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.

Tinnitus is often seen as an early indication of salicylate toxicity, which occurs when there is an excessive use of salicylate. Another common symptom is feeling nauseous and/or vomiting. In the initial stages of a salicylate overdose, individuals may experience respiratory alkalosis, which is caused by the direct stimulation of the respiratory centers in the medulla by salicylate. This leads to hyperventilation and the elimination of carbon dioxide, resulting in alkalosis. As the body metabolizes salicylate, a metabolic acidosis may develop.

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.

This question revolves around the challenge of delivering difficult news. The family involved in this situation have good intentions as they aim to shield their loved one from the distress of understanding the true nature of their underlying condition.

However, if the patient possesses the mental capacity to comprehend, it is important to disclose the details of their condition if they express a desire to know. Engage in an open and sensitive conversation with the patient, allowing them to determine the extent of information they wish to receive about their condition.

For further information, refer to the GMC Guidance on the topic of utilizing and divulging patient information for direct care.
https://www.gmc-uk.org/ethical-guidance/ethical-guidance-for-doctors/confidentiality/using-and-disclosing-patient-information-for-direct-care

Pyloric stenosis is characterized by recurring episodes of projectile vomiting and the presence of a mass in the upper abdomen, often described as an olive. This patient exhibits clinical features that align with pyloric stenosis and possesses several common risk factors, including being a male, being the firstborn son, being bottle-fed, and being delivered via C-section. It is important to note that intestinal atresia is typically diagnosed either during pregnancy or shortly after birth.

Further Reading:

Pyloric stenosis is a condition that primarily affects infants, characterized by the thickening of the muscles in the pylorus, leading to obstruction of the gastric outlet. It typically presents between the 3rd and 12th weeks of life, with recurrent projectile vomiting being the main symptom. The condition is more common in males, with a positive family history and being first-born being additional risk factors. Bottle-fed children and those delivered by c-section are also more likely to develop pyloric stenosis.

Clinical features of pyloric stenosis include projectile vomiting, usually occurring about 30 minutes after a feed, as well as constipation and dehydration. A palpable mass in the upper abdomen, often described as like an olive, may also be present. The persistent vomiting can lead to electrolyte disturbances, such as hypochloremia, alkalosis, and mild hypokalemia.

Ultrasound is the preferred diagnostic tool for confirming pyloric stenosis. It can reveal specific criteria, including a pyloric muscle thickness greater than 3 mm, a pylorus longitudinal length greater than 15-17 mm, a pyloric volume greater than 1.5 cm3, and a pyloric transverse diameter greater than 13 mm.

The definitive treatment for pyloric stenosis is pyloromyotomy, a surgical procedure that involves making an incision in the thickened pyloric muscle to relieve the obstruction. Before surgery, it is important to correct any hypovolemia and electrolyte disturbances with intravenous fluids. Overall, pyloric stenosis is a relatively common condition in infants, but with prompt diagnosis and appropriate management, it can be effectively treated.

Severe hypothermia is defined as having a core body temperature below 28ºC. The Royal College of Emergency Medicine (RCEM) also uses the term profound hypothermia to describe individuals with a core temperature below 20ºC.

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.

Lidocaine functions by inhibiting the activity of voltage-gated sodium channels, preventing the flow of sodium ions through these channels.

Further Reading:

In the management of respiratory and cardiac arrest, several drugs are commonly used to help restore normal function and improve outcomes. Adrenaline is a non-selective agonist of adrenergic receptors and is administered intravenously at a dose of 1 mg every 3-5 minutes. It works by causing vasoconstriction, increasing systemic vascular resistance (SVR), and improving cardiac output by increasing the force of heart contraction. Adrenaline also has bronchodilatory effects.

Amiodarone is another drug used in cardiac arrest situations. It blocks voltage-gated potassium channels, which prolongs repolarization and reduces myocardial excitability. The initial dose of amiodarone is 300 mg intravenously after 3 shocks, followed by a dose of 150 mg after 5 shocks.

