Conjunctivitis is the most common reason for red eyes, accounting for about 35% of all eye problems seen in general practice. It occurs when the conjunctiva, the thin layer covering the white part of the eye, becomes inflamed. Conjunctivitis can be caused by an infection or an allergic reaction.

Infective conjunctivitis is inflammation of the conjunctiva caused by a viral, bacterial, or parasitic infection. The most common type of infective conjunctivitis is viral, with adenoviruses being the main culprits. Bacterial conjunctivitis is also common and is usually caused by Streptococcus pneumoniae, Staphylococcus aureus, or Haemophilus influenzae.

The symptoms of infective conjunctivitis include sudden redness of the conjunctiva, discomfort described as a gritty or burning sensation, watering of the eyes, and discharge that may temporarily blurry vision. It can be challenging to differentiate between viral and bacterial conjunctivitis based on symptoms alone.

Here are some key features that can help distinguish between viral and bacterial conjunctivitis:

Features suggestive of viral conjunctivitis:
– Mild to moderate redness of the conjunctiva
– Presence of follicles on the inner surface of the eyelids
– Swelling of the eyelids
– Small, pinpoint bleeding under the conjunctiva
– Pseudomembranes (thin layers of tissue) may form on the inner surface of the eyelids in severe cases, often caused by adenovirus
– Less discharge (usually watery) compared to bacterial conjunctivitis
– Mild to moderate itching
– Symptoms of upper respiratory tract infection and swollen lymph nodes in front of the ears

Features suggestive of bacterial conjunctivitis:
– Purulent or mucopurulent discharge with crusting of the eyelids, which may cause them to stick together upon waking
– Mild or no itching
– Swollen lymph nodes in front of the ears, which are often present in severe bacterial conjunctivitis
– If the discharge is copious and mucopurulent, infection with Neisseria gonorrhoeae should be considered.

By considering these distinguishing features, healthcare professionals can better diagnose and manage cases of conjunctivitis.

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

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

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

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

When administering treatment to patients with hepatic impairment, it is crucial to consider that midazolam is metabolized in the liver.

Further Reading:

Procedural sedation is commonly used by emergency department (ED) doctors to minimize pain and discomfort during procedures that may be painful or distressing for patients. Effective procedural sedation requires the administration of analgesia, anxiolysis, sedation, and amnesia. This is typically achieved through the use of a combination of short-acting analgesics and sedatives.

There are different levels of sedation, ranging from minimal sedation (anxiolysis) to general anesthesia. It is important for clinicians to understand the level of sedation being used and to be able to manage any unintended deeper levels of sedation that may occur. Deeper levels of sedation are similar to general anesthesia and require the same level of care and monitoring.

Various drugs can be used for procedural sedation, including propofol, midazolam, ketamine, and fentanyl. Each of these drugs has its own mechanism of action and side effects. Propofol is commonly used for sedation, amnesia, and induction and maintenance of general anesthesia. Midazolam is a benzodiazepine that enhances the effect of GABA on the GABA A receptors. Ketamine is an NMDA receptor antagonist and is used for dissociative sedation. Fentanyl is a highly potent opioid used for analgesia and sedation.

The doses of these drugs for procedural sedation in the ED vary depending on the drug and the route of administration. It is important for clinicians to be familiar with the appropriate doses and onset and peak effect times for each drug.

Safe sedation requires certain requirements, including appropriate staffing levels, competencies of the sedating practitioner, location and facilities, and monitoring. The level of sedation being used determines the specific requirements for safe sedation.

After the procedure, patients should be monitored until they meet the criteria for safe discharge. This includes returning to their baseline level of consciousness, having vital signs within normal limits, and not experiencing compromised respiratory status. Pain and discomfort should also be addressed before discharge.

Flucloxacillin is recommended as the initial treatment for mild cellulitis, according to NICE guidelines. The recommended dosage for flucloxacillin is 500-1000 mg taken four times a day for a period of 5-7 days. However, if a patient is allergic to penicillin or if flucloxacillin is not suitable for them, alternative medications such as clarithromycin, doxycycline, or erythromycin can be used as second-line options. It is important to note that for cellulitis near the eyes, co-amoxiclav is advised as the first-line treatment, while for cellulitis in patients with lymphedema who do not require hospital admission, amoxicillin is recommended as the first-line treatment.

