockers, such as propranolol (80 mg PO), can help control heart rate. High-dose carbimazole (45-60 mg/day) is recommended.

Cerebral edema is the most significant complication of diabetic ketoacidosis (DKA), leading to death in many cases. It occurs in approximately 0.2-1% of DKA cases. The high blood glucose levels cause an osmolar gradient, resulting in the movement of water from the intracellular fluid (ICF) to the extracellular fluid (ECF) space and a decrease in cell volume. When insulin and intravenous fluids are administered to correct the condition, the effective osmolarity decreases rapidly, causing a reversal of the fluid shift and the development of cerebral edema.

Cerebral edema is associated with a higher mortality rate and poor neurological outcomes. To prevent its occurrence, it is important to slowly normalize osmolarity over a period of 48 hours, paying attention to glucose and sodium levels, as well as ensuring proper hydration. Monitoring the child for symptoms such as headache, recurrent vomiting, irritability, changes in Glasgow Coma Scale (GCS), abnormal slowing of heart rate, and increasing blood pressure is crucial.

If cerebral edema does occur, it should be treated with either a hypertonic (3%) saline solution at a dosage of 3 ml/kg or a mannitol infusion at a dosage of 250-500 mg/kg over a 20-minute period.

In addition to cerebral edema, there are other complications associated with DKA in children, including cardiac arrhythmias, pulmonary edema, and acute renal failure.

Anaemia can be categorized based on the size of red blood cells. Microcytic anaemia, characterized by a mean corpuscular volume (MCV) of less than 80 fl, can be caused by various factors such as iron deficiency, thalassaemia, anaemia of chronic disease (which can also be normocytic), sideroblastic anaemia (which can also be normocytic), lead poisoning, and aluminium toxicity (although this is now rare and mainly affects haemodialysis patients).

On the other hand, normocytic anaemia, with an MCV ranging from 80 to 100 fl, can be attributed to conditions like haemolysis, acute haemorrhage, bone marrow failure, anaemia of chronic disease (which can also be microcytic), mixed iron and folate deficiency, pregnancy, chronic renal failure, and sickle-cell disease.

Lastly, macrocytic anaemia, characterized by an MCV greater than 100 fl, can be caused by factors such as B12 deficiency, folate deficiency, hypothyroidism, reticulocytosis, liver disease, alcohol abuse, myeloproliferative disease, myelodysplastic disease, and certain drugs like methotrexate, hydroxyurea, and azathioprine.

It is important to understand the different causes of anaemia based on red cell size as this knowledge can aid in the diagnosis and management of this condition.

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.

The initial indication of progressive compression on the oculomotor nerve is the dilation of the pupil. In cases where the oculomotor nerve is being compressed, the outer parasympathetic fibers are typically affected before the inner motor fibers. These parasympathetic fibers are responsible for stimulating the constriction of the pupil. When they are disrupted, the sympathetic stimulation of the pupil is unopposed, leading to the dilation of the pupil (known as mydriasis or blown pupil). This symptom is usually observed before the drooping of the eyelid (lid ptosis) and the downward and outward positioning of the eye.

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.

Potentially, there can be a serious condition called hypokalaemia, which is characterized by low levels of potassium in the body. This condition should be taken seriously, especially in cases of severe asthma, as it can be made worse by certain medications like theophyllines (such as aminophylline and Uniphyllin Continus), corticosteroids, and low oxygen levels. Additionally, the use of thiazide and loop diuretics can also worsen hypokalaemia. Therefore, it is important to regularly monitor the levels of potassium in the blood of individuals with severe asthma.

It is worth noting that spironolactone, a type of diuretic, is known as a potassium-sparing medication. This means that it does not typically contribute to hypokalaemia.

There is an increased risk of neural tube defects in women with epilepsy who take carbamazepine during pregnancy, ranging from 2 to 10 times higher. Additionally, there is a risk of haemorrhagic disease of the newborn associated with this medication. It is crucial to have discussions about epilepsy treatments with women of childbearing age during the planning stages so that they can start early supplementation of folic acid.

