The ability to rotate the neck actively by 45 degrees to the left and right is a crucial distinction between the ‘no risk’ and ‘low risk’ categories when applying the Canadian C-spine rules. In this case, the patient does not exhibit any high-risk factors for cervical spine injury according to the Canadian C-spine rule. However, they do have a low-risk factor due to their involvement in a minor rear-end motor collision. If a patient with a low-risk factor is unable to actively rotate their neck by 45 degrees in either direction, they should undergo imaging. It is important to note that while the patient’s use of anticoagulation medication may affect the need for brain imaging, it typically does not impact the decision to perform a CT scan of the cervical spine.

Further Reading:

When assessing for cervical spine injury, it is recommended to use the Canadian C-spine rules. These rules help determine the risk level for a potential injury. High-risk factors include being over the age of 65, experiencing a dangerous mechanism of injury (such as a fall from a height or a high-speed motor vehicle collision), or having paraesthesia in the upper or lower limbs. Low-risk factors include being involved in a minor rear-end motor vehicle collision, being comfortable in a sitting position, being ambulatory since the injury, having no midline cervical spine tenderness, or experiencing a delayed onset of neck pain. If a person is unable to actively rotate their neck 45 degrees to the left and right, their risk level is considered low. If they have one of the low-risk factors and can actively rotate their neck, their risk level remains low.

If a high-risk factor is identified or if a low-risk factor is identified and the person is unable to actively rotate their neck, full in-line spinal immobilization should be maintained and imaging should be requested. Additionally, if a patient has risk factors for thoracic or lumbar spine injury, imaging should be requested. However, if a patient has low-risk factors for cervical spine injury, is pain-free, and can actively rotate their neck, full in-line spinal immobilization and imaging are not necessary.

NICE recommends CT as the primary imaging modality for cervical spine injury in adults aged 16 and older, while MRI is recommended as the primary imaging modality for children under 16.

Different mechanisms of spinal trauma can cause injury to the spine in predictable ways. The majority of cervical spine injuries are caused by flexion combined with rotation. Hyperflexion can result in compression of the anterior aspects of the vertebral bodies, stretching and tearing of the posterior ligament complex, chance fractures (also known as seatbelt fractures), flexion teardrop fractures, and odontoid peg fractures. Flexion and rotation can lead to disruption of the posterior ligament complex and posterior column, fractures of facet joints, lamina, transverse processes, and vertebral bodies, and avulsion of spinous processes. Hyperextension can cause injury to the anterior column, anterior fractures of the vertebral body, and potential retropulsion of bony fragments or discs into the spinal canal. Rotation can result in injury to the posterior ligament complex and facet joint dislocation.

The current algorithm for the treatment of a convulsing child, known as APLS, is as follows:

Step 1 (5 minutes after the start of convulsion):
If a child has been convulsing for 5 minutes or more, the initial dose of benzodiazepine should be administered. This can be done by giving Lorazepam at a dose of 0.1 mg/kg intravenously (IV) or intraosseously (IO) if vascular access is available. Alternatively, buccal midazolam at a dose of 0.5 mg/kg or rectal diazepam at a dose of 0.5 mg/kg can be given if vascular access is not available.

Step 2 (10 minutes after the start of Step 1):
If the convulsion continues for a further 10 minutes, a second dose of benzodiazepine should be given. It is also important to summon senior help at this point.

Step 3 (10 minutes after the start of Step 2):
At this stage, it is necessary to involve senior help to reassess the child and provide guidance on further management. The recommended approach is as follows:
– If the child is not already on phenytoin, a phenytoin infusion should be initiated. This involves administering 20 mg/kg of phenytoin intravenously over a period of 20 minutes.
– If the child is already taking phenytoin, phenobarbitone can be used as an alternative. The recommended dose is 20 mg/kg administered intravenously over 20 minutes.
– In the meantime, rectal paraldehyde can be considered at a dose of 0.8 ml/kg of the 50:50 mixture while preparing the infusion.

Step 4 (20 minutes after the start of Step 3):
If the child is still experiencing convulsions at this stage, it is crucial to have an anaesthetist present. A rapid sequence induction with thiopental is recommended for further management.