Lidocaine is an alternative to amiodarone in cardiac arrest situations. It works by blocking sodium channels and decreasing heart rate. The recommended dose is 1 mg/kg by slow intravenous injection, with a repeat half of the initial dose after 5 minutes. The maximum total dose of lidocaine is 3 mg/kg.

Magnesium sulfate is used to reverse myocardial hyperexcitability associated with hypomagnesemia. It is administered intravenously at a dose of 2 g over 10-15 minutes. An additional dose may be given if necessary, but the maximum total dose should not exceed 3 g.

Atropine is an antagonist of muscarinic acetylcholine receptors and is used to counteract the slowing of heart rate caused by the parasympathetic nervous system. It is administered intravenously at a dose of 500 mcg every 3-5 minutes, with a maximum dose of 3 mg.

Naloxone is a competitive antagonist for opioid receptors and is used in cases of respiratory arrest caused by opioid overdose. It has a short duration of action, so careful monitoring is necessary. The initial dose of naloxone is 400 micrograms, followed by 800 mcg after 1 minute. The dose can be gradually escalated up to 2 mg per dose if there is no response to the preceding dose.

It is important for healthcare professionals to have knowledge of the pharmacology and dosing schedules of these drugs in order to effectively manage respiratory and cardiac arrest situations.

The classification of severity in salicylate overdose can sometimes be confused by mixing up the ingested dose and the measured plasma salicylate level. To clarify, when using the blood salicylate level, moderate toxicity is indicated by a level of 350-700 mg/L, while severe toxicity is indicated by a level exceeding 700 mg/L.

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..

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.

CT scan is considered the most reliable imaging technique for diagnosing intra-abdominal conditions. It is also considered the gold standard for evaluating organ damage. However, it is crucial to carefully consider the specific circumstances before using CT scan, as it may not be suitable for unstable patients or those who clearly require immediate surgical intervention. In such cases, other methods like FAST can be used to detect fluid in the abdominal cavity, although it is not as accurate in assessing injuries to solid organs or hollow structures within the abdomen.

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.

Malignant otitis externa, also known as necrotising otitis externa, is a severe infection that affects the external auditory canal and spreads to the temporal bone and nearby tissues, leading to skull base osteomyelitis. The primary cause of this condition is usually an infection by Pseudomonas aeruginosa. It is commonly observed in older individuals with diabetes.

Further Reading:

Otitis externa is inflammation of the skin and subdermis of the external ear canal. It can be acute, lasting less than 6 weeks, or chronic, lasting more than 3 months. Malignant otitis externa, also known as necrotising otitis externa, is a severe and potentially life-threatening infection that can spread to the bones and surrounding structures of the ear. It is most commonly caused by Pseudomonas aeruginosa.

Symptoms of malignant otitis externa include severe and persistent ear pain, headache, discharge from the ear, fever, malaise, vertigo, and profound hearing loss. It can also lead to facial nerve palsy and other cranial nerve palsies. In severe cases, the infection can spread to the central nervous system, causing meningitis, brain abscess, and sepsis.

Acute otitis externa is typically caused by Pseudomonas aeruginosa or Staphylococcus aureus, while chronic otitis externa can be caused by fungal infections such as Aspergillus or Candida albicans. Risk factors for otitis externa include eczema, psoriasis, dermatitis, acute otitis media, trauma to the ear canal, foreign bodies in the ear, water exposure, ear canal obstruction, and long-term antibiotic or steroid use.

Clinical features of otitis externa include itching of the ear canal, ear pain, tenderness of the tragus and/or pinna, ear discharge, hearing loss if the ear canal is completely blocked, redness and swelling of the ear canal, debris in the ear canal, and cellulitis of the pinna and adjacent skin. Tender regional lymphadenitis is uncommon.

