This patient presents with a classic case of temporal arteritis, also known as giant cell arteritis (GCA). Temporal arteritis is a chronic condition characterized by inflammation in the walls of medium and large arteries, specifically granulomatous inflammation. It typically affects individuals who are over 50 years old.

The clinical features of temporal arteritis include headache, tenderness in the scalp, jaw claudication, and episodes of sudden blindness or amaurosis fugax (usually occurring in one eye). Some patients may also experience systemic symptoms such as fever, fatigue, loss of appetite, weight loss, and depression.

Temporal arteritis is often associated with polymyalgia rheumatica (PMR) in about 50% of cases. PMR is characterized by stiffness, aching, and tenderness in the upper arms (bilateral) and pain in the pelvic girdle.

Visual loss is an early and significant complication of temporal arteritis, and once it occurs, it rarely improves. Therefore, early treatment with high-dose corticosteroids is crucial to prevent further visual loss and other ischemic complications. If temporal arteritis is suspected, immediate initiation of high-dose glucocorticosteroid treatment (40 – 60 mg prednisolone daily) is necessary. It is also important to arrange an urgent referral for specialist evaluation, including a same-day ophthalmology assessment for those with visual symptoms, and a temporal artery biopsy.

The normal intracranial pressure (ICP) for an adult lying down is typically between 5 and 15 mmHg.

Further Reading:

Intracranial pressure (ICP) refers to the pressure within the craniospinal compartment, which includes neural tissue, blood, and cerebrospinal fluid (CSF). Normal ICP for a supine adult is 5-15 mmHg. The body maintains ICP within a narrow range through shifts in CSF production and absorption. If ICP rises, it can lead to decreased cerebral perfusion pressure, resulting in cerebral hypoperfusion, ischemia, and potentially brain herniation.

The cranium, which houses the brain, is a closed rigid box in adults and cannot expand. It is made up of 8 bones and contains three main components: brain tissue, cerebral blood, and CSF. Brain tissue accounts for about 80% of the intracranial volume, while CSF and blood each account for about 10%. The Monro-Kellie doctrine states that the sum of intracranial volumes is constant, so an increase in one component must be offset by a decrease in the others.

There are various causes of raised ICP, including hematomas, neoplasms, brain abscesses, edema, CSF circulation disorders, venous sinus obstruction, and accelerated hypertension. Symptoms of raised ICP include headache, vomiting, pupillary changes, reduced cognition and consciousness, neurological signs, abnormal fundoscopy, cranial nerve palsy, hemiparesis, bradycardia, high blood pressure, irregular breathing, focal neurological deficits, seizures, stupor, coma, and death.

Measuring ICP typically requires invasive procedures, such as inserting a sensor through the skull. Management of raised ICP involves a multi-faceted approach, including antipyretics to maintain normothermia, seizure control, positioning the patient with a 30º head up tilt, maintaining normal blood pressure, providing analgesia, using drugs to lower ICP (such as mannitol or saline), and inducing hypocapnoeic vasoconstriction through hyperventilation. If these measures are ineffective, second-line therapies like barbiturate coma, optimised hyperventilation, controlled hypothermia, or decompressive craniectomy may be considered.

Status epilepticus is a condition characterized by continuous seizure activity lasting for 5 minutes or more without the return of consciousness, or the occurrence of recurrent seizures (2 or more) without any intervening period of neurological recovery.

In the management of a patient with status epilepticus, if the patient has already received two doses of benzodiazepine and is still experiencing seizures, the next step should be to initiate a phenytoin infusion. This involves administering a dose of 15-18 mg/kg at a rate of 50 mg/minute. Alternatively, fosphenytoin can be used as an alternative, and a phenobarbital bolus of 10-15 mg/kg at a rate of 100 mg/minute can also be considered. It is important to note that there is no indication for the administration of intravenous glucose or thiamine in this situation.

The management of status epilepticus involves several general measures. In the early stage (0-10 minutes), the airway should be secured and resuscitation should be performed. Oxygen should be administered and the patient’s cardiorespiratory function should be assessed. Intravenous access should also be established.

In the second stage (0-30 minutes), regular monitoring should be instituted. It is important to consider the possibility of non-epileptic status and commence emergency antiepileptic drug (AED) therapy. Emergency investigations should be conducted, including the administration of glucose (50 ml of 50% solution) and/or intravenous thiamine if there is any suggestion of alcohol abuse or impaired nutrition. Acidosis should be treated if it is severe.

In the third stage (0-60 minutes), the underlying cause of the status epilepticus should be identified. The anaesthetist and intensive care unit (ITU) should be alerted, and any medical complications should be identified and treated. Pressor therapy may be appropriate in certain cases.