Please note that this algorithm is subject to change based on individual patient circumstances and the guidance of medical professionals.

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

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

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

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

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

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

Nasopharyngeal airway adjuncts (NPAs) are selected based on their length, which should match the distance between the nostril and the tragus of the ear.

Further Reading:

Techniques to keep the airway open:

1. Suction: Used to remove obstructing material such as blood, vomit, secretions, and food debris from the oral cavity.

2. Chin lift manoeuvres: Involves lifting the head off the floor and lifting the chin to extend the head in relation to the neck. Improves alignment of the pharyngeal, laryngeal, and oral axes.

3. Jaw thrust: Used in trauma patients with cervical spine injury concerns. Fingers are placed under the mandible and gently pushed upward.

Airway adjuncts:

1. Oropharyngeal airway (OPA): Prevents the tongue from occluding the airway. Sized according to the patient by measuring from the incisor teeth to the angle of the mandible. Inserted with the tip facing backwards and rotated 180 degrees once it touches the back of the palate or oropharynx.

2. Nasopharyngeal airway (NPA): Useful when it is difficult to open the mouth or in semi-conscious patients. Sized by length (distance between nostril and tragus of the ear) and diameter (roughly that of the patient’s little finger). Contraindicated in basal skull and midface fractures.

Laryngeal mask airway (LMA):

– Supraglottic airway device used as a first line or rescue airway.
– Easy to insert, sized according to patient’s bodyweight.
– Advantages: Easy insertion, effective ventilation, some protection from aspiration.
– Disadvantages: Risk of hypoventilation, greater gastric inflation than endotracheal tube (ETT), risk of aspiration and laryngospasm.

Note: Proper training and assessment of the patient’s condition are essential for airway management.

Public Health England (PHE) has the primary goal of promptly identifying potential disease outbreaks and epidemics. While accuracy of diagnosis is not the main focus, clinical suspicion of a notifiable infection has been sufficient since 1968.

Registered medical practitioners (RMPs) are legally obligated to inform the designated proper officer at their local council or local health protection team (HPT) about suspected cases of specific infectious diseases.

The Health Protection (Notification) Regulations 2010 outline the diseases that RMPs must report to the proper officers at local authorities. These diseases include acute encephalitis, acute infectious hepatitis, acute meningitis, acute poliomyelitis, anthrax, botulism, brucellosis, cholera, COVID-19, diphtheria, enteric fever (typhoid or paratyphoid fever), food poisoning, haemolytic uraemic syndrome (HUS), infectious bloody diarrhoea, invasive group A streptococcal disease, Legionnaires’ disease, leprosy, malaria, measles, meningococcal septicaemia, mumps, plague, rabies, rubella, severe acute respiratory syndrome (SARS), scarlet fever, smallpox, tetanus, tuberculosis, typhus, viral haemorrhagic fever (VHF), whooping cough, and yellow fever.

During cardiac arrest, Lidocaine is administered through a slow IV injection at an initial dose of 1 mg/kg when deemed suitable.

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.

Transfusion transmitted bacterial infection is a rare complication that can occur during blood transfusion. It is more commonly associated with platelet transfusion, as platelets are stored at room temperature. Additionally, previously frozen components that are thawed using a water bath and red cell components stored for several weeks are also at a higher risk for bacterial infection.

Both Gram-positive and Gram-negative bacteria have been implicated in transfusion-transmitted bacterial infection, but Gram-negative bacteria are known to cause more severe illness and have higher rates of morbidity and mortality. Among the bacterial organisms, Yersinia enterocolitica is the most commonly associated with this type of infection. This particular organism is able to multiply at low temperatures and utilizes iron as a nutrient, making it well-suited for proliferation in blood stores.

The clinical features of transfusion-transmitted bacterial infection typically manifest shortly after the transfusion begins. These features include a high fever, chills and rigors, nausea and vomiting, tachycardia, hypotension, and even circulatory collapse.

