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

Further Reading:

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

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

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

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

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

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

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

Thiopental sodium is a barbiturate with a very short duration of action. It is primarily used to induce anesthesia. Barbiturates are believed to primarily affect synapses by reducing the sensitivity of postsynaptic receptors to neurotransmitters and by interfering with the release of neurotransmitters from presynaptic neurons.

Thiopental sodium specifically binds to a unique site associated with a chloride ionophore at the GABAA receptor, which is responsible for the opening of chloride ion channels. This binding increases the length of time that the chloride ionophore remains open. As a result, the inhibitory effect of GABA on postsynaptic neurons in the thalamus is prolonged.

In summary, thiopental sodium acts as a short-acting barbiturate that is commonly used to induce anesthesia. It affects synapses by reducing postsynaptic receptor sensitivity and interfering with neurotransmitter release. By binding to a specific site at the GABAA receptor, thiopental sodium prolongs the inhibitory effect of GABA in the thalamus.

The sepsis 6 pathway is a time-sensitive protocol that should be started promptly and all 6 initial steps should be completed within 1 hour. It is important not to confuse the sepsis 6 pathway with the 6 hour care bundle. Time is of the essence when managing septic patients, and initiating the sepsis 6 pathway immediately has been proven to enhance survival rates in sepsis patients.

Further Reading:

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

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

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

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

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

Several studies have shown that elevating the head by 20-30 degrees is beneficial for increasing oxygen levels compared to lying flat on the back.

Further Reading:

Rapid sequence induction (RSI) is a method used to place an endotracheal tube (ETT) in the trachea while minimizing the risk of aspiration. It involves inducing loss of consciousness while applying cricoid pressure, followed by intubation without face mask ventilation. The steps of RSI can be remembered using the 7 P’s: preparation, pre-oxygenation, pre-treatment, paralysis and induction, protection and positioning, placement with proof, and post-intubation management.

Preparation involves preparing the patient, equipment, team, and anticipating any difficulties that may arise during the procedure. Pre-oxygenation is important to ensure the patient has an adequate oxygen reserve and prolongs the time before desaturation. This is typically done by breathing 100% oxygen for 3 minutes. Pre-treatment involves administering drugs to counter expected side effects of the procedure and anesthesia agents used.

Paralysis and induction involve administering a rapid-acting induction agent followed by a neuromuscular blocking agent. Commonly used induction agents include propofol, ketamine, thiopentone, and etomidate. The neuromuscular blocking agents can be depolarizing (such as suxamethonium) or non-depolarizing (such as rocuronium). Depolarizing agents bind to acetylcholine receptors and generate an action potential, while non-depolarizing agents act as competitive antagonists.

Protection and positioning involve applying cricoid pressure to prevent regurgitation of gastric contents and positioning the patient’s neck appropriately. Tube placement is confirmed by visualizing the tube passing between the vocal cords, auscultation of the chest and stomach, end-tidal CO2 measurement, and visualizing misting of the tube. Post-intubation management includes standard care such as monitoring ECG, SpO2, NIBP, capnography, and maintaining sedation and neuromuscular blockade.

Overall, RSI is a technique used to quickly and safely secure the airway in patients who may be at risk of aspiration. It involves a series of steps to ensure proper preparation, oxygenation, drug administration, and tube placement. Monitoring and post-intubation care are also important aspects of RSI.

This patient has been diagnosed with severe hyperkalemia and is showing significant ECG changes. The top priority in this situation is to protect the heart. It is recommended to administer 10 ml of 10% calcium chloride immediately over a period of 2-5 minutes. Calcium helps counteract the harmful effects of hyperkalemia on the heart by stabilizing the cardiac cell membrane and preventing unwanted depolarization.