Further Reading:

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

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

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

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

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

Infectious mononucleosis, also known as glandular fever, is a condition that is not clearly defined in medical literature. It is characterized by symptoms such as a sore throat, swollen tonsils with a whitish coating, enlarged lymph nodes in the neck, fatigue, and an enlarged liver and spleen. This condition is caused by a specific virus.

Further Reading:

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

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

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

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

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

Grey baby syndrome is a rare but serious side effect that can occur in neonates, especially premature babies, as a result of the build-up of the antibiotic chloramphenicol. This condition is characterized by several symptoms, including ashen grey skin color, poor feeding, vomiting, cyanosis, hypotension, hypothermia, hypotonia, cardiovascular collapse, abdominal distension, and respiratory difficulties.

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

Benzodiazepines, such as diazepam, when administered late in pregnancy, can cause respiratory depression and a neonatal withdrawal syndrome. Calcium-channel blockers, if given in the first trimester, may lead to phalangeal abnormalities, while their use in the second and third trimesters can result in fetal growth retardation. Carbamazepine can cause hemorrhagic disease of the newborn and neural tube defects.

Chloramphenicol, as mentioned earlier, can cause grey baby syndrome. Corticosteroids, if given in the first trimester, may cause orofacial clefts. Danazol, if administered in the first trimester, can cause masculinization of the female fetuses genitals. Pregnant women should avoid handling crushed or broken tablets of finasteride, as it can be absorbed through the skin and affect male sex organ development.

Haloperidol, if given in the first trimester, may cause limb malformations, while its use in the third trimester increases the risk of extrapyramidal symptoms in the neonate. Heparin can lead to maternal bleeding and thrombocytopenia. Isoniazid can cause maternal liver damage and neuropathy and seizures in the neonate. Isotretinoin carries a high risk of teratogenicity, including multiple congenital malformations, spontaneous abortion, and intellectual disability.

When rescuing drowning patients, it is important to extricate them from the water in a horizontal position whenever possible. This is because the pressure of the water on the body when submerged increases the flow of blood back to the heart, which in turn increases cardiac output. However, when the patient is removed from the water, this pressure effect is lost, which can lead to a sudden drop in blood pressure and circulatory collapse due to the loss of peripheral resistance and pooling of blood in the veins. By extricating the patient in a horizontal position, we can help counteract this effect.

It is worth noting that the amount of water in the lungs after drowning is typically small, usually less than 4 milliliters per kilogram of body weight. Therefore, attempting to drain the water from the lungs is ineffective and not recommended.

In cases of fresh water drowning, pneumonia may occur due to unusual pathogens such as aeromonas spp, burkholderia pseudomallei, chromobacterium spp, pseudomonas species, and leptospirosis.

If the patient experiences bronchospasm, nebulized bronchodilators can be used as a treatment.

To prevent secondary brain injury, it is important to prevent hyperthermia. This can be achieved by maintaining the patient’s core body temperature below 36 degrees Celsius during the rewarming process.

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.

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.

Diabetic ketoacidosis (DKA) is a life-threatening condition that occurs when there is a lack of insulin, leading to an inability to process glucose. This results in high blood sugar levels and excessive thirst. As the body tries to eliminate the excess glucose through urine, dehydration becomes inevitable. Without insulin, the body starts using fat as its main energy source, which leads to the production of ketones and a buildup of acid in the blood.

The main characteristics of DKA are high blood sugar levels (above 11 mmol/l), the presence of ketones in the blood or urine, and acidosis (low bicarbonate levels and/or low venous pH). Symptoms of DKA include nausea, vomiting, excessive thirst, frequent urination, abdominal pain, signs of dehydration, a distinct smell of ketones on the breath, rapid and deep breathing, confusion or reduced consciousness, and cardiovascular symptoms like rapid heartbeat, low blood pressure, and shock.

To diagnose DKA, various tests should be performed, including blood glucose measurement, urine dipstick test (which shows high levels of glucose and ketones), blood ketone assay (more accurate than urine dipstick), complete blood count, and electrolyte levels. Arterial or venous blood gas analysis can confirm the presence of metabolic acidosis.

The management of DKA involves careful fluid administration and insulin replacement. Fluid boluses should only be given if there are signs of shock and should be administered slowly in 10 ml/kg increments. Once shock is resolved, rehydration should be done over 48 hours. The first 20 ml/kg of fluid given for resuscitation should not be subtracted from the total fluid volume calculated for the 48-hour replacement. In cases of hypotensive shock, consultation with a pediatric intensive care specialist may be necessary.

