Hepatitis B vaccination is included in the routine childhood immunisation schedule to provide long-term protection against hepatitis for children under 1 year of age. For these children, the vaccination consists of a primary course that includes the diphtheria with tetanus, pertussis, hepatitis B, poliomyelitis, and Haemophilus influenza type B vaccine. This primary course is given at 4 weekly intervals.

The Hepatitis B vaccine is a conjugate vaccine that contains a surface antigen of the hepatitis virus (HBsAg) and is combined with an aluminium adjuvant to enhance its effectiveness. It is produced using a recombinant DNA technique.

When administering the vaccine to adults and older children, the preferred injection site is the deltoid muscle. However, in younger children, the anterolateral thigh is the preferred site. It is not recommended to inject the vaccine in the gluteal area as it has been found to have reduced efficacy.

The standard vaccination regime for Hepatitis B consists of three primary doses. The initial dose is followed by further doses at one and six months later. A booster dose is recommended at five years if the individual is still at risk.

In cases of post-exposure prophylaxis, an accelerated vaccination regime is used. This involves administering a vaccination at the time of exposure, followed by repeat doses at one and two months later.

In high-risk situations, Hepatitis B immunoglobulin can be given up to 7 days after exposure. Ideally, it should be administered within 12 hours, but according to the BNF, it can still be effective if given within 7 days after exposure.

Functional murmurs, also referred to as physiological or flow murmurs, are frequently observed during pregnancy and other conditions associated with increased blood flow. These murmurs arise as a result of the heightened resting cardiac output and do not necessitate any additional examination.

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

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

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

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

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

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

Decompression sickness often presents with symptoms such as paraplegia, tetraplegia, or hemiplegia. In the emergency department, the most crucial intervention is providing high flow oxygen at a rate of 15 L/min through a non-rebreather mask. This should be administered to all patients, regardless of their oxygen saturations. The definitive treatment for decompression sickness involves recompression therapy in a hyperbaric oxygen chamber, which should be arranged promptly.

Further Reading:

Decompression illness (DCI) is a term that encompasses both decompression sickness (DCS) and arterial gas embolism (AGE). When diving underwater, the increasing pressure causes gases to become more soluble and reduces the size of gas bubbles. As a diver ascends, nitrogen can come out of solution and form gas bubbles, leading to decompression sickness or the bends. Boyle’s and Henry’s gas laws help explain the changes in gases during changing pressure.

Henry’s law states that the amount of gas that dissolves in a liquid is proportional to the partial pressure of the gas. Divers often use atmospheres (ATM) as a measure of pressure, with 1 ATM being the pressure at sea level. Boyle’s law states that the volume of gas is inversely proportional to the pressure. As pressure increases, volume decreases.

Decompression sickness occurs when nitrogen comes out of solution as a diver ascends. The evolved gas can physically damage tissue by stretching or tearing it as bubbles expand, or by provoking an inflammatory response. Joints and spinal nervous tissue are commonly affected. Symptoms of primary damage usually appear immediately or soon after a dive, while secondary damage may present hours or days later.

Arterial gas embolism occurs when nitrogen bubbles escape into the arterial circulation and cause distal ischemia. The consequences depend on where the embolism lodges, ranging from tissue ischemia to stroke if it lodges in the cerebral arterial circulation. Mechanisms for distal embolism include pulmonary barotrauma, right to left shunt, and pulmonary filter overload.

Clinical features of decompression illness vary, but symptoms often appear within six hours of a dive. These can include joint pain, neurological symptoms, chest pain or breathing difficulties, rash, vestibular problems, and constitutional symptoms. Factors that increase the risk of DCI include diving at greater depth, longer duration, multiple dives close together, problems with ascent, closed rebreather circuits, flying shortly after diving, exercise shortly after diving, dehydration, and alcohol use.