Hyperkalemia is a commonly encountered electrolyte disorder, affecting up to 10% of hospitalized patients. It is typically caused by an increase in potassium release from cells or impaired excretion by the kidneys. The main causes of hyperkalemia include renal failure, certain medications (such as ACE inhibitors, ARBs, potassium-sparing diuretics, and NSAIDs), tissue breakdown (as seen in conditions like tumor lysis, rhabdomyolysis, and hemolysis), metabolic acidosis (often associated with renal failure or diabetic ketoacidosis), and endocrine disorders like Addison’s disease.

ECG changes that may be observed in hyperkalemia include a prolonged PR interval, peaked T-waves, widening of the QRS complex, reduced or absent P wave, sine wave pattern, AV dissociation, asystole, and bradycardia. It is important to note that the severity of ECG changes may not always correlate with the actual serum potassium levels in a patient.

The treatment approach for hyperkalemia depends on its severity. Mild hyperkalemia is defined as a potassium level of 5.5-5.9 mmol/L, moderate hyperkalemia as 6.0-6.4 mmol/L, and severe hyperkalemia as >6.5 mmol/L.

For mild hyperkalemia, the focus should be on addressing the underlying cause and preventing further increase in serum potassium levels. This may involve adjusting medications or dietary changes. If treatment is necessary, potassium exchange resins like calcium resonium can be used to remove potassium from the body.

In cases of moderate hyperkalemia, the goal is to shift potassium from the extracellular space into the cells. This can be achieved by administering insulin and glucose intravenously. Monitoring blood glucose levels is crucial in this situation. Potassium exchange resins should also be considered, and dialysis may be necessary.

Severe hyperkalemia without ECG changes requires immediate medical attention.

Based on the Lund and Browder chart, the total percentage of burns is calculated as 3 since it affects one side of both hands.

Further Reading:

Burn injuries can be classified based on their type (degree, partial thickness or full thickness), extent as a percentage of total body surface area (TBSA), and severity (minor, moderate, major/severe). Severe burns are defined as a >10% TBSA in a child and >15% TBSA in an adult.

When assessing a burn, it is important to consider airway injury, carbon monoxide poisoning, type of burn, extent of burn, special considerations, and fluid status. Special considerations may include head and neck burns, circumferential burns, thorax burns, electrical burns, hand burns, and burns to the genitalia.

Airway management is a priority in burn injuries. Inhalation of hot particles can cause damage to the respiratory epithelium and lead to airway compromise. Signs of inhalation injury include visible burns or erythema to the face, soot around the nostrils and mouth, burnt/singed nasal hairs, hoarse voice, wheeze or stridor, swollen tissues in the mouth or nostrils, and tachypnea and tachycardia. Supplemental oxygen should be provided, and endotracheal intubation may be necessary if there is airway obstruction or impending obstruction.

The initial management of a patient with burn injuries involves conserving body heat, covering burns with clean or sterile coverings, establishing IV access, providing pain relief, initiating fluid resuscitation, measuring urinary output with a catheter, maintaining nil by mouth status, closely monitoring vital signs and urine output, monitoring the airway, preparing for surgery if necessary, and administering medications.

Burns can be classified based on the depth of injury, ranging from simple erythema to full thickness burns that penetrate into subcutaneous tissue. The extent of a burn can be estimated using methods such as the rule of nines or the Lund and Browder chart, which takes into account age-specific body proportions.

Fluid management is crucial in burn injuries due to significant fluid losses. Evaporative fluid loss from burnt skin and increased permeability of blood vessels can lead to reduced intravascular volume and tissue perfusion. Fluid resuscitation should be aggressive in severe burns, while burns <15% in adults and <10% in children may not require immediate fluid resuscitation. The Parkland formula can be used to calculate the intravenous fluid requirements for someone with a significant burn injury.

Insulin is known to have several effects on the body. One of its important functions is to increase blood pH. In patients with diabetic ketoacidosis (DKA), their blood pH is low due to acidosis. Insulin helps to correct this by reducing the levels of free fatty acids in the blood, which are responsible for the production of ketone bodies that contribute to acidosis. By doing so, insulin can increase the blood pH.