Management of acute otitis externa involves general ear care measures, optimizing any underlying medical or skin conditions that are risk factors, avoiding the use of hearing aids or ear plugs if there is a suspected contact allergy, and avoiding the use of ear drops if there is a suspected allergy to any of its ingredients. Treatment options include over-the-counter acetic acid 2% ear drops or spray, aural toileting via dry swabbing, irrigation, or microsuction, and prescribing topical antibiotics with or without a topical corticosteroid. Oral antibiotics may be prescribed in severe cases or for immunocompromised individuals.

Follow-up is advised if symptoms do not improve within 48-72 hours of starting treatment, if symptoms have not fully resolved

Shingles is caused by the varicella-zoster virus (VZV), which primarily infects individuals during childhood as chickenpox. However, the initial infection can also be subclinical. After the primary infection, the virus remains dormant in the sensory nervous system, specifically in the geniculate, trigeminal, or dorsal root ganglia.

During the dormant phase, the virus is kept under control by the immune system for many years. However, it can later become active and cause a flare-up in a specific dermatomal segment. This reactivation occurs when the virus travels down the affected nerve over a period of 3 to 5 days, leading to inflammation within and around the nerve. The decline in cell-mediated immunity is believed to trigger the virus’s reactivation.

Several factors can trigger the reactivation of the varicella-zoster virus, including advancing age (with most patients being older than 50), immunosuppressive illnesses, physical trauma, and psychological stress. In immunocompetent patients, the most common site of reactivation is the thoracic nerves, followed by the ophthalmic division of the trigeminal nerve.

Diagnosing shingles can usually be done based on the patient’s history and clinical examination alone, as it has a distinct history and appearance. While various techniques can be used to detect the virus or antibodies, they are often unnecessary. Microscopy and culture tests using scrapings and smears typically yield negative results.

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.

Early assessment of the airway is a critical aspect of managing a patient who has suffered burns. Airway blockage can occur rapidly due to direct injury, such as inhalation injury, or as a result of swelling caused by the burn. If there is a history of trauma, the airway should be evaluated and treated while maintaining control of the cervical spine.

Signs of airway obstruction may not be immediately apparent, as swelling typically does not occur right away. Children with thermal burns are at a higher risk of airway obstruction compared to adults due to their smaller airway size, so they require careful observation.

There are several risk factors for airway obstruction in burned patients, including inhalation injury, the presence of soot in the mouth or nostrils, singed nasal hairs, burns to the head, face, or neck, burns inside the mouth, a large burn area with increasing depth, and associated trauma. A carboxyhemoglobin level above 10% is also suggestive of an inhalation injury.

Based on the patient’s symptoms of suprapubic pain, increased urinary frequency, and foul-smelling urine, along with the presence of nitrites, leukocytes, and blood in the urine dipstick test, the most likely cause of her symptoms is a urinary tract infection (UTI). The most probable causative organism for UTIs is Escherichia coli.

Further Reading:

A urinary tract infection (UTI) is an infection that occurs in any part of the urinary system, from the kidneys to the bladder. It is characterized by symptoms such as dysuria, nocturia, polyuria, urgency, incontinence, and changes in urine appearance and odor. UTIs can be classified as lower UTIs, which affect the bladder, or upper UTIs, which involve the kidneys. Recurrent UTIs can be due to relapse or re-infection, and the number of recurrences considered significant depends on age and sex. Uncomplicated UTIs occur in individuals with a normal urinary tract and kidney function, while complicated UTIs are caused by anatomical, functional, or pharmacological factors that make the infection persistent, recurrent, or resistant to treatment.

The most common cause of UTIs is Escherichia coli, accounting for 70-95% of cases. Other causative organisms include Staphylococcus saprophyticus, Proteus mirabilis, and Klebsiella species. UTIs are typically caused by bacteria from the gastrointestinal tract entering the urinary tract through the urethra. Other less common mechanisms of entry include direct spread via the bloodstream or instrumentation of the urinary tract, such as catheter insertion.