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

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

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

Aspirin: High doses of aspirin can cause first-trimester abortions, delayed onset 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 given late in pregnancy, these medications can result in respiratory depression and a neonatal withdrawal syndrome.

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

Carbamazepine: This medication is associated with haemorrhagic disease of the newborn and neural tube defects.

Chloramphenicol: Use of this drug can cause grey baby syndrome in newborns.

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

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

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

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

Heparin: Use of heparin during pregnancy is associated with an acceptable bleeding rate and a low rate of thrombotic recurrence in the mother.

Healthcare workers responding to contaminated casualties must prioritize their own safety by wearing appropriate personal protective equipment. This is crucial because secondary contamination can occur. Additionally, if working in contaminated areas, healthcare workers should maximize ventilation and use breathing equipment. Ensuring the safety of healthcare workers is essential as they cannot effectively help the casualties without it.

The first step in managing contaminated casualties is early skin decontamination. It is important to move the casualties to a safe area and remove all contaminated clothing to minimize further exposure. The skin should then be thoroughly rinsed with water to physically remove the nerve agent. After rinsing, it should be washed with an alkaline solution of soap and water or a 0.5% hypochlorite solution to chemically neutralize the nerve agent. To prevent ongoing absorption through the eyes, contact lenses should be removed and the eyes irrigated.

Resuscitation should be initiated using an ABCDE approach, and casualties should be supported and transferred to the hospital as quickly as possible. Ventilation may be necessary in some cases. Nerve agent antidote autoinjectors can be utilized, and the use of these should be guided by local policy for prehospital personnel.

Injuries to the zygomatic arch that result in limited mouth opening or closing can occur when the temporalis muscle or mandibular condyle becomes trapped. If this happens, it is important to seek immediate medical attention. It is worth noting that the muscles responsible for chewing (masseter, temporalis, medial pterygoid, and lateral pterygoid) are innervated by the mandibular nerve (V3).

Further Reading:

Zygomatic injuries, also known as zygomatic complex fractures, involve fractures of the zygoma bone and often affect surrounding bones such as the maxilla and temporal bones. These fractures can be classified into four positions: the lateral and inferior orbital rim, the zygomaticomaxillary buttress, and the zygomatic arch. The full extent of these injuries may not be visible on plain X-rays and may require a CT scan for accurate diagnosis.

Zygomatic fractures can pose risks to various structures in the face. The temporalis muscle and coronoid process of the mandible may become trapped in depressed fractures of the zygomatic arch. The infraorbital nerve, which passes through the infraorbital foramen, can be injured in zygomaticomaxillary complex fractures. In orbital floor fractures, the inferior rectus muscle may herniate into the maxillary sinus.

Clinical assessment of zygomatic injuries involves observing facial asymmetry, depressed facial bones, contusion, and signs of eye injury. Visual acuity must be assessed, and any persistent bleeding from the nose or mouth should be noted. Nasal injuries, including septal hematoma, and intra-oral abnormalities should also be evaluated. Tenderness of facial bones and the temporomandibular joint should be assessed, along with any step deformities or crepitus. Eye and jaw movements must also be evaluated.

Imaging for zygomatic injuries typically includes facial X-rays, such as occipitomental views, and CT scans for a more detailed assessment. It is important to consider the possibility of intracranial hemorrhage and cervical spine injury in patients with facial fractures.

Management of most zygomatic fractures can be done on an outpatient basis with maxillofacial follow-up, assuming the patient is stable and there is no evidence of eye injury. However, orbital floor fractures should be referred immediately to ophthalmologists or maxillofacial surgeons. Zygomatic arch injuries that restrict mouth opening or closing due to entrapment of the temporalis muscle or mandibular condyle also require urgent referral. Nasal fractures, often seen in conjunction with other facial fractures, can be managed by outpatient ENT follow-up but should be referred urgently if there is uncontrolled epistaxis, CSF rhinorrhea, or septal hematoma.

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.