The typical duration of treatment for unprovoked pulmonary embolisms is 6 months, with first-line treatment now being direct oral anticoagulants. Patients are usually reviewed after 3 months, and if no cause was found, treatment is continued for a further 3 months. 3 months would be appropriate for provoked embolisms, but as there was no clear cause in this case, 6 months is more appropriate. 4 months is not a standard duration of treatment, and 12 months is not usual either, although the doctor may decide to extend treatment after review. In some cases, lifelong anticoagulation may be recommended if an underlying prothrombotic condition is found, but for this patient, 6 months is appropriate.

Management of Pulmonary Embolism: NICE Guidelines

Pulmonary embolism (PE) is a serious condition that requires prompt management. The National Institute for Health and Care Excellence (NICE) updated their guidelines on the management of venous thromboembolism (VTE) in 2020, with some key changes. One of the significant changes is the recommendation to use direct oral anticoagulants (DOACs) as the first-line treatment for most people with VTE, including those with active cancer. Another change is the increasing use of outpatient treatment for low-risk PE patients, determined by a validated risk stratification tool.

Anticoagulant therapy is the cornerstone of VTE management, and the guidelines recommend using apixaban or rivaroxaban as the first-line treatment following the diagnosis of a PE. If neither of these is suitable, LMWH followed by dabigatran or edoxaban or LMWH followed by a vitamin K antagonist (VKA) can be used. For patients with active cancer, DOACs are now recommended instead of LMWH. The length of anticoagulation is determined by whether the VTE was provoked or unprovoked, with treatment typically stopped after 3-6 months for provoked VTE and continued for up to 6 months for unprovoked VTE.

In cases of haemodynamic instability, thrombolysis is recommended as the first-line treatment for massive PE with circulatory failure. Patients who have repeat pulmonary embolisms, despite adequate anticoagulation, may be considered for inferior vena cava (IVC) filters. However, the evidence base for IVC filter use is weak.

Overall, the updated NICE guidelines provide clear recommendations for the management of PE, including the use of DOACs as first-line treatment and outpatient management for low-risk patients. The guidelines also emphasize the importance of individualized treatment based on risk stratification and balancing the risks of VTE recurrence and bleeding.

ROSIER is an acronym for a tool used to assess stroke symptoms in an acute setting.

Assessment and Investigations for Stroke

Whilst diagnosing a stroke may be straightforward in some cases, it can be challenging when symptoms are vague. The FAST screening tool, which stands for Face/Arms/Speech/Time, is a well-known tool used by the general public to identify stroke symptoms. However, medical professionals use a validated tool called the ROSIER score, recommended by the Royal College of Physicians. The ROSIER score assesses for loss of consciousness or syncope, seizure activity, and new, acute onset of asymmetric facial, arm, or leg weakness, speech disturbance, or visual field defect. A score of greater than zero indicates a likely stroke.

When investigating suspected stroke, a non-contrast CT head scan is the first line radiological investigation. The key question to answer is whether the stroke is ischaemic or haemorrhagic, as this determines the appropriate management. Ischaemic strokes may show areas of low density in the grey and white matter of the territory, while haemorrhagic strokes typically show areas of hyperdense material surrounded by low density. It is important to identify the type of stroke promptly, as thrombolysis and thrombectomy play an increasing role in acute stroke management. In rare cases, a third pathology such as a tumour may also be detected.

If a patient with diabetic ketoacidosis still has significant ketonaemia and acidosis after 24 hours, it is recommended to seek a review from a senior endocrinologist. This is important to consider other potential diagnoses and advise on further treatment. Treatment should aim to reduce blood ketones by approximately 1 mmol/hr and glucose by around 3mmol/hr. By 24 hours, the patient should be eating and drinking normally and can be switched to subcutaneous insulin.

Admission to ICU is not necessary at this point as the patient is relatively stable. The priority is to continue treatment and determine why the current treatment is not working, which can be best achieved with a senior review.