Diagnosis of UTIs involves urine dipstick testing and urine culture. A urine culture should be sent in certain circumstances, such as in male patients, pregnant patients, women aged 65 years or older, patients with persistent or unresolved symptoms, recurrent UTIs, patients with urinary catheters, and those with risk factors for resistance or complicated UTIs. Further investigations, such as cystoscopy and imaging, may be required in cases of recurrent UTIs or suspected underlying causes.

Management of UTIs includes simple analgesia, advice on adequate fluid intake, and the prescription of appropriate antibiotics. The choice of antibiotic depends on the patient’s gender and risk factors. For women, first-line antibiotics include nitrofurantoin or trimethoprim, while second-line options include nitrofurantoin (if not used as first-line), pivmecillinam, or fosfomycin. For men, trimethoprim or nitrofurantoin are the recommended antibiotics. In cases of suspected acute prostatitis, fluoroquinolone antibiotics such as ciprofloxacin or ofloxacin may be prescribed for a 4-week course.

Haemothorax often leads to reduced or absent air entry, a dull percussion sound, and decreased fremitus on the affected side. Commonly observed symptoms in patients with haemothorax include decreased or absent air entry, a dull percussion note when the affected side is tapped, reduced fremitus on the affected side, and in cases of massive haemothorax, tracheal deviation away from the affected side. Other signs that may be present include a rapid heart rate (tachycardia), rapid breathing (tachypnoea), low blood pressure (hypotension), and signs of shock.

Further Reading:

Haemothorax is the accumulation of blood in the pleural cavity of the chest, usually resulting from chest trauma. It can be difficult to differentiate from other causes of pleural effusion on a chest X-ray. Massive haemothorax refers to a large volume of blood in the pleural space, which can impair physiological function by causing blood loss, reducing lung volume for gas exchange, and compressing thoracic structures such as the heart and IVC.

The management of haemothorax involves replacing lost blood volume and decompressing the chest. This is done through supplemental oxygen, IV access and cross-matching blood, IV fluid therapy, and the insertion of a chest tube. The chest tube is connected to an underwater seal and helps drain the fluid, pus, air, or blood from the pleural space. In cases where there is prompt drainage of a large amount of blood, ongoing significant blood loss, or the need for blood transfusion, thoracotomy and ligation of bleeding thoracic vessels may be necessary. It is important to have two IV accesses prior to inserting the chest drain to prevent a drop in blood pressure.

In summary, haemothorax is the accumulation of blood in the pleural cavity due to chest trauma. Managing haemothorax involves replacing lost blood volume and decompressing the chest through various interventions, including the insertion of a chest tube. Prompt intervention may be required in cases of significant blood loss or ongoing need for blood transfusion.

Addison’s disease is primarily caused by tuberculosis, making it the most prevalent factor worldwide.

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.

Bacterial vaginosis (BV) is a common condition that affects up to a third of women during their childbearing years. It occurs when there is an overgrowth of bacteria, specifically Gardnerella vaginalis. This bacterium is anaerobic, meaning it thrives in environments without oxygen. As it multiplies, it disrupts the balance of bacteria in the vagina, leading to a rise in pH levels and a decrease in lactic acid-producing lactobacilli. It’s important to note that BV is not a sexually transmitted infection.

The main symptom of BV is a greyish discharge with a distinct fishy odor. However, it’s worth mentioning that around 50% of affected women may not experience any symptoms at all.

To diagnose BV, healthcare providers often use Amsel’s criteria. This involves looking for the presence of three out of four specific criteria: a vaginal pH greater than 4.5, a positive fishy smell test when potassium hydroxide is added, the presence of clue cells on microscopy, and a thin, white, homogeneous discharge.