If there is suspicion of a transfusion-transmitted bacterial infection, it is crucial to immediately stop the transfusion. Blood cultures and a Gram-stain should be requested to identify the specific bacteria causing the infection. Broad-spectrum antibiotics should be initiated promptly. Furthermore, the blood pack should be returned to the blood bank urgently for culture and Gram-stain analysis.

Bullous pemphigoid (BP) is a chronic autoimmune disorder that affects the skin, causing blistering. It occurs when the immune system mistakenly attacks the basement membrane of the epidermis. This attack is carried out by immunoglobulins (IgG and sometimes IgE) and activated T lymphocytes. The autoantibodies bind to proteins and release cytokines, leading to complement activation, neutrophil recruitment, and the release of enzymes that destroy the hemidesmosomes. As a result, subepidermal blisters form.

Pemphigus, on the other hand, is a group of autoimmune disorders characterized by blistering of the skin and mucosal surfaces. The most common type, pemphigus vulgaris (PV), accounts for about 70% of cases worldwide. PV is also autoimmune in nature, with autoantibodies targeting cell surface antigens on keratinocytes (desmogleins 1 and 3). This leads to a loss of adhesion between cells and their separation.

Here is a comparison of the key differences between pemphigus vulgaris and bullous pemphigoid:

Pemphigus vulgaris:
– Age: Middle-aged people (average age 50)
– Oral involvement: Common
– Blister type: Large, flaccid, and painful
– Blister content: Fluid-filled, often haemorrhagic
– Areas commonly affected: Initially face and scalp, then spread to the chest and back
– Nikolsky sign: Usually positive
– Pruritus: Rare
– Skin biopsy: Intra-epidermal deposition of IgG between cells throughout the epidermis

Bullous pemphigoid:
– Age: Elderly people (average age 80)
– Oral involvement: Rare
– Blister type: Large and tense
– Blister content: Fluid-filled
– Areas commonly affected: Upper arms, thighs, and skin flexures
– Nikolsky sign: Usually negative
– Pruritus: Common
– Skin biopsy: A band of IgG and/or C3 at the dermo-epidermal junction

Lactulose and the oral antibiotic Rifaximin are commonly prescribed to patients with hepatic encephalopathy. The main goal of treatment for this condition is to identify and address any factors that may have triggered it. Lactulose is administered to relieve constipation, which can potentially lead to hepatic encephalopathy. On the other hand, Rifaximin is used to decrease the presence of enteric bacteria that produce ammonia.

Further Reading:

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

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

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

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

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

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

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

The current recommendations from NICE for managing warfarin in the presence of bleeding or an abnormal INR are as follows:

In cases of major active bleeding, regardless of the INR level, the first step is to stop administering warfarin. Next, 5 mg of vitamin K (phytomenadione) should be given intravenously. Additionally, dried prothrombin complex concentrate, which contains factors II, VII, IX, and X, should be administered. If dried prothrombin complex is not available, fresh frozen plasma can be given at a dose of 15 ml/kg.

If the INR is greater than 8.0 and there is minor bleeding, warfarin should be stopped. Slow injection of 1-3 mg of vitamin K can be given, and this dose can be repeated after 24 hours if the INR remains high. Warfarin can be restarted once the INR is less than 5.0.

If the INR is greater than 8.0 with no bleeding, warfarin should be stopped. Oral administration of 1-5 mg of vitamin K can be given, and this dose can be repeated after 24 hours if the INR remains high. Warfarin can be restarted once the INR is less than 5.0.

If the INR is between 5.0-8.0 with minor bleeding, warfarin should be stopped. Slow injection of 1-3 mg of vitamin K can be given, and warfarin can be restarted once the INR is less than 5.0.

If the INR is between 5.0-8.0 with no bleeding, one or two doses of warfarin should be withheld, and the subsequent maintenance dose should be reduced.

For more information, please refer to the NICE Clinical Knowledge Summary on the management of warfarin therapy and the BNF guidance on the use of phytomenadione.

Technetium 99 (Tc-99) pertechnetate scintigraphy is the preferred imaging method for evaluating frostbite. This technique is highly accurate in detecting tissue damage and provides both sensitivity and specificity.