Insulin replacement should begin 1-2 hours after starting intravenous fluid therapy. A soluble insulin infusion should be used at a dosage of 0.05-0.1 units/kg/hour. The goal is to bring blood glucose levels close to normal. Regular monitoring of electrolytes and blood glucose levels is important to prevent imbalances and rapid changes in serum osmolarity. Identifying and treating the underlying cause of DKA is also crucial.

When calculating fluid requirements for children and young people with DKA, assume a 5% fluid deficit for mild-to-moderate cases (blood pH of 7.1 or above) and a 10% fluid deficit in severe DKA (indicated by a blood pH below 7.1). The total replacement fluid to be given over 48 hours is calculated as follows: Hourly rate = (deficit/48 hours) + maintenance per hour.

Lown-Ganong-Levine (LGL) syndrome is a condition that affects the electrical conducting system of the heart. It is classified as a pre-excitation syndrome, similar to the more well-known Wolff-Parkinson-White (WPW) syndrome. However, unlike WPW syndrome, LGL syndrome does not involve an accessory pathway for conduction. Instead, it is believed that there may be accessory fibers present that bypass all or part of the atrioventricular node.

When looking at an electrocardiogram (ECG) of a patient with LGL syndrome in sinus rhythm, there are several characteristic features to observe. The PR interval, which represents the time it takes for the electrical signal to travel from the atria to the ventricles, is typically shortened and measures less than 120 milliseconds. The QRS duration, which represents the time it takes for the ventricles to contract, is normal. The P wave, which represents the electrical activity of the atria, may be normal or inverted. However, what distinguishes LGL syndrome from other pre-excitation syndromes is the absence of a delta wave, which is a slurring of the initial rise in the QRS complex.

It is important to note that LGL syndrome predisposes individuals to paroxysmal supraventricular tachycardia (SVT), a rapid heart rhythm that originates above the ventricles. However, it does not increase the risk of developing atrial fibrillation or flutter, which are other types of abnormal heart rhythms.

Occlusion of branches of the anterior spinal artery leads to the development of the medial medullary syndrome. This condition is characterized by several distinct symptoms. Firstly, there is contralateral hemiplegia, which occurs due to damage to the pyramidal tracts. Additionally, there is contralateral loss of joint position sense, vibratory sense, and discriminatory touch, resulting from damage to the medial lemniscus. Lastly, there is ipsilateral deviation and paralysis of the tongue, which is caused by damage to the hypoglossal nucleus.

Anti-D is an antibody of the IgG class that targets the Rhesus D (RhD) antigen. It is specifically administered to women who are RhD negative, meaning they do not have the RhD antigen on their red blood cells. When a RhD negative woman is exposed to the blood of a RhD positive fetus, she may develop antibodies against RhD that can cross the placenta and attack the red blood cells of the fetus, leading to a condition called hemolytic disease of the newborn. Anti-D is given to bind to the fetal red blood cells in the mother’s circulation and neutralize them before an immune response is triggered.

RhD should be administered in the event of a sensitizing event, which can include childbirth, antepartum hemorrhage, miscarriage, ectopic pregnancy, intrauterine death, amniocentesis, chorionic villus sampling, or abdominal trauma. It is important to administer Anti-D as soon as possible after a sensitizing event, but it can still provide some benefit even if given outside of the recommended 72-hour window, according to the British National Formulary (BNF).

For RhD negative women, routine antenatal prophylaxis with Anti-D is recommended at 28 and 34 weeks of pregnancy, regardless of whether they have already received Anti-D earlier in the same pregnancy due to a sensitizing event.

In cases of uncomplicated miscarriage before 12 weeks of gestation, confirmed by ultrasound, or mild and painless vaginal bleeding, prophylactic Anti-D is not necessary because the risk of feto-maternal hemorrhage is extremely low. However, in cases of therapeutic termination of pregnancy, whether through surgical or medical methods, confirmed RhD negative women who are not known to be sensitized to RhD should receive 250 IU of prophylactic Anti-D immunoglobulin.

People with chronic mitral regurgitation often experience atrial fibrillation.

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

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

In patients with hypothermia, it is important to use a low reading thermometer such as an oesophageal temperature probe or vascular temperature probe. Skin surface thermometers are not effective in hypothermia cases, and rectal and tympanic thermometers may not provide accurate readings. Therefore, it is recommended to use oesophageal temperature or vascular temperature probes. However, it is worth noting that oesophageal probes may not be accurate if the patient is receiving warmed inhaled air.