The primary treatment for BV is oral metronidazole, typically taken for 5-7 days. This medication has an initial cure rate of about 75%. It’s crucial to provide special care to pregnant patients diagnosed with BV, as it has been linked to an increased risk of late miscarriage, early labor, and chorioamnionitis. Therefore, prompt treatment for these patients is of utmost importance.

Central retinal vein occlusion (CRVO) typically leads to painless, one-sided vision loss. When examining the retina, it may appear similar to a ‘pizza thrown against a wall’, with swollen retinal veins, swelling of the optic disc, multiple flame-shaped hemorrhages, and cotton wool spots. Hypertension is present in about 65% of CRVO patients, and it is more common in individuals over the age of 65. Other known risk factors include being elderly, having chronic glaucoma, arteriosclerosis, and polycythemia.

In contrast, central retinal artery occlusion (CRAO) is characterized by a pale retina and a ‘cherry-red spot’ in the macula’s center, which is spared due to its blood supply from the underlying choroid. It is important to differentiate between CRVO and CRAO based on these distinct features.

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.

The recommended daily oral dose for adults is 900 mg, which should be taken in 2-3 divided doses. For severe asthma or COPD, the initial intravenous dose is 5 mg/kg and should be administered over 10-20 minutes. This can be followed by a continuous infusion of 0.5 mg/kg/hour. In the case of a 60 kg patient, the appropriate infusion rate would be 30 mg/hour. It is important to note that the therapeutic range for aminophylline is narrow, ranging from 10-20 microgram/ml. Therefore, it is beneficial to estimate the plasma concentration of aminophylline during long-term treatment.

Depression and dementia are both more prevalent in the elderly population and often coexist. Diagnosing these conditions can be challenging due to the overlapping symptoms they share.

Depression is characterized by a persistent low mood throughout the day, significant unintentional weight changes, sleep disturbances, fatigue, feelings of worthlessness or guilt, difficulty concentrating, loss of interest in activities, and recurrent thoughts of death. It may also manifest as agitation or slowed movements, which can be observed by others.

Dementia, on the other hand, refers to a group of symptoms resulting from a pathological process that leads to significant cognitive impairment. This impairment is more severe than what would be expected for a person’s age. Alzheimer’s disease is the most common form of dementia.

Symptoms of dementia include memory loss, particularly in the short-term, changes in mood that are usually reactive to situations and improve with support and stimulation, infrequent thoughts about death, alterations in personality, difficulty finding the right words, struggles with complex tasks, urinary incontinence, loss of appetite and weight in later stages, and agitation in unfamiliar environments.

By understanding the distinct features of depression and dementia, healthcare professionals can better identify and differentiate between these conditions in the elderly population.

Hyperkalaemia, or high levels of potassium in the blood, can be caused by various factors that are not related to drug use. These include conditions such as renal failure, where the kidneys are unable to properly regulate potassium levels, and excess potassium supplementation. Other non-drug causes include Addison’s disease, a condition characterized by adrenal insufficiency, and congenital adrenal hyperplasia. Renal tubular acidosis, specifically type 4, can also lead to hyperkalaemia. Additionally, conditions like rhabdomyolysis, burns and trauma, and tumour lysis syndrome can contribute to elevated potassium levels. Acidosis, an imbalance in the body’s pH levels, is another non-drug cause of hyperkalaemia.

On the other hand, certain medications have been associated with hyperkalaemia. These include ACE inhibitors, angiotensin receptor blockers, NSAIDs, beta-blockers, digoxin, and suxamethonium. These drugs can interfere with the body’s potassium regulation mechanisms and lead to increased levels of potassium in the blood.

In contrast, there are also conditions that result in low levels of potassium, known as hypokalaemia. Bartter’s syndrome, a rare inherited defect in the ascending limb of the loop of Henle, is characterized by hypokalaemic alkalosis and normal to low blood pressure. Type 1 and 2 renal tubular acidosis are other conditions that cause hypokalaemia. On the other hand, type 4 renal tubular acidosis leads to hyperkalaemia. Gitelman’s syndrome, another rare inherited defect, affects the distal convoluted tubule of the kidney and causes a metabolic alkalosis with hypokalaemia and hypomagnesaemia.