Further Reading:

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, the basal metabolic rate decreases and cell signaling between neurons decreases, leading to reduced tissue perfusion. This can result in decreased myocardial contractility, vasoconstriction, ventilation-perfusion mismatch, and increased blood viscosity. Symptoms of hypothermia progress as the core temperature drops, starting with compensatory increases in heart rate and shivering, and eventually leading to bradyarrhythmias, prolonged PR, QRS, and QT intervals, and cardiac arrest.

In the management of hypothermic cardiac arrest, ALS should be initiated with some modifications. The pulse check during CPR should be prolonged to 1 minute due to difficulty in obtaining a pulse. Rewarming the patient is important, and mechanical ventilation may be necessary due to stiffness of the chest wall. Drug metabolism is slowed in hypothermic patients, so dosing of drugs should be adjusted or withheld. Electrolyte disturbances are common in hypothermic patients and should be corrected.

Frostbite refers to a freezing injury to human tissue and occurs when tissue temperature drops below 0ºC. It can be classified as superficial or deep, with superficial frostbite affecting the skin and subcutaneous tissues, and deep frostbite affecting bones, joints, and tendons. Frostbite can be classified from 1st to 4th degree based on the severity of the injury. Risk factors for frostbite include environmental factors such as cold weather exposure and medical factors such as peripheral vascular disease and diabetes.

Signs and symptoms of frostbite include skin changes, cold sensation or firmness to the affected area, stinging, burning, or numbness, clumsiness of the affected extremity, and excessive sweating, hyperemia, and tissue gangrene. Frostbite is diagnosed clinically and imaging may be used in some cases to assess perfusion or visualize occluded vessels. Management involves moving the patient to a warm environment, removing wet clothing, and rapidly rewarming the affected tissue. Analgesia should be given as reperfusion is painful, and blisters should be de-roofed and aloe vera applied. Compartment syndrome is a risk and should be monitored for. Severe cases may require surgical debridement of amputation.

Regular use of medications that decrease gastric acid secretion, such as proton pump inhibitors (esomeprazole, lansoprazole, omeprazole, pantoprazole, and rabeprazole) and H2 receptor antagonists like ranitidine, can increase the risk of developing clostridium difficile diarrhoea. However, it is important to note that antibiotics are the most common cause of this condition.

Further Reading:

Clostridium difficile (C.diff) is a gram positive rod commonly found in hospitals. Some strains of C.diff produce exotoxins that can cause intestinal damage, leading to pseudomembranous colitis. This infection can range from mild diarrhea to severe illness. Antibiotic-associated diarrhea is often caused by C.diff, with 20-30% of cases being attributed to this bacteria. Antibiotics such as clindamycin, cephalosporins, fluoroquinolones, and broad-spectrum penicillins are frequently associated with C.diff infection.

Clinical features of C.diff infection include diarrhea, distinctive smell, abdominal pain, raised white blood cell count, and in severe cases, toxic megacolon. In some severe cases, diarrhea may be absent due to the infection causing paralytic ileus. Diagnosis is made by detecting Clostridium difficile toxin (CDT) in the stool. There are two types of exotoxins produced by C.diff, toxin A and toxin B, which cause mucosal damage and the formation of a pseudomembrane in the colon.

Risk factors for developing C.diff infection include age over 65, antibiotic treatment, previous C.diff infection, exposure to infected individuals, proton pump inhibitor or H2 receptor antagonist use, prolonged hospitalization or residence in a nursing home, and chronic disease or immunosuppression. Complications of C.diff infection can include toxic megacolon, colon perforation, sepsis, and even death, especially in frail elderly individuals.

Management of C.diff infection involves stopping the causative antibiotic if possible, optimizing hydration with IV fluids if necessary, and assessing the severity of the infection. Treatment options vary based on severity, ranging from no antibiotics for mild cases to vancomycin or fidaxomicin for moderate cases, and hospital protocol antibiotics (such as oral vancomycin with IV metronidazole) for severe or life-threatening cases. Severe cases may require admission under gastroenterology or GI surgeons.