Continuing the current fluid replacement would be inappropriate as patients with DKA should see resolution of their condition after 24 hours of normal treatment. If the patient remains in DKA after this point, a senior review is needed.

Increasing insulin rate, as well as increasing the rate of IV fluids, should not be done without consulting a senior endocrinologist as it may lead to hypoglycaemia or dilutional hyponatraemia, respectively, which could worsen the patient’s condition.

Diabetic ketoacidosis (DKA) is a serious complication of type 1 diabetes mellitus, accounting for around 6% of cases. It can also occur in rare cases of extreme stress in patients with type 2 diabetes mellitus. However, mortality rates have decreased from 8% to under 1% in the past 20 years. DKA is caused by uncontrolled lipolysis, resulting in an excess of free fatty acids that are ultimately converted to ketone bodies. The most common precipitating factors of DKA are infection, missed insulin doses, and myocardial infarction. Symptoms include abdominal pain, polyuria, polydipsia, dehydration, Kussmaul respiration, and acetone-smelling breath. Diagnostic criteria include glucose levels above 13.8 mmol/l, pH below 7.30, serum bicarbonate below 18 mmol/l, anion gap above 10, and ketonaemia.

Management of DKA involves fluid replacement, insulin, and correction of electrolyte disturbance. Most patients with DKA are depleted around 5-8 litres, and isotonic saline is used initially, even if the patient is severely acidotic. Insulin is administered through an intravenous infusion, and correction of electrolyte disturbance is necessary. Long-acting insulin should be continued, while short-acting insulin should be stopped. DKA resolution is defined as pH above 7.3, blood ketones below 0.6 mmol/L, and bicarbonate above 15.0mmol/L. Complications may occur from DKA itself or the treatment, such as gastric stasis, thromboembolism, arrhythmias, acute respiratory distress syndrome, acute kidney injury, and cerebral oedema. Children and young adults are particularly vulnerable to cerebral oedema following fluid resuscitation in DKA and often need 1:1 nursing to monitor neuro-observations.

Gilbert’s syndrome is typically characterized by a rise in bilirubin levels in response to physiological stress. Therefore, it is likely that a 22-year-old male with isolated hyperbilirubinemia has Gilbert’s syndrome. Dubin-Johnson and Rotor syndrome, which both result in conjugated bilirubinemia, can be ruled out based on a normal dipstick urinalysis. Viral infections are often responsible for triggering a bilirubin increase in individuals with Gilbert’s syndrome.

Gilbert’s syndrome is a genetic condition that affects the way bilirubin is processed in the body. It is caused by a deficiency of UDP glucuronosyltransferase, which leads to unconjugated hyperbilirubinaemia. This means that bilirubin is not properly broken down and eliminated from the body, resulting in jaundice. However, jaundice may only be visible during certain situations such as intercurrent illness, exercise, or fasting. The prevalence of Gilbert’s syndrome is around 1-2% in the general population.

To diagnose Gilbert’s syndrome, doctors may look for a rise in bilirubin levels after prolonged fasting or the administration of IV nicotinic acid. However, treatment is not necessary for this condition. The exact mode of inheritance for Gilbert’s syndrome is still a matter of debate.

The middle cerebral artery is associated with contralateral hemiparesis and sensory loss, with the upper extremity being more affected than the lower. It also causes contralateral homonymous hemianopia and aphasia.

When a stroke occurs, the location of the lesion in the brain can determine the specific effects on the body. Depending on which artery is affected, different symptoms may arise. For example, a stroke in the anterior cerebral artery can lead to contralateral hemiparesis and sensory loss, with the lower extremity being more affected than the upper. On the other hand, a stroke in the middle cerebral artery can cause contralateral hemiparesis and sensory loss, with the upper extremity being more affected than the lower, as well as contralateral homonymous hemianopia and aphasia.