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.

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.

Severe aortic stenosis (AS) is characterized by several distinct features. These include a slow rising pulse, an ejection systolic murmur that is heard loudest in the aortic area and may radiate to the carotids, and a soft or absent S2 heart sound. Additionally, patients with severe AS often have a narrow pulse pressure and may exhibit an S4 heart sound.

AS is commonly caused by hypertension, although blood pressure findings can vary. In severe cases, patients may actually be hypotensive due to impaired cardiac output. Symptoms of severe AS typically include Presyncope or syncope, exertional chest pain, and shortness of breath. These symptoms can be remembered using the acronym SAD (Syncope, Angina, Dyspnoea).

It is important to note that aortic stenosis primarily affects older individuals, as it is a result of scarring and calcium buildup in the valve. Age-related AS typically begins after the age of 60, but symptoms may not appear until patients are in their 70s or 80s.

Diastolic murmurs, on the other hand, are associated with conditions such as aortic regurgitation, pulmonary regurgitation, and mitral stenosis.

Further Reading:

Valvular heart disease refers to conditions that affect the valves of the heart. In the case of aortic valve disease, there are two main conditions: aortic regurgitation and aortic stenosis.

Aortic regurgitation is characterized by an early diastolic murmur, a collapsing pulse (also known as a water hammer pulse), and a wide pulse pressure. In severe cases, there may be a mid-diastolic Austin-Flint murmur due to partial closure of the anterior mitral valve cusps caused by the regurgitation streams. The first and second heart sounds (S1 and S2) may be soft, and S2 may even be absent. Additionally, there may be a hyperdynamic apical pulse. Causes of aortic regurgitation include rheumatic fever, infective endocarditis, connective tissue diseases like rheumatoid arthritis and systemic lupus erythematosus, and a bicuspid aortic valve. Aortic root diseases such as aortic dissection, spondyloarthropathies like ankylosing spondylitis, hypertension, syphilis, and genetic conditions like Marfan’s syndrome and Ehler-Danlos syndrome can also lead to aortic regurgitation.

Aortic stenosis, on the other hand, is characterized by a narrow pulse pressure, a slow rising pulse, and a delayed ESM (ejection systolic murmur). The second heart sound (S2) may be soft or absent, and there may be an S4 (atrial gallop) that occurs just before S1. A thrill may also be felt. The duration of the murmur is an important factor in determining the severity of aortic stenosis. Causes of aortic stenosis include degenerative calcification (most common in older patients), a bicuspid aortic valve (most common in younger patients), William’s syndrome (supravalvular aortic stenosis), post-rheumatic disease, and subvalvular conditions like hypertrophic obstructive cardiomyopathy (HOCM).

Management of aortic valve disease depends on the severity of symptoms. Asymptomatic patients are generally observed, while symptomatic patients may require valve replacement. Surgery may also be considered for asymptomatic patients with a valvular gradient greater than 40 mmHg and features such as left ventricular systolic dysfunction. Balloon valvuloplasty is limited to patients with critical aortic stenosis who are not fit for valve replacement.

Lipohaemathrosis is commonly seen in the suprapatellar pouch in individuals who have tibial plateau fractures. Notable X-ray characteristics of tibial plateau fractures include a visible fracture of the tibial plateau and the presence of lipohaemathrosis in the suprapatellar pouch.

Further Reading:

Tibial plateau fractures are a type of traumatic lower limb and joint injury that can involve the medial or lateral tibial plateau, or both. These fractures are classified using the Schatzker classification, with higher grades indicating a worse prognosis. X-ray imaging can show visible fractures of the tibial plateau and the presence of lipohaemathrosis in the suprapatellar pouch. However, X-rays often underestimate the severity of these fractures, so CT scans are typically used for a more accurate assessment.

Tibial spine fractures, on the other hand, are separate from tibial plateau fractures. They occur when the tibial spine is avulsed by the anterior cruciate ligament (ACL). This can happen due to forced knee hyperextension or a direct blow to the femur when the knee is flexed. These fractures are most common in children aged 8-14.

Tibial tuberosity avulsion fractures primarily affect adolescent boys and are often caused by jumping or landing from a jump. These fractures can be associated with Osgood-Schlatter disease. The treatment for these fractures depends on their grading. Low-grade fractures may be managed with immobilization for 4-6 weeks, while more significant avulsions are best treated with surgical fixation.