The recommended first-line antibiotics for eradicating H. pylori are amoxicillin in combination with either clarithromycin or metronidazole. According to NICE guidelines, for H. pylori-associated ulcers not caused by NSAID use, a 7-day eradication therapy is advised. This therapy consists of taking amoxicillin 1 g twice daily, along with either clarithromycin 500 mg twice daily or metronidazole 400 mg twice daily. Additionally, a proton pump inhibitor should be taken twice daily, with several options available. Please refer to the yellow box at the end of the notes for appropriate PPI choices.

Further Reading:

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

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

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

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

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

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

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

The clinical course of whooping cough can be divided into two stages. The first stage is called the catarrhal stage, which resembles a mild respiratory infection with symptoms like low-grade fever and a runny nose. A cough may be present, but it is usually mild compared to the second stage. The catarrhal stage typically lasts for about a week.

The second stage is known as the paroxysmal stage. During this phase, the cough becomes more severe as the catarrhal symptoms start to subside. The coughing occurs in spasms, often preceded by an inspiratory whoop sound, followed by a series of rapid coughs. Vomiting may occur, and patients may develop subconjunctival hemorrhages and petechiae. Patients generally feel well between coughing spasms, and there are usually no abnormal chest findings. This stage can last up to 3 months, with a gradual recovery over time. The later stages of this phase are sometimes referred to as the convalescent stage.

Complications of whooping cough can include secondary pneumonia, rib fractures, pneumothorax, hernias, syncopal episodes, encephalopathy, and seizures.

Public Health England (PHE) provides recommendations for testing whooping cough based on the patient’s age, time since onset of illness, and severity of symptoms. For infants under 12 months of age who are hospitalized, PCR testing is recommended. Non-hospitalized infants within two weeks of symptom onset should undergo culture testing of a nasopharyngeal swab or aspirate. Non-hospitalized infants presenting over two weeks after symptom onset should be tested for anti-pertussis toxin IgG antibody levels using serology.

For children over 12 months of age and adults, culture testing of a nasopharyngeal swab or aspirate is recommended within two weeks of symptom onset. Children aged 5 to 16 who have not received the vaccine within the last year and present over two weeks after symptom onset should undergo oral fluid testing for anti-pertussis toxin IgG antibody levels. Children under 5 or adults over

This patient has presented with an Addisonian crisis, which is a rare but potentially catastrophic condition if not diagnosed promptly. The most likely underlying rheumatological diagnosis in this case is polymyalgia rheumatica, and it is likely that the GP started the patient on prednisolone medication.

Addison’s disease occurs when the adrenal glands underproduce steroid hormones, affecting the production of glucocorticoids, mineralocorticoids, and sex steroids. The main causes of Addison’s disease include autoimmune adrenalitis (accounting for 80% of cases), bilateral adrenalectomy, Waterhouse-Friderichsen syndrome (hemorrhage into the adrenal glands), and tuberculosis.

An Addisonian crisis is most commonly triggered by the deliberate or accidental withdrawal of steroid therapy in patients with Addison’s disease. Other factors that can precipitate a crisis include infection, trauma, myocardial infarction, cerebral infarction, asthma, hypothermia, and alcohol abuse.

The clinical features of Addison’s disease include weakness, lethargy, hypotension (especially orthostatic hypotension), nausea, vomiting, weight loss, reduced axillary and pubic hair, depression, and hyperpigmentation (particularly in palmar creases, buccal mucosa, and exposed areas). In an Addisonian crisis, the main features are usually hypoglycemia and shock, characterized by tachycardia, peripheral vasoconstriction, hypotension, altered consciousness, and coma.

Biochemically, Addison’s disease is characterized by increased ACTH levels (as a compensatory response to stimulate the adrenal glands), elevated serum renin levels, hyponatremia, hyperkalemia, hypercalcemia, hypoglycemia, and metabolic acidosis. Diagnostic investigations may include the Synacthen test, plasma ACTH level, plasma renin level, and adrenocortical antibodies.