If the stroke occurs in the posterior cerebral artery, the individual may experience contralateral homonymous hemianopia with macular sparing and visual agnosia. In the case of Weber’s syndrome, which involves branches of the posterior cerebral artery that supply the midbrain, the person may have an ipsilateral CN III palsy and contralateral weakness of the upper and lower extremities.

Other types of strokes include those affecting the posterior inferior cerebellar artery, which can lead to ipsilateral facial pain and temperature loss and contralateral limb/torso pain and temperature loss, as well as ataxia and nystagmus. A stroke in the anterior inferior cerebellar artery can cause similar symptoms to Wallenberg’s syndrome, but with the addition of ipsilateral facial paralysis and deafness.

Finally, lacunar strokes are small, localized strokes that often occur in individuals with hypertension. They typically present with isolated hemiparesis, hemisensory loss, or hemiparesis with limb ataxia, and commonly affect the basal ganglia, thalamus, and internal capsule.

The patient’s symptoms and elevated troponin levels suggest a diagnosis of myocardial infarction. The ECG findings indicate a posterior myocardial infarction, as evidenced by tall R waves and ST depression in leads V1 and V2. This is because the infarct is located in the posterior region, causing a reversal of the lead findings. It is important to note that not all patients with myocardial infarction will present with classic symptoms. Anterior ST elevation myocardial infarction and inferior myocardial infarction are both incorrect diagnoses. A posterior myocardial infarction with tall R waves is a type of ST-elevation myocardial infarction (STEMI) and requires different management than a non-ST-elevation myocardial infarction (NSTEMI).

The following table displays the relationship between ECG changes and the corresponding coronary artery territories. Anteroseptal changes in V1-V4 indicate involvement of the left anterior descending artery. Inferior changes in II, III, and aVF suggest the right coronary artery is affected. Anterolateral changes in V1-6, I, and aVL indicate the proximal left anterior descending artery is involved. Lateral changes in I, aVL, and possibly V5-6 suggest the left circumflex artery is affected. Posterior changes in V1-3 may indicate a posterior infarction, which is confirmed by ST elevation and Q waves in posterior leads (V7-9). This type of infarction is usually caused by the left circumflex artery, but can also be caused by the right coronary artery. Reciprocal changes of STEMI are typically seen as horizontal ST depression, tall and broad R waves, upright T waves, and a dominant R wave in V2. It is important to note that a new left bundle branch block (LBBB) may indicate acute coronary syndrome.

Overall, understanding the correlation between ECG changes and coronary artery territories is crucial in diagnosing acute coronary syndrome. By identifying the specific changes in the ECG, medical professionals can determine which artery is affected and provide appropriate treatment. Additionally, recognizing the reciprocal changes of STEMI and the significance of a new LBBB can aid in making an accurate diagnosis.

Pharyngeal pouch may lead to dysphagia, aspiration pneumonia, and halitosis.

Understanding Pharyngeal Pouch or Zenker’s Diverticulum

A pharyngeal pouch, also known as Zenker’s diverticulum, is a condition where there is a posteromedial diverticulum through Killian’s dehiscence. This triangular area is found in the wall of the pharynx between the thyropharyngeus and cricopharyngeus muscles. It is more common in older patients and is five times more common in men.

The symptoms of pharyngeal pouch include dysphagia, regurgitation, aspiration, neck swelling that gurgles on palpation, and halitosis. To diagnose this condition, a barium swallow combined with dynamic video fluoroscopy is usually done.

Surgery is the most common management for pharyngeal pouch. It is important to address this condition promptly to prevent complications such as aspiration pneumonia. Understanding the symptoms and seeking medical attention early can help in the proper management of pharyngeal pouch.