Diagnosis of DCI is clinical, and investigations depend on the presentation. All patients should receive high flow oxygen, and a low threshold for ordering a chest X-ray should be maintained. Hydration is important, and IV fluids may be necessary. Definitive treatment is recompression therapy in a hyperbaric oxygen chamber, which should be arranged as soon as possible. Entonox should not be given, as it will increase the pressure effect in air spaces.

This patient’s clinical presentation is consistent with a diagnosis of idiopathic pulmonary fibrosis. The typical symptoms of idiopathic pulmonary fibrosis include a dry cough, progressive breathlessness, arthralgia and muscle pain, finger clubbing (seen in 50% of cases), cyanosis, fine end-expiratory bibasal crepitations, and right heart failure and cor pulmonale in later stages.

Finger clubbing, which is prominent in this patient, can also be caused by bronchiectasis and tuberculosis. However, these conditions would not result in a raised FEV1/FVC ratio, which is a characteristic feature of a restrictive lung disorder.

In restrictive lung disease, the FEV1/FVC ratio is typically normal, around 70% predicted, while the FVC is reduced to less than 80% predicted. Both the FVC and FEV1 are generally reduced in this condition. The ratio can also be elevated if the FVC is reduced to a greater extent.

It is important to note that smoking is a risk factor for developing idiopathic pulmonary fibrosis, particularly in individuals with a history of smoking greater than 20 pack-years.

Rocuronium is a type of neuromuscular blocker that does not cause depolarization.

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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.

Tricuspid regurgitation leads to a pansystolic murmur that is most pronounced in the tricuspid area during inhalation. The primary cause of tricuspid regurgitation is right ventricular failure.

Other clinical signs that may be present in tricuspid regurgitation include a raised jugular venous pressure (JVP) and giant C-V waves. Additionally, features of increased right atrial pressure, such as ascites and dependent edema, may be observed. Pulsatile hepatomegaly and a thrill at the left sternal edge are also possible indicators. Reverse splitting of the second heart sound, due to early closure of the pulmonary valve, and a third heart sound, caused by rapid right ventricular filling, may be heard as well.

Aortic regurgitation, on the other hand, produces an early diastolic murmur that is most audible at the lower left sternal edge when the patient is sitting forward and exhaling.

In the case of mitral stenosis, a rumbling mid-diastolic murmur is best heard at the apex while the patient is in the left lateral position and exhaling, using the bell of the stethoscope.

Atrial myxomas are benign tumors that can develop in the heart. Most commonly found on the left side, they may obstruct the mitral valve, resulting in a mid-diastolic murmur similar to that of mitral stenosis.

Lastly, left anterior descending artery stenosis can cause an early diastolic murmur, also known as Dock’s murmur. This murmur is similar to that of aortic regurgitation and is best heard at the left 2nd or 3rd intercostal space.

This woman is experiencing hypoglycemia, most likely due to her treatment with glibenclamide. Hypoglycemia is defined as having a blood glucose level below 3.0 mmol/l, and it is crucial to promptly treat this condition to prevent further complications such as seizures, stroke, or heart problems.

If the patient is conscious and able to swallow, a fast-acting carbohydrate like sugar or GlucoGel can be given orally. However, since this woman is unconscious, this option is not feasible.

In cases where intravenous access is available, like in this situation, an intravenous bolus of dextrose should be administered. The recommended doses are either 75 mL of 20% dextrose or 150 mL of 10% dextrose.

When a patient is at home and intravenous access is not possible, the preferred initial treatment is glucagon. Under these circumstances, 1 mg of glucagon can be given either intramuscularly (IM) or subcutaneously (SC).

It is important to note that immediate action is necessary to address hypoglycemia and prevent any potential complications.

When it comes to managing seizures in cases of TCA overdose, benzodiazepines are considered the most effective treatment. Diazepam or lorazepam are commonly administered for this purpose. However, it’s important to note that lamotrigine and carbamazepine are typically used for preventing seizures rather than for immediate seizure control.