In the fourth stage (30-90 minutes), the patient should be transferred to the intensive care unit. Intensive care and EEG monitoring should be established, and intracranial pressure monitoring may be necessary in certain cases. Initial long-term, maintenance AED therapy should also be initiated.

Emergency investigations should include blood tests for blood gases, glucose, renal and liver function, calcium and magnesium, full blood count (including platelets), blood clotting, and AED drug levels.

Patients with Parkinson’s disease (PD) typically exhibit the following clinical features:

– Hypokinesia (reduced movement)
– Bradykinesia (slow movement)
– Rest tremor (usually occurring at a rate of 4-6 cycles per second)
– Rigidity (increased muscle tone and ‘cogwheel rigidity’)

Other commonly observed clinical features include:

– Gait disturbance (characterized by a shuffling gait and loss of arm swing)
– Loss of facial expression
– Monotonous, slurred speech
– Micrographia (small, cramped handwriting)
– Increased salivation and dribbling
– Difficulty with fine movements

Initially, these signs are typically seen on one side of the body at the time of diagnosis, but they progressively worsen and may eventually affect both sides. In later stages of the disease, additional clinical features may become evident, including:

– Postural instability
– Cognitive impairment
– Orthostatic hypotension

Although PD primarily affects movement, patients often experience psychiatric issues such as depression and dementia. Autonomic disturbances and pain can also occur, leading to significant disability and reduced quality of life for the affected individual. Additionally, family members and caregivers may also be indirectly affected by the disease.

Cerebral perfusion pressure (CPP) is calculated by adding the intracranial pressure (ICP) to the diastolic blood pressure (DBP).

Further Reading:

Intracranial pressure (ICP) refers to the pressure within the craniospinal compartment, which includes neural tissue, blood, and cerebrospinal fluid (CSF). Normal ICP for a supine adult is 5-15 mmHg. The body maintains ICP within a narrow range through shifts in CSF production and absorption. If ICP rises, it can lead to decreased cerebral perfusion pressure, resulting in cerebral hypoperfusion, ischemia, and potentially brain herniation.

The cranium, which houses the brain, is a closed rigid box in adults and cannot expand. It is made up of 8 bones and contains three main components: brain tissue, cerebral blood, and CSF. Brain tissue accounts for about 80% of the intracranial volume, while CSF and blood each account for about 10%. The Monro-Kellie doctrine states that the sum of intracranial volumes is constant, so an increase in one component must be offset by a decrease in the others.

There are various causes of raised ICP, including hematomas, neoplasms, brain abscesses, edema, CSF circulation disorders, venous sinus obstruction, and accelerated hypertension. Symptoms of raised ICP include headache, vomiting, pupillary changes, reduced cognition and consciousness, neurological signs, abnormal fundoscopy, cranial nerve palsy, hemiparesis, bradycardia, high blood pressure, irregular breathing, focal neurological deficits, seizures, stupor, coma, and death.

Measuring ICP typically requires invasive procedures, such as inserting a sensor through the skull. Management of raised ICP involves a multi-faceted approach, including antipyretics to maintain normothermia, seizure control, positioning the patient with a 30º head up tilt, maintaining normal blood pressure, providing analgesia, using drugs to lower ICP (such as mannitol or saline), and inducing hypocapnoeic vasoconstriction through hyperventilation. If these measures are ineffective, second-line therapies like barbiturate coma, optimised hyperventilation, controlled hypothermia, or decompressive craniectomy may be considered.

This patient has developed Wernicke’s encephalopathy, a condition that is associated with alcohol abuse and other causes of thiamine deficiency. It is important to note that the infusion of glucose-containing intravenous fluids without thiamine in a patient with chronic thiamine deficiency can trigger Wernicke’s encephalopathy. In this particular case, it seems that this is what has occurred.

Wernicke’s encephalopathy is typically characterized by a triad of symptoms, which include acute confusion, ophthalmoplegia, and ataxia. Additionally, other possible features of this condition may include papilloedema, hearing loss, apathy, dysphagia, memory impairment, and hypothermia. It is also common for peripheral neuropathy, primarily affecting the legs, to occur in the majority of cases.

This condition is characterized by the presence of acute capillary haemorrhages, astrocytosis, and neuronal death in the upper brainstem and diencephalon. These abnormalities can be visualized through MRI scanning, although CT scanning is not very useful for diagnosis.

If left untreated, most patients with Wernicke’s encephalopathy will go on to develop a Korsakoff psychosis. This condition is characterized by retrograde amnesia, an inability to form new memories, disordered time perception, and confabulation.

Patients who are suspected to have Wernicke’s encephalopathy should be promptly treated with parenteral thiamine (such as Pabrinex) for a minimum of 5 days. Following the parenteral therapy, oral thiamine should be administered.