When children with diabetic ketoacidosis (DKA) show signs of shock such as low blood pressure, fast heart rate, and poor peripheral perfusion, it is important for clinicians to consider DKA as a possible cause. In these cases, the initial treatment should involve giving a fluid bolus of 10 ml/kg to help stabilize the patient.

Further Reading:

Diabetic ketoacidosis (DKA) is a serious complication of diabetes that occurs due to a lack of insulin in the body. It is most commonly seen in individuals with type 1 diabetes but can also occur in type 2 diabetes. DKA is characterized by hyperglycemia, acidosis, and ketonaemia.

The pathophysiology of DKA involves insulin deficiency, which leads to increased glucose production and decreased glucose uptake by cells. This results in hyperglycemia and osmotic diuresis, leading to dehydration. Insulin deficiency also leads to increased lipolysis and the production of ketone bodies, which are acidic. The body attempts to buffer the pH change through metabolic and respiratory compensation, resulting in metabolic acidosis.

DKA can be precipitated by factors such as infection, physiological stress, non-compliance with insulin therapy, acute medical conditions, and certain medications. The clinical features of DKA include polydipsia, polyuria, signs of dehydration, ketotic breath smell, tachypnea, confusion, headache, nausea, vomiting, lethargy, and abdominal pain.

The diagnosis of DKA is based on the presence of ketonaemia or ketonuria, blood glucose levels above 11 mmol/L or known diabetes mellitus, and a blood pH below 7.3 or bicarbonate levels below 15 mmol/L. Initial investigations include blood gas analysis, urine dipstick for glucose and ketones, blood glucose measurement, and electrolyte levels.

Management of DKA involves fluid replacement, electrolyte correction, insulin therapy, and treatment of any underlying cause. Fluid replacement is typically done with isotonic saline, and potassium may need to be added depending on the patient’s levels. Insulin therapy is initiated with an intravenous infusion, and the rate is adjusted based on blood glucose levels. Monitoring of blood glucose, ketones, bicarbonate, and electrolytes is essential, and the insulin infusion is discontinued once ketones are below 0.3 mmol/L, pH is above 7.3, and bicarbonate is above 18 mmol/L.

Complications of DKA and its treatment include gastric stasis, thromboembolism, electrolyte disturbances, cerebral edema, hypoglycemia, acute respiratory distress syndrome, and acute kidney injury. Prompt medical intervention is crucial in managing DKA to prevent potentially fatal outcomes.

It is crucial to continuously monitor the oxygen saturation, blood pressure, ECG, and temperature of critically ill patients during transfers. If the patient is intubated, monitoring of end-tidal CO2 is also necessary. The minimum standard monitoring requirements for any critically ill patient during transfers include ECG, oxygen saturation, blood pressure, and temperature. Additionally, if the patient is intubated, monitoring of end-tidal CO2 is mandatory. It is important to note that the guidance from ICS/FICM suggests that monitoring protocols for intra-hospital transfers should be similar to those for interhospital transfers.

Further Reading:

Transfer of critically ill patients in the emergency department is a common occurrence and can involve intra-hospital transfers or transfers to another hospital. However, there are several risks associated with these transfers that doctors need to be aware of and manage effectively.

Technical risks include equipment failure or inadequate equipment, unreliable power or oxygen supply, incompatible equipment, restricted positioning, and restricted monitoring equipment. These technical issues can hinder the ability to detect and treat problems with ventilation, blood pressure control, and arrhythmias during the transfer.

Non-technical risks involve limited personal and medical team during the transfer, isolation and lack of resources in the receiving hospital, and problems with communication and liaison between the origin and destination sites.

Organizational risks can be mitigated by having a dedicated consultant lead for transfers who is responsible for producing guidelines, training staff, standardizing protocols, equipment, and documentation, as well as capturing data and conducting audits.

To optimize the patient’s clinical condition before transfer, several key steps should be taken. These include ensuring a low threshold for intubation and anticipating airway and ventilation problems, securing the endotracheal tube (ETT) and verifying its position, calculating oxygen requirements and ensuring an adequate supply, monitoring for circulatory issues and inserting at least two IV accesses, providing ongoing analgesia and sedation, controlling seizures, and addressing any fractures or temperature changes.