Management of Addison’s disease should be overseen by an Endocrinologist. Typically, patients require hydrocortisone, fludrocortisone, and dehydroepiandrosterone. Some patients may also need thyroxine if there is hypothalamic-pituitary disease present. Treatment is lifelong, and patients should carry a steroid card and a MedicAlert bracelet, being aware of the possibility of an Addisonian crisis.

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.

The supraspinatus tendon passes through a narrow space located between the underside of the acromion and acromioclavicular joint, as well as the head of the humerus. When the tendon becomes trapped in this space, it can cause pain and restrict movement, especially during overhead activities. This condition is known as subacromial impingement.

Impingement can occur due to various factors, such as thickening of the tendon caused by partial tears, inflammation, or degeneration. It can also be a result of the space narrowing due to osteoarthritis of the acromioclavicular joint or the presence of bone spurs. Some individuals may have a naturally downward sloping acromion, which makes them more susceptible to impingement.

Certain professions that involve a significant amount of overhead work, like plasterers, builders, and decorators, are particularly prone to developing subacromial impingement.

The main objectives in managing haemothorax are to restore the lost blood volume and relieve pressure in the pleural space. These actions are crucial for improving the patient’s oxygen levels.

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.

The diving reflex occurs when the face comes into contact with cold water, leading to apnoea, bradycardia, and peripheral vasoconstriction. This response helps decrease the workload on the heart, lower oxygen demand in the heart muscle, and ensure adequate blood flow to the brain and vital organs. The trigeminal nerve (CN V) is responsible for transmitting sensory information, while the vagus nerve (CN X) primarily controls the motor response. This reflex is more prominent in young children and is believed to contribute to their improved survival rates in prolonged submersion in cold water.

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.

To clinically test for Le Fort fractures, one can perform the following procedure: Place one hand on the forehead to stabilize it, and with the other hand, gently grip the upper teeth and anterior maxilla. Then, gently rock the hard palate back and forth.

This test is useful in suspected cases of Le Fort fractures. In a Le Fort I fracture, only the teeth and hard palate will move, while the rest of the mid face and skull remain still. In Le Fort II fractures, the teeth, hard palate, and nose will move, but the eyes and zygomatic arches will remain still. In Le Fort III fractures, the entire face will move in relation to the forehead.

Further Reading:

The Le Fort fracture classification describes three fracture patterns seen in midface fractures, all involving the maxilla and pterygoid plate disruption. As the classification grading increases, the anatomic level of the maxillary fracture ascends from inferior to superior.

Le Fort I fractures, also known as floating palate fractures, typically result from a downward blow struck above the upper dental row. Signs include swelling of the upper lip, bruising to the upper buccal sulcus, malocclusion, and mobile upper teeth.

Le Fort II fractures, also known as floating maxilla fractures, are typically the result of a forceful blow to the midaxillary area. Signs include a step deformity at the infraorbital margin, oedema over the middle third of the face, sensory disturbance of the cheek, and bilateral circumorbital ecchymosis.

Le Fort III fractures, also known as craniofacial dislocation or floating face fractures, are typically the result of high force blows to the nasal bridge or upper maxilla. These fractures involve the zygomatic arch and extend through various structures in the face. Signs include tenderness at the frontozygomatic suture, lengthening of the face, enophthalmos, and bilateral circumorbital ecchymosis.

Management of Le Fort fractures involves securing the airway as a priority, following the ABCDE approach, and identifying and managing other injuries, especially cervical spine injuries. Severe bleeding may occur and should be addressed appropriately. Surgery is almost always required, and patients should be referred to maxillofacial surgeons. Other specialties, such as neurosurgery and ophthalmology, may need to be involved depending on the specific case.

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

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

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

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

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

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

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

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

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

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

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

Chronic myeloid leukaemia (CML) is a type of blood disorder that arises from an abnormal pluripotent haemopoietic stem cell. The majority of CML cases, more than 80%, are caused by a cytogenetic abnormality called the Philadelphia chromosome. This abnormality occurs when there is a reciprocal translocation between the long arms of chromosomes 9 and 22.

CML typically develops slowly over a period of several years, known as the chronic stage. During this stage, patients usually do not experience any symptoms, and it is often discovered incidentally through routine blood tests. Around 90% of CML cases are diagnosed during this stage. In the bone marrow, less than 10% of the white cells are immature blasts.