Lastly, excessive consumption of liquorice can result in a condition called hypermineralocorticoidism, which can lead to hypokalaemia.

Amiodarone functions by inhibiting voltage-gated potassium channels, leading to an extended repolarization period and decreased excitability of the heart muscle.

Further Reading:

In the management of respiratory and cardiac arrest, several drugs are commonly used to help restore normal function and improve outcomes. Adrenaline is a non-selective agonist of adrenergic receptors and is administered intravenously at a dose of 1 mg every 3-5 minutes. It works by causing vasoconstriction, increasing systemic vascular resistance (SVR), and improving cardiac output by increasing the force of heart contraction. Adrenaline also has bronchodilatory effects.

Amiodarone is another drug used in cardiac arrest situations. It blocks voltage-gated potassium channels, which prolongs repolarization and reduces myocardial excitability. The initial dose of amiodarone is 300 mg intravenously after 3 shocks, followed by a dose of 150 mg after 5 shocks.

Lidocaine is an alternative to amiodarone in cardiac arrest situations. It works by blocking sodium channels and decreasing heart rate. The recommended dose is 1 mg/kg by slow intravenous injection, with a repeat half of the initial dose after 5 minutes. The maximum total dose of lidocaine is 3 mg/kg.

Magnesium sulfate is used to reverse myocardial hyperexcitability associated with hypomagnesemia. It is administered intravenously at a dose of 2 g over 10-15 minutes. An additional dose may be given if necessary, but the maximum total dose should not exceed 3 g.

Atropine is an antagonist of muscarinic acetylcholine receptors and is used to counteract the slowing of heart rate caused by the parasympathetic nervous system. It is administered intravenously at a dose of 500 mcg every 3-5 minutes, with a maximum dose of 3 mg.

Naloxone is a competitive antagonist for opioid receptors and is used in cases of respiratory arrest caused by opioid overdose. It has a short duration of action, so careful monitoring is necessary. The initial dose of naloxone is 400 micrograms, followed by 800 mcg after 1 minute. The dose can be gradually escalated up to 2 mg per dose if there is no response to the preceding dose.

It is important for healthcare professionals to have knowledge of the pharmacology and dosing schedules of these drugs in order to effectively manage respiratory and cardiac arrest situations.

The differences in anti-inflammatory activity among NSAIDs are minimal, but there is significant variation in how individuals respond to and tolerate these drugs. Approximately 60% of patients will experience a positive response to any NSAID, and those who do not respond to one may find relief with another. Pain relief typically begins shortly after taking the first dose, and a full analgesic effect is usually achieved within a week. However, it may take up to 3 weeks to see an anti-inflammatory effect, which may not be easily assessed. If desired results are not achieved within these timeframes, it is recommended to try a different NSAID.

NSAIDs work by reducing the production of prostaglandins through the inhibition of the enzyme cyclo-oxygenase. Different NSAIDs vary in their selectivity for inhibiting different types of cyclo-oxygenase. Selective inhibition of cyclo-oxygenase-2 is associated with a lower risk of gastrointestinal intolerance. Other factors also play a role in susceptibility to gastrointestinal effects, so the choice of NSAID should consider the incidence of gastrointestinal and other side effects.

Ibuprofen, a propionic acid derivative, possesses anti-inflammatory, analgesic, and antipyretic properties. It generally has fewer side effects compared to other non-selective NSAIDs, but its anti-inflammatory properties are weaker. For rheumatoid arthritis, doses of 1.6 to 2.4 g daily are required, and it may not be suitable for conditions where inflammation is prominent, such as acute gout.