It is also important to have the necessary equipment and personnel for the transfer. Standard monitoring equipment should include ECG, oxygen saturation, blood pressure, temperature, and capnographic monitoring for ventilated patients. Additional monitoring may be required depending on the level of care needed by the patient.

In terms of oxygen supply, it is standard practice to calculate the expected oxygen consumption during transfer and multiply it by two to ensure an additional supply in case of delays. The suggested oxygen supply for transfer can be calculated using the minute volume, fraction of inspired oxygen, and estimated transfer time.

Overall, managing the risks associated with patient transfers requires careful planning, communication, and coordination to ensure the safety and well-being of critically ill patients.

The explanation states that the increased activity of the enzyme kininogenase is caused by hormonal factors, specifically oestrogen, as well as genetic factors.

Further Reading:

Angioedema and urticaria are related conditions that involve swelling in different layers of tissue. Angioedema refers to swelling in the deeper layers of tissue, such as the lips and eyelids, while urticaria, also known as hives, refers to swelling in the epidermal skin layers, resulting in raised red areas of skin with itching. These conditions often coexist and may have a common underlying cause.

Angioedema can be classified into allergic and non-allergic types. Allergic angioedema is the most common type and is usually triggered by an allergic reaction, such as to certain medications like penicillins and NSAIDs. Non-allergic angioedema has multiple subtypes and can be caused by factors such as certain medications, including ACE inhibitors, or underlying conditions like hereditary angioedema (HAE) or acquired angioedema.

HAE is an autosomal dominant disease characterized by a deficiency of C1 esterase inhibitor. It typically presents in childhood and can be inherited or acquired as a result of certain disorders like lymphoma or systemic lupus erythematosus. Acquired angioedema may have similar clinical features to HAE but is caused by acquired deficiencies of C1 esterase inhibitor due to autoimmune or lymphoproliferative disorders.

The management of urticaria and allergic angioedema focuses on ensuring the airway remains open and addressing any identifiable triggers. In mild cases without airway compromise, patients may be advised that symptoms will resolve without treatment. Non-sedating antihistamines can be used for up to 6 weeks to relieve symptoms. Severe cases of urticaria may require systemic corticosteroids in addition to antihistamines. In moderate to severe attacks of allergic angioedema, intramuscular epinephrine may be considered.

The management of HAE involves treating the underlying deficiency of C1 esterase inhibitor. This can be done through the administration of C1 esterase inhibitor, bradykinin receptor antagonists, or fresh frozen plasma transfusion, which contains C1 inhibitor.

In summary, angioedema and urticaria are related conditions involving swelling in different layers of tissue. They can coexist and may have a common underlying cause. Management involves addressing triggers, using antihistamines, and in severe cases, systemic corticosteroids or other specific treatments for HAE.

According to the RCEM, the minimum time for cuff inflation during Bier’s block is 20 minutes, while the maximum time is 45 minutes.

Further Reading:

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

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

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

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

To perform a landmark guided femoral nerve block, first locate the inguinal ligament. This can be done by drawing an imaginary line between the anterior superior iliac spine (ASIS) and the pubic symphysis. The femoral nerve passes through the center of this line and is most superficial at the level of the inguinal crease.

Next, palpate the femoral pulse at the level of the inguinal ligament. The femoral nerve is located approximately 1-1.5 cm lateral to this point. This is where the needle entry point should be.

By following these steps and using the landmarks provided, you can accurately perform a femoral nerve block.

Activated charcoal is a commonly utilized substance for decontamination in cases of poisoning. Its main function is to attract and bind molecules of the ingested toxin onto its surface.

Activated charcoal is a chemically inert form of carbon. It is a fine black powder that has no odor or taste. This powder is created by subjecting carbonaceous matter to high heat, a process known as pyrolysis, and then concentrating it with a solution of zinc chloride. Through this process, the activated charcoal develops a complex network of pores, providing it with a large surface area of approximately 3,000 m2/g. This extensive surface area allows it to effectively hinder the absorption of the harmful toxin by up to 50%.

The typical dosage for adults is 50 grams, while children are usually given 1 gram per kilogram of body weight. Activated charcoal can be administered orally or through a nasogastric tube. It is crucial to administer it within one hour of ingestion, and if necessary, a second dose may be repeated after one hour.

Bell’s palsy is a condition characterized by a facial paralysis that affects the lower motor neurons. It can be distinguished from an upper motor neuron lesion by the inability to raise the eyebrow and the involvement of the upper facial muscles.