Additionally, insulin plays a role in regulating glucose levels. It facilitates the movement of glucose from the blood into cells, leading to a decrease in blood glucose levels and an increase in intracellular glucose.

Furthermore, insulin affects the balance of sodium and potassium in the body. It decreases the excretion of sodium by the kidneys and drives potassium from the blood into cells, resulting in a reduction in blood potassium levels. However, it is important to monitor potassium levels closely during insulin infusions, as if they become too low (hypokalemia), the infusion may need to be stopped.

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.

Aortic stenosis is a common condition where the valve in the heart becomes narrowed due to the progressive calcification that occurs with age. This typically occurs around the age of 70. Other causes of aortic stenosis include calcification of a congenital bicuspid aortic valve and rheumatic fever.

The symptoms of aortic stenosis can vary but commonly include difficulty breathing during physical activity, fainting, dizziness, chest pain (angina), and in severe cases, sudden death. However, it is also possible for aortic stenosis to be asymptomatic, meaning that there are no noticeable symptoms.

When examining a patient with aortic stenosis, there are several signs that may be present. These include a slow-rising and low-volume pulse, a narrow pulse pressure, a sustained apex beat, a thrill (a vibrating sensation) in the area of the aorta, and an ejection click if the valve is pliable. Additionally, there is typically an ejection systolic murmur, which is a specific type of heart murmur, that can be heard loudest in the aortic area (located at the right sternal edge, 2nd intercostal space) and may radiate to the carotid arteries.

It is important to differentiate aortic stenosis from aortic sclerosis, which is a degeneration of the aortic valve but does not cause obstruction of the left ventricular outflow tract. Aortic sclerosis can be distinguished by the presence of a normal pulse character and the absence of radiation of the murmur.

Hereditary angioedema is a condition caused by a lack of C1 esterase inhibitor, a protein that is part of the complement system. It is typically inherited in an autosomal dominant manner. Symptoms usually start in childhood and continue sporadically into adulthood. Attacks can be triggered by minor surgical procedures, dental work, and stress. The main clinical signs of hereditary angioedema include swelling of the skin and mucous membranes, with the face, tongue, and extremities being the most commonly affected areas. There is often a tingling sensation before an attack, sometimes accompanied by a non-itchy rash.

Angioedema and anaphylaxis resulting from C1 esterase inhibitor deficiency do not respond to adrenaline, steroids, or antihistamines. Treatment requires the use of C1 esterase inhibitor concentrate or fresh frozen plasma, both of which contain C1 esterase inhibitor. In situations that may trigger an attack, short-term prophylaxis can be achieved by administering C1 esterase inhibitor or fresh frozen plasma infusions prior to the event. For long-term prevention, androgenic steroids like stanozolol or antifibrinolytic drugs such as tranexamic acid can be used.

The occurrence of schizophrenia is consistent across all social classes. It affects individuals from all walks of life without discrimination. The likelihood of developing schizophrenia over one’s lifetime is 1%, and this probability remains the same for both men and women. However, it is worth noting that men tend to experience the onset of symptoms at a younger age compared to women, with the average age of onset falling between 15 and 45 years.

There is a recognized genetic predisposition for schizophrenia, meaning that certain individuals may have a higher likelihood of developing the condition due to their genetic makeup. The risk of schizophrenia affecting first-degree relatives, such as siblings or parents, is approximately 10%. Furthermore, the risk of children being affected by schizophrenia increases to 40%.

When considering the impact of genetics on schizophrenia, it is interesting to note that monozygotic twins, who share identical genetic material, have a concordance rate of around 50%. This suggests that genetic factors play a significant role in the development of the condition.

Tragically, approximately 10% of individuals suffering from schizophrenia ultimately die by suicide, particularly during the early stages of the illness. This highlights the importance of providing appropriate support and intervention to individuals with schizophrenia to prevent such devastating outcomes.