Naproxen is often a preferred choice due to its combination of good efficacy and low incidence of side effects. However, it does have a higher occurrence of side effects compared to ibuprofen.

Ketoprofen and diclofenac have similar anti-inflammatory properties to ibuprofen but are associated with more side effects.

Indometacin has an action that is equal to or superior to naproxen, but it also has a high incidence of side effects, including headache, dizziness, and gastrointestinal disturbances.

Nelson’s syndrome is a rare condition that occurs many years after a bilateral adrenalectomy for Cushing’s syndrome. It is believed to develop due to the loss of the normal negative feedback control that suppresses high cortisol levels. As a result, the hypothalamus starts producing CRH again, which stimulates the growth of a pituitary adenoma that produces adrenocorticotropic hormone (ACTH).

Only 15-20% of patients who undergo bilateral adrenalectomy will develop this condition, and it is now rarely seen as the procedure is no longer commonly performed.

The symptoms and signs of Nelson’s syndrome are related to the growth of the pituitary adenoma and the increased production of ACTH and melanocyte-stimulating hormone (MSH) from the adenoma. These may include headaches, visual field defects (up to 50% of cases), increased skin pigmentation, and the possibility of hypopituitarism.

ACTH levels will be significantly elevated (usually >500 ng/L). Thyroxine, TSH, gonadotrophin, and sex hormone levels may be low. Prolactin levels may be high, but not as high as with a prolactin-producing tumor. MRI or CT scanning can be helpful in identifying the presence of an expanding pituitary mass.

The treatment of choice for Nelson’s syndrome is trans-sphenoidal surgery.

For the treatment of young people under 16 years with lower urinary tract infection (UTI), it is important to obtain a urine sample before starting antibiotics. This sample can be tested using a dipstick or sent for culture and susceptibility testing. In cases where children under 5 present with fever along with lower UTI, it is recommended to follow the guidance outlined in the NICE guideline on fever in under 5s.

Immediate antibiotic prescription should be offered to children and young people under 16 years with lower UTI. When making this prescription, it is important to consider previous urine culture and susceptibility results, as well as any history of antibiotic use that may have led to resistant bacteria. If a urine sample has been sent for culture and sensitivity testing, the choice of antibiotic should be reviewed once the microbiological results are available. If the bacteria are found to be resistant and symptoms are not improving, a narrow-spectrum antibiotic should be used whenever possible.

For non-pregnant women aged 16 years and under, the following antibiotics can be considered:
– Children under 3 months: It is recommended to refer to a pediatric specialist and treat with an intravenous antibiotic in line with the NICE guideline on fever in under 5s.
– First-choice in children over 3 months: Nitrofurantoin (if eGFR >45 ml/minute) or Trimethoprim (if low risk of resistance*).
– Second-choice in children over 3 months (when there is no improvement in lower UTI symptoms on first-choice for at least 48 hours, or when first-choice is not suitable): Nitrofurantoin (if eGFR >45 ml/minute and not used as first-choice), Amoxicillin (only if culture results are available and susceptible), or Cefalexin.

Please refer to the BNF for children for dosing information. It is important to consider the risk of resistance when choosing antibiotics. A lower risk of resistance may be more likely if the antibiotic has not been used in the past 3 months, if previous urine culture suggests susceptibility (but was not used), and in younger people in areas where local epidemiology data suggest low resistance. On the other hand, a higher risk of resistance may be more likely with recent antibiotic use and in older people in residential facilities.

Klumpke’s palsy, also known as Dejerine-Klumpke palsy, is a condition where the arm becomes paralyzed due to an injury to the lower roots of the brachial plexus. The most commonly affected root is C8, but T1 can also be involved. The main cause of Klumpke’s palsy is when the arm is pulled forcefully in an outward position during a difficult childbirth. It can also occur in adults with apical lung carcinoma (Pancoast’s syndrome).