One distinctive feature of Bell’s palsy is the occurrence of Bell’s phenomenon, which refers to the upward and outward rolling of the eye on the affected side when attempting to close the eye and bare the teeth.

Approximately 80% of sudden onset lower motor neuron facial palsies are attributed to Bell’s palsy. It is believed that this condition is caused by swelling of the facial nerve within the petrous temporal bone, which is secondary to a latent herpesvirus, specifically HSV-1 and HZV.

Unlike some other conditions, Bell’s palsy does not lead to sensorineural deafness and tinnitus.

Treatment options for Bell’s palsy include the use of steroids and acyclovir.

Discitis is an infection that affects the space between the intervertebral discs in the spine. This condition can have serious consequences, including the formation of abscesses and sepsis. The most common cause of discitis is usually Staphylococcus aureus, but other organisms like Streptococcus viridans and Pseudomonas aeruginosa may be responsible in certain cases, especially in immunocompromised individuals and intravenous drug users. Gram-negative organisms like Escherichia coli and Mycobacterium tuberculosis can also cause discitis, particularly in cases of Pott’s disease.

There are several risk factors that increase the likelihood of developing discitis. These include having undergone spinal surgery (which occurs in about 1-2% of patients post-operatively), having an immunodeficiency, being an intravenous drug user, being under the age of eight, having diabetes mellitus, or having a malignancy.

The typical symptoms of discitis include back or neck pain (which occurs in over 90% of cases), pain that often wakes the patient from sleep, fever (present in 60-70% of cases), and neurological deficits (which can occur in up to 50% of cases). In children, a refusal to walk may also be a symptom.

When diagnosing discitis, magnetic resonance imaging (MRI) is the preferred imaging modality due to its high sensitivity and specificity. It is important to image the entire spine, as discitis often affects multiple levels. Plain radiographs are not very sensitive to the early changes of discitis and may appear normal for 2-4 weeks. Computed tomography (CT) scanning is also not very sensitive in detecting discitis.

Treatment for discitis involves hospital admission for intravenous antibiotics. Before starting the antibiotics, it is recommended to send three sets of blood cultures and a full set of blood tests, including a C-reactive protein (CRP) test, to the laboratory.

A typical antibiotic regimen for discitis would include intravenous flucloxacillin 2 g every 6 hours as the first-line treatment if there is no penicillin allergy. Intravenous vancomycin may be used if the infection was acquired in the hospital, if there is a high risk of methicillin-resistant Staphylococcus aureus (MRSA) infection, or if there is a documented penicillin allergy.

Terlipressin, a vasopressin analogue, has been found to significantly enhance survival rates in cases of acute upper gastrointestinal variceal haemorrhage when compared to a placebo. Alternatively, somatostatin and its analogue octreotide have also demonstrated similar benefits and can be used as alternatives. It is not recommended to administer proton pump inhibitors (PPIs) before endoscopy in cases of acute upper GI bleeds, but they are advised after endoscopy for non-variceal upper GI bleeds. There is no consensus on whether PPIs improve outcomes in variceal bleeding. Recombinant factor Vlla should only be considered if other blood products have failed to correct coagulopathy. Studies indicate that tranexamic acid does not reduce mortality from upper GI bleeding and may actually increase the risk of thromboembolic events.

Further Reading:

Upper gastrointestinal bleeding (UGIB) refers to the loss of blood from the gastrointestinal tract, occurring in the upper part of the digestive system. It can present as haematemesis (vomiting blood), coffee-ground emesis, bright red blood in the nasogastric tube, or melaena (black, tarry stools). UGIB can lead to significant hemodynamic compromise and is a major health burden, accounting for approximately 70,000 hospital admissions each year in the UK with a mortality rate of 10%.

The causes of UGIB vary, with peptic ulcer disease being the most common cause, followed by gastritis/erosions, esophagitis, and other less common causes such as varices, Mallory Weiss tears, and malignancy. Swift assessment, hemodynamic resuscitation, and appropriate interventions are essential for the management of UGIB.

Assessment of patients with UGIB should follow an ABCDE approach, and scoring systems such as the Glasgow-Blatchford bleeding score (GBS) and the Rockall score are recommended to risk stratify patients and determine the urgency of endoscopy. Transfusion may be necessary for patients with massive hemorrhage, and platelet transfusion, fresh frozen plasma (FFP), and prothrombin complex concentrate may be offered based on specific criteria.