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

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

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

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

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

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

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

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

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

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

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

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

This patient presents with a classic case of temporal arteritis, also known as giant cell arteritis (GCA). Temporal arteritis is a chronic condition characterized by inflammation in the walls of medium and large arteries, specifically granulomatous inflammation. It typically affects individuals who are over 50 years old.

The clinical features of temporal arteritis include headache, tenderness in the scalp, jaw claudication, and episodes of sudden blindness or amaurosis fugax (usually occurring in one eye). Some patients may also experience systemic symptoms such as fever, fatigue, loss of appetite, weight loss, and depression.

Temporal arteritis is often associated with polymyalgia rheumatica (PMR) in about 50% of cases. PMR is characterized by stiffness, aching, and tenderness in the upper arms (bilateral) and pain in the pelvic girdle.

Visual loss is an early and significant complication of temporal arteritis, and once it occurs, it rarely improves. Therefore, early treatment with high-dose corticosteroids is crucial to prevent further visual loss and other ischemic complications. If temporal arteritis is suspected, immediate initiation of high-dose glucocorticosteroid treatment (40 – 60 mg prednisolone daily) is necessary. It is also important to arrange an urgent referral for specialist evaluation, including a same-day ophthalmology assessment for those with visual symptoms, and a temporal artery biopsy.

Due to the potentially life-threatening nature of the disease, it is crucial to initiate treatment without waiting for laboratory confirmation. Immediate administration of antibiotics is necessary.

In a hospital setting, the preferred agents for treatment are IV ceftriaxone (2 g for adults; 80 mg/kg for children) or IV cefotaxime (2 g for adults; 80 mg/kg for children). In the prehospital setting, IM benzylpenicillin can be given as an alternative. If there is a history of anaphylaxis to cephalosporins, chloramphenicol is a suitable alternative.

It is important to prioritize prompt treatment due to the severity of the disease. The recommended antibiotics should be administered as soon as possible to ensure the best possible outcome for the patient.

Klumpke’s palsy, also known as Dejerine-Klumpke palsy, is a condition where the arm becomes paralyzed due to an injury to the lower roots of the brachial plexus. The most commonly affected root is C8, but T1 can also be involved. The main cause of Klumpke’s palsy is when the arm is pulled forcefully in an outward position during a difficult childbirth. It can also occur in adults with apical lung carcinoma (Pancoast’s syndrome).

Clinically, Klumpke’s palsy is characterized by a deformity known as ‘claw hand’, which is caused by the paralysis of the intrinsic hand muscles. There is also a loss of sensation along the ulnar side of the forearm and hand. In some cases where T1 is affected, a condition called Horner’s syndrome may also be present.

Klumpke’s palsy can be distinguished from Erb’s palsy, which affects the upper roots of the brachial plexus (C5 and sometimes C6). In Erb’s palsy, the arm hangs by the side with the elbow extended and the forearm turned inward (known as the ‘waiter’s tip sign’). Additionally, there is a loss of shoulder abduction, external rotation, and elbow flexion.

The symptoms and signs of strokes can vary depending on which blood vessel is affected. Here is a summary of the main symptoms based on the territory affected:

Anterior cerebral artery: This can cause weakness on the opposite side of the body, with the leg and shoulder being more affected than the arm, hand, and face. There may also be minimal loss of sensation on the opposite side of the body. Other symptoms can include difficulty speaking (dysarthria), language problems (aphasia), apraxia (difficulty with limb movements), urinary incontinence, and changes in behavior and personality.

Middle cerebral artery: This can lead to weakness on the opposite side of the body, with the face and arm being more affected than the leg. There may also be a loss of sensation on the opposite side of the body. Depending on the dominant hemisphere of the brain, there may be difficulties with expressive or receptive language (dysphasia). In the non-dominant hemisphere, there may be neglect of the opposite side of the body.

Posterior cerebral artery: This can cause a loss of vision on the opposite side of both eyes (homonymous hemianopia). There may also be defects in a specific quadrant of the visual field. In some cases, there may be a syndrome affecting the thalamus on the opposite side of the body.

It’s important to note that these are just general summaries and individual cases may vary. If you suspect a stroke, it’s crucial to seek immediate medical attention.

Alzheimer’s disease, the leading cause of dementia, is characterized by the presence of beta-amyloid plaques and neurofibrillary tangles in the brain. These plaques are formed due to an excessive buildup of amyloid, which can be caused by either overproduction or impaired clearance of beta-amyloid. The accumulation of amyloid plaques leads to inflammation in the surrounding brain tissue, resulting in damage to neurons. Additionally, the abnormal phosphorylation of tau protein causes it to aggregate into neurofibrillary tangles within neurons. It is important to note that Lewy bodies, composed mainly of alpha-synuclein, are associated with diseases like Parkinson’s disease and dementia with Lewy bodies. Autoimmune diseases often involve the activation of autoreactive T-cells.