Further Reading:

Tricyclic antidepressant (TCA) overdose is a common occurrence in emergency departments, with drugs like amitriptyline and dosulepin being particularly dangerous. TCAs work by inhibiting the reuptake of norepinephrine and serotonin in the central nervous system. In cases of toxicity, TCAs block various receptors, including alpha-adrenergic, histaminic, muscarinic, and serotonin receptors. This can lead to symptoms such as hypotension, altered mental state, signs of anticholinergic toxicity, and serotonin receptor effects.

TCAs primarily cause cardiac toxicity by blocking sodium and potassium channels. This can result in a slowing of the action potential, prolongation of the QRS complex, and bradycardia. However, the blockade of muscarinic receptors also leads to tachycardia in TCA overdose. QT prolongation and Torsades de Pointes can occur due to potassium channel blockade. TCAs can also have a toxic effect on the myocardium, causing decreased cardiac contractility and hypotension.

Early symptoms of TCA overdose are related to their anticholinergic properties and may include dry mouth, pyrexia, dilated pupils, agitation, sinus tachycardia, blurred vision, flushed skin, tremor, and confusion. Severe poisoning can lead to arrhythmias, seizures, metabolic acidosis, and coma. ECG changes commonly seen in TCA overdose include sinus tachycardia, widening of the QRS complex, prolongation of the QT interval, and an R/S ratio >0.7 in lead aVR.

Management of TCA overdose involves ensuring a patent airway, administering activated charcoal if ingestion occurred within 1 hour and the airway is intact, and considering gastric lavage for life-threatening cases within 1 hour of ingestion. Serial ECGs and blood gas analysis are important for monitoring. Intravenous fluids and correction of hypoxia are the first-line therapies. IV sodium bicarbonate is used to treat haemodynamic instability caused by TCA overdose, and benzodiazepines are the treatment of choice for seizure control. Other treatments that may be considered include glucagon, magnesium sulfate, and intravenous lipid emulsion.

There are certain things to avoid in TCA overdose, such as anti-arrhythmics like quinidine and flecainide, as they can prolonged depolarization.

Dressings that function as flutter valves are beneficial in the initial treatment of open pneumothorax. The first step involves applying an occlusive dressing that covers the wound, with one side intentionally left open to create a flutter-valve effect. Alternatively, a chest seal device can be used. The occlusive dressing should be square or rectangular in shape, with three sides securely sealed and one side left unsealed. When the patient inhales, the dressing is drawn against the chest wall, preventing air from entering the chest cavity. However, during exhalation, air can still escape through the open side of the dressing. Another option is to use a chest seal device that includes a built-in one-way (flutter) valve. Definitive management typically involves surgical intervention to repair the defect and address any other injuries. The Royal College of Emergency Medicine (RCEM) also recommends surgery as the definitive treatment, as inserting a chest drain may disrupt tissues that could otherwise be used to cover the defect with muscle flaps.

Further Reading:

An open pneumothorax, also known as a sucking chest wound, occurs when air enters the pleural space due to an open chest wound or physical defect. This can lead to ineffective ventilation, causing hypoxia and hypercarbia. Air can enter the pleural cavity passively or be sucked in during inspiration, leading to lung collapse on that side. Sucking wounds can be heard audibly as air passes through the chest defect, and entry wounds are usually visible.

To manage an open pneumothorax, respiratory compromise can be alleviated by covering the wound with a dressing or using a chest seal device. It is important to ensure that one side of the dressing is not occluded, allowing the dressing to function as a flutter valve and prevent significant air ingress during inspiration while allowing air to escape the pleural cavity. If tension pneumothorax is suspected after applying a dressing, the dressing may need to be temporarily removed for decompression.

Intubation and intermittent positive pressure ventilation (IPPV) can be used to ventilate the patient and alleviate respiratory distress. Definitive management involves either inserting a chest drain or surgically repairing the defect. Surgical repair is typically preferred, especially for large wounds.