Endoscopy plays a crucial role in the management of UGIB. Unstable patients with severe acute UGIB should undergo endoscopy immediately after resuscitation, while all other patients should undergo endoscopy within 24 hours of admission. Endoscopic treatment of non-variceal bleeding may involve mechanical methods of hemostasis, thermal coagulation, or the use of fibrin or thrombin with adrenaline. Proton pump inhibitors should only be used after endoscopy.

Variceal bleeding requires specific management, including the use of terlipressin and prophylactic antibiotics. Oesophageal varices can be treated with band ligation or transjugular intrahepatic portosystemic shunts (TIPS), while gastric varices may be treated with endoscopic injection of N-butyl-2-cyanoacrylate or TIPS if bleeding is not controlled.

For patients taking NSAIDs, aspirin, or clopidogrel, low-dose aspirin can be continued once hemostasis is achieved, NSAIDs should be stopped in patients presenting with UGIB

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

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

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

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

Further Reading:

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

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

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

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

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

De Quervain’s tenosynovitis is a condition characterized by inflammation and thickening of the sheath that contains the tendons of the extensor pollicis brevis and abductor pollicis longus. This leads to pain on the radial side of the wrist. It is more commonly observed in women, particularly those aged between 30 and 50 years. The condition is often associated with repetitive activities that involve pinching and grasping.

During examination, swelling and tenderness along the tendon sheath may be observed. The tendon sheath itself may also appear thickened. The most pronounced tenderness is usually felt over the tip of the radial styloid. A positive Finkelstein’s test, which involves flexing the wrist and moving it towards the ulnar side while the thumb is flexed across the palm, can help confirm the diagnosis.

Treatment for De Quervain’s tenosynovitis involves avoiding movements that can trigger symptoms and using a thumb splint to immobilize the thumb. In cases where symptoms persist, a local corticosteroid injection or surgical decompression may be considered.

This child has been clinically diagnosed with measles. The typical presentation includes a high fever accompanied by symptoms of a runny nose and sensitivity to light. Conjunctivitis, or pink eye, is often present as well. The associated rash is a widespread red rash with raised bumps. Koplik spots, which are white lesions on the inside of the cheeks, are a telltale sign of measles.

According to Public Health England, it is recommended that children with measles stay away from school, nursery, or childminders for four days starting from when the rash first appears.

For more information, you can refer to the Guidance on Infection Control in Schools and other Childcare Settings.
https://www.publichealth.hscni.net/sites/default/files/Guidance_on_infection_control_in%20schools_poster.pdf

Activated charcoal is a commonly used substance for decontamination in cases of poisoning. Its main function is to adsorb the molecules of the ingested toxin onto its surface.

Activated charcoal is a chemically inert form of carbon. It is a fine black powder that has no odor or taste. It is produced by subjecting carbonaceous matter to high temperatures, a process known as pyrolysis, and then concentrating it with a zinc chloride solution. This creates a network of pores within the charcoal, giving it a large absorptive area of approximately 3,000 m2/g. This porous structure helps prevent the absorption of the harmful toxin by up to 50%.

The usual dosage of activated charcoal is 50 grams for adults and 1 gram per kilogram of body weight for children. It can be administered orally or through a nasogastric tube. It is important to give the charcoal within one hour of ingestion, and it may be repeated after one hour if necessary.

However, there are certain situations where activated charcoal should not be used. If the patient is unconscious or in a coma, there is a risk of aspiration, so the charcoal should not be given. Similarly, if seizures are likely to occur, there is a risk of aspiration and the charcoal should be avoided. Additionally, if there is reduced gastrointestinal motility, there is a risk of obstruction, so activated charcoal should not be used in such cases.

Activated charcoal is effective in treating overdose with various drugs and toxins, including aspirin, paracetamol, barbiturates, tricyclic antidepressants, digoxin, amphetamines, morphine, cocaine, and phenothiazines. However, it is ineffective in treating overdose with substances such as iron, lithium, boric acid, cyanide, ethanol, ethylene glycol, methanol, malathion, DDT, carbamate, hydrocarbon, strong acids, or alkalis.

There are some potential adverse effects associated with activated charcoal. These include nausea and vomiting, diarrhea, constipation, bezoar formation (a mass of undigested material that can cause blockages), bowel obstruction, pulmonary aspiration (inhaling the charcoal into the lungs), and impaired absorption of oral medications or antidotes.