Clinically, Klumpke’s palsy is characterized by a deformity known as ‘claw hand’, which is caused by the paralysis of the intrinsic hand muscles. There is also a loss of sensation along the ulnar side of the forearm and hand. In some cases where T1 is affected, a condition called Horner’s syndrome may also be present.

Klumpke’s palsy can be distinguished from Erb’s palsy, which affects the upper roots of the brachial plexus (C5 and sometimes C6). In Erb’s palsy, the arm hangs by the side with the elbow extended and the forearm turned inward (known as the ‘waiter’s tip sign’). Additionally, there is a loss of shoulder abduction, external rotation, and elbow flexion.

The patient’s symptoms strongly suggest a diagnosis of acute cholecystitis. This condition occurs when a gallstone becomes stuck in the outlet of the gallbladder, causing irritation and inflammation of the gallbladder wall. As a result, the gallbladder fills with pus, which is initially sterile but can become infected with bacteria such as Escherichia coli and Klebsiella spp.

The clinical features of acute cholecystitis include severe pain in the upper right quadrant or epigastric, which can radiate to the back and lasts for more than 12 hours. Fevers and rigors are also commonly present, along with nausea and vomiting. Murphy’s sign, a physical examination finding, is highly sensitive and has a high positive predictive value for acute cholecystitis. However, its specificity is lower, as it can also be positive in biliary colic and ascending cholangitis.

In acute cholecystitis, the white cell count and C-reactive protein (CRP) levels are usually elevated. Liver function tests, such as AST, ALT, and ALP, may also be elevated but can often be within the normal range. Bilirubin levels may be mildly elevated, but they can also be normal. If there is a significant elevation in AST, ALT, ALP, or bilirubin, it may indicate other biliary tract conditions, such as ascending cholangitis or choledocholithiasis.

It is important to differentiate acute cholecystitis from other conditions with similar presentations. Renal colic, for example, presents with pain in the loin area and tenderness in the renal angle, which is different from the symptoms seen in acute cholecystitis. Cholangiocarcinoma, a rare type of cancer originating from the biliary epithelium, typically presents with painless jaundice and itching.

To help distinguish between biliary colic, acute cholecystitis, and ascending cholangitis, the following summarizes their key differences:

Biliary colic:
– Pain duration: Less than 12 hours
– Fever: Absent
– Murphy’s sign: Negative
– WCC & CRP: Normal
– AST, ALT & ALP: Normal
– Bilirubin: Normal

Acute cholecystitis:
– Pain duration: More than 12 hours
– Fever: Present
– Murphy’s sign: Positive
– WCC &

Traumatic aortic rupture is a relatively common cause of sudden death following major trauma, especially high-speed road traffic accidents (RTAs). It is estimated that 15-20% of deaths from RTAs are due to this injury. If the aortic rupture is promptly recognized and treated, patients who survive the initial injury can fully recover.

Surviving patients often have an incomplete laceration near the ligamentum arteriosum of the aorta. The continuity is maintained by either an intact adventitial layer or a contained mediastinal hematoma, which prevents immediate exsanguination and death.

Detecting traumatic aortic rupture can be challenging as many patients do not exhibit specific symptoms, and other injuries may also be present, making the diagnosis unclear.

Chest X-ray findings can aid in the diagnosis and include fractures of the 1st and 2nd ribs, a grossly widened mediastinum, a hazy left lung field, obliteration of the aortic knob, 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.

Helical contrast-enhanced CT scanning is highly sensitive and specific for detecting aortic rupture, but it should only be performed on hemodynamically stable patients.

Treatment options include primary repair or resection of the torn segment with replacement using an interposition graft. Endovascular repair is also now considered an acceptable alternative approach.

The primary cause for the majority of out-of-hospital cardiac arrests is cardiovascular disease. This refers to conditions that affect the heart and blood vessels, such as coronary artery disease, heart attacks, and arrhythmias. These conditions can lead to sudden 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.