Symptoms start to appear when the CML cells begin to expand, which is known as the accelerated stage. Approximately 10% of cases are diagnosed during this stage. Between 10 and 30% of the blood cells in the bone marrow are blasts at this point. Common clinical features during this stage include tiredness, fatigue, fever, night sweats, abdominal distension, left upper quadrant pain (splenic infarction), splenomegaly (enlarged spleen), hepatomegaly (enlarged liver), easy bruising, gout (due to rapid cell turnover), and hyperviscosity (which can lead to complications like stroke, priapism, etc.).

In some cases, a small number of patients may present with a blast crisis, also known as the blast stage. During this stage, more than 30% of the blood cells in the bone marrow are immature blast cells. Patients in this stage are generally very ill, experiencing severe constitutional symptoms such as fever, weight loss, and bone pain, as well as infections and bleeding tendencies.

Laboratory findings in CML include a significantly elevated white cell count (often greater than 100 x 109/l), a left shift with an increased number of immature leukocytes, mild to moderate normochromic, normocytic anaemia, variable platelet counts (low, normal, or elevated), presence of the Philadelphia chromosome in more than 80% of cases, and elevated levels of serum uric acid and alkaline phosphatase.

An abdominal aortic aneurysm (AAA) is a condition where the abdominal aorta becomes enlarged, either in a specific area or throughout its length, reaching 1.5 times its normal size. Most AAAs are found between the diaphragm and the point where the aorta splits into two branches. They can be classified into three types based on their location: suprarenal, pararenal, and infrarenal. Suprarenal AAAs involve the origin of one or more visceral arteries, pararenal AAAs involve the origins of the renal arteries, and infrarenal AAAs start below the renal arteries. The majority of AAAs (approximately 85%) are infrarenal. In individuals over 50 years old, a normal infrarenal aortic diameter is 1.7 cm in men and 1.5 cm in women. An infrarenal aorta with a diameter greater than 3 cm is considered to be an aneurysm. While most AAAs do not cause symptoms, an expanding aneurysm can sometimes lead to abdominal pain or pulsatile sensations. Symptomatic AAAs have a high risk of rupture. In the UK, elective surgery for AAAs is typically recommended if the aneurysm is larger than 5.5 cm in diameter or if it is larger than 4.5 cm in diameter and has increased in size by more than 0.5 cm in the past six months.

The GMC provides guidance on confidentiality that highlights the importance of assessing whether adults have the ability to give consent for the disclosure of their medical information. If the patient is capable, meaning they can comprehend relevant information, retain it, evaluate it, and communicate their decision, then their preferences should be honored, even if you believe their decision is unwise or puts them at risk of serious harm.

In the event that the patient has the capacity but you believe it would be beneficial to involve social services, you can encourage them to allow you to contact them. However, it is crucial to respect their decision if they decline. On the other hand, if the patient lacks capacity, the doctor should make a decision based on what is in their best interests, which may include raising a concern for their protection.

Ketamine should not be used in individuals who have pulmonary hypertension, as it can worsen their condition. Additionally, it is contraindicated in children under 12 months old, as they are at a higher risk of experiencing laryngospasm and airway complications. Other contraindications include a high risk of laryngospasm (such as having an active respiratory infection or asthma), unstable or abnormal airway (due to tracheal surgery or stenosis), active upper or lower respiratory tract infection, proposed procedure within the mouth or pharynx, severe psychological problems, significant cardiac disease, intracranial hypertension with cerebrospinal fluid obstruction, intraocular pathology, previous psychotic illness, uncontrolled epilepsy, hyperthyroidism or taking thyroid medication, porphyria, prior adverse reaction to ketamine, altered conscious level due to acute illness or injury, and drug or alcohol intoxication.

Further Reading:

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.

Patients who present with an anticholinergic toxidrome can be difficult to manage due to the agitation and disruptive behavior that is typically present. It is important to provide meticulous supportive care to address the behavioral effects of delirium and prevent complications such as dehydration, injury, and pulmonary aspiration. Often, one-to-one nursing is necessary.