WHO Recommendations for Diabetes and Intermediate Hyperglycaemia Diagnosis

The World Health Organization (WHO) has established diagnostic criteria for diabetes and intermediate hyperglycaemia. According to the 2006 recommendations, a fasting plasma glucose level of 7.0 mmol/L (126 mg/dL) or higher, or a 2-hour plasma glucose level of 11.1 mmol/L (200 mg/dL) or higher indicates diabetes. On the other hand, impaired glucose tolerance (IGT) is diagnosed when the fasting plasma glucose level is less than 7.0 mmol/L (126 mg/dL) and the 2-hour plasma glucose level is between 7.8 and 11.1 mmol/L (140 mg/dL and 200 mg/dL). Impaired fasting glucose (IFG) is diagnosed when the fasting plasma glucose level is between 6.1 and 6.9 mmol/L (110 mg/dL to 125 mg/dL) and the 2-hour plasma glucose level is less than 7.8 mmol/L (140 mg/dL), if measured.

It is important to note that if the 2-hour plasma glucose level is not measured, the status of the individual is uncertain as diabetes or IGT cannot be excluded. These recommendations serve as a guide for healthcare professionals in diagnosing and managing diabetes and intermediate hyperglycaemia.

When hypothermia leads to cardiac arrest, defibrillation is not as effective and should be limited to three shocks before the patient is warmed up to 30 degrees Celsius. Pacing is also ineffective until the patient reaches normal body temperature. Medications should be held off until the patient reaches 30 degrees Celsius, and then administered at double the usual intervals until the patient achieves normal body temperature or experiences the return of spontaneous circulation (ROSC).

Hypothermia is a condition where the core body temperature drops below normal levels, often caused by exposure to cold environments. It is most common in the winter and the elderly are particularly susceptible. Signs include shivering, cold and pale skin, slurred speech, and confusion. Treatment involves removing the patient from the cold environment, warming the body with blankets, securing the airway, and monitoring breathing. Rapid re-warming should be avoided as it can lead to peripheral vasodilation and shock. Certain actions, such as putting the person in a hot bath or giving them alcohol, should be avoided.

Lactulose and rifaximin are the recommended medications for secondary prophylaxis of hepatic encephalopathy. This condition is characterized by confusion, altered consciousness, asterixis, and triphasic slow waves on EEG, and is caused by excess absorption of ammonia and glutamine from bacterial breakdown of proteins in the gut. Lactulose promotes the excretion of ammonia and increases its metabolism by gut bacteria, while rifaximin modulates the gut flora to decrease ammonia production. Spironolactone and furosemide are not used for hepatic encephalopathy, but rather for managing ascites and edema in patients with hypoalbuminemia due to cirrhosis. Propranolol is also not used for prophylaxis against hepatic encephalopathy, but rather to lower portal pressure and prevent variceal bleeding.

Understanding Hepatic Encephalopathy

Hepatic encephalopathy is a condition that can occur in individuals with liver disease, regardless of the cause. The exact cause of this condition is not fully understood, but it is believed to be related to the absorption of excess ammonia and glutamine from the breakdown of proteins by bacteria in the gut. While hepatic encephalopathy is commonly associated with acute liver failure, it can also be seen in chronic liver disease. In fact, many patients with liver cirrhosis may experience mild cognitive impairment before the more recognizable symptoms of hepatic encephalopathy appear. It is also worth noting that transjugular intrahepatic portosystemic shunting (TIPSS) can trigger encephalopathy.

The symptoms of hepatic encephalopathy can range from irritability and confusion to incoherence and coma. The condition can be graded based on the severity of the symptoms, with Grade I being the mildest and Grade IV being the most severe. There are several factors that can precipitate hepatic encephalopathy, including infection, gastrointestinal bleeding, constipation, and certain medications.

The management of hepatic encephalopathy involves treating any underlying causes and using medications to alleviate symptoms. Lactulose is often the first-line treatment, as it promotes the excretion of ammonia and increases its metabolism by gut bacteria. Antibiotics such as rifaximin can also be used to modulate the gut flora and reduce ammonia production. In some cases, embolization of portosystemic shunts or liver transplantation may be necessary.

Overall, hepatic encephalopathy is a complex condition that requires careful management and monitoring. By understanding the causes, symptoms, and treatment options, healthcare providers can provide the best possible care for patients with this condition.