The management approach for these patients is as follows:

1. Resuscitate using a standard ABC approach.
2. Administer sedation for behavioral control. Benzodiazepines, such as IV diazepam in 5 mg-10 mg increments, are the first-line therapy. The goal is to achieve a patient who is sleepy but easily roused. It is important to avoid over-sedating the patient as this can increase the risk of aspiration.
3. Prescribe intravenous fluids as patients are typically unable to eat and drink, and may be dehydrated upon presentation.
4. Insert a urinary catheter as urinary retention is often present and needs to be managed.
5. Consider physostigmine as the specific antidote for anticholinergic delirium in carefully selected cases. Physostigmine acts as a reversible acetylcholinesterase inhibitor, temporarily blocking the breakdown of acetylcholine. This enhances its effects at muscarinic and nicotinic receptors, thereby reversing the effects of the anticholinergic agents.

Physostigmine is indicated in the following situations:

1. Severe anticholinergic delirium that does not respond to benzodiazepine sedation.
2. Poisoning with a pure anticholinergic agent, such as atropine.

The dosage and administration of physostigmine are as follows:

1. Administer in a monitored setting with appropriate staff and resources to manage adverse effects.
2. Perform a 12-lead ECG before administration to rule out bradycardia, AV block, or broadening of the QRS.
3. Administer IV physostigmine 0.5-1 mg as a slow push over 5 minutes. Repeat every 10 minutes up to a maximum of 4 mg.
4. The clinical end-point of therapy is the resolution of delirium.
5. Delirium may reoccur in 1-4 hours as the effects of physostigmine wear off. In such cases, the dose may be cautiously repeated.

Hypothermia can lead to various abnormalities in the electrocardiogram (ECG). These abnormalities include bradyarrhythmias, the presence of a J wave (also known as an Osborn wave), and prolonged intervals such as PR, QRS, and QT. Additionally, shivering artefact and ventricular ectopics may be observed. In severe cases, hypothermia can even result in cardiac arrest, which can manifest as ventricular tachycardia (VT), ventricular fibrillation (VF), or asystole.

One distinctive feature of hypothermia on an ECG is the appearance of a small extra wave immediately following the QRS complex. This wave, known as a J wave or Osborn wave, was named after the individual who first described it. Interestingly, this wave tends to disappear as the body temperature is warmed. Despite its recognition, the exact mechanism behind the presence of the J wave in hypothermia remains unknown.

Naseptin, a topical antiseptic cream containing chlorhexidine and neomycin, has been found to be just as effective as silver nitrate cautery in treating recurrent nosebleeds in children. This means that using Naseptin can help prevent future nosebleeds in children with this condition. It is important to note that silver nitrate cautery can cause more pain and should only be used if a specific bleeding vessel can be identified.

Further Reading:

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

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

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

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

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

NICE recommends the use of octreotide for individuals in the final stages of life who are experiencing obstructive bowel disorders and have nausea or vomiting that does not improve within 24 hours of starting treatment with hyoscine butylbromide.

When managing nausea and vomiting in individuals nearing the end of life, it is important to assess the likely causes, such as certain medications, recent chemotherapy or radiotherapy, psychological factors, biochemical imbalances, raised intracranial pressure, gastrointestinal motility disorders, ileus, or bowel obstruction.

It is crucial to have discussions with the person who is dying and their loved ones about the available options for treating nausea and vomiting. Non-pharmacological methods should be considered as well.

When selecting medications to manage these symptoms, factors to consider include the likely cause and its reversibility, potential side effects (including sedation), other symptoms the person may be experiencing, the desired balance of effects when managing other symptoms, and compatibility and drug interactions with other medications the person is taking.

For individuals with obstructive bowel disorders who have nausea or vomiting, hyoscine butylbromide is recommended as the first-line pharmacological treatment. If symptoms do not improve within 24 hours of starting this treatment, octreotide should be considered.

For more information, please refer to the NICE guidance on the care of dying adults in the last days of life. https://www.nice.org.uk/guidance/ng31