Further Reading:

Dementia is a progressive and irreversible clinical syndrome characterized by cognitive and behavioral symptoms. These symptoms include memory loss, impaired reasoning and communication, personality changes, and reduced ability to carry out daily activities. The decline in cognition affects multiple domains of intellectual functioning and is not solely due to normal aging.

To diagnose dementia, a person must have impairment in at least two cognitive domains that significantly impact their daily activities. This impairment cannot be explained by delirium or other major psychiatric disorders. Early-onset dementia refers to dementia that develops before the age of 65.

The most common cause of dementia is Alzheimer’s disease, accounting for 50-75% of cases. Other causes include vascular dementia, dementia with Lewy bodies, and frontotemporal dementia. Less common causes include Parkinson’s disease dementia, Huntington’s disease, prion disease, and metabolic and endocrine disorders.

There are several risk factors for dementia, including age, mild cognitive impairment, genetic predisposition, excess alcohol intake, head injury, depression, learning difficulties, diabetes, obesity, hypertension, smoking, Parkinson’s disease, low social engagement, low physical activity, low educational attainment, hearing impairment, and air pollution.

Assessment of dementia involves taking a history from the patient and ideally a family member or close friend. The person’s current level of cognition and functional capabilities should be compared to their baseline level. Physical examination, blood tests, and cognitive assessment tools can also aid in the diagnosis.

Differential diagnosis for dementia includes normal age-related memory changes, mild cognitive impairment, depression, delirium, vitamin deficiencies, hypothyroidism, adverse drug effects, normal pressure hydrocephalus, and sensory deficits.

Management of dementia involves a multi-disciplinary approach that includes non-pharmacological and pharmacological measures. Non-pharmacological interventions may include driving assessment, modifiable risk factor management, and non-pharmacological therapies to promote cognition and independence. Drug treatments for dementia should be initiated by specialists and may include acetylcholinesterase inhibitors, memantine, and antipsychotics in certain cases.

In summary, dementia is a progressive and irreversible syndrome characterized by cognitive and behavioral symptoms. It has various causes and risk factors, and its management involves a multi-disciplinary approach.

In an adult patient, a Glasgow Coma Scale (GCS) score of 13 or lower necessitates an urgent CT scan of the head. The GCS is a neurological assessment tool that evaluates a patient’s level of consciousness and neurological functioning. It consists of three components: eye opening, verbal response, and motor response. Each component is assigned a score ranging from 1 to 4 or 5, with a higher score indicating a higher level of consciousness.

A GCS score of 15 is considered normal and indicates that the patient is fully conscious. A score of 14 or 13 suggests a mild impairment in consciousness, but it may not necessarily require an urgent CT scan unless there are other concerning symptoms or signs. However, a GCS score of 11 or 9 indicates a moderate to severe impairment in consciousness, which raises concerns for a potentially serious head injury. In these cases, an urgent CT scan of the head is necessary to assess for any structural brain abnormalities or bleeding that may require immediate intervention.

Therefore, in this case, the minimum GCS score that necessitates an urgent CT scan of the head is 13.

Further Reading:

Indications for CT Scanning in Head Injuries (Adults):
– CT head scan should be performed within 1 hour if any of the following features are present:
– GCS < 13 on initial assessment in the ED
– GCS < 15 at 2 hours after the injury on assessment in the ED
– Suspected open or depressed skull fracture
– Any sign of basal skull fracture (haemotympanum, ‘panda’ eyes, cerebrospinal fluid leakage from the ear or nose, Battle’s sign)
– Post-traumatic seizure
– New focal neurological deficit
– > 1 episode of vomiting

Indications for CT Scanning in Head Injuries (Children):
– CT head scan should be performed within 1 hour if any of the features in List 1 are present:
– Suspicion of non-accidental injury
– Post-traumatic seizure but no history of epilepsy
– GCS < 14 on initial assessment in the ED for children more than 1 year of age
– Paediatric GCS < 15 on initial assessment in the ED for children under 1 year of age
– At 2 hours after the injury, GCS < 15
– Suspected open or depressed skull fracture or tense fontanelle
– Any sign of basal skull fracture (haemotympanum, ‘panda’ eyes, cerebrospinal fluid leakage from the ear or nose, Battle’s sign)
– New focal neurological deficit
– For children under 1 year, presence of bruise, swelling or laceration of more than 5 cm on the head

– CT head scan should be performed within 1 hour if none of the above features are present but two or more of the features in List 2 are present:
– Loss of consciousness lasting more than 5 minutes (witnessed)
– Abnormal drowsiness
– Three or more discrete episodes of vomiting
– Dangerous mechanism of injury (high-speed road traffic accident, fall from a height of

Patients who experience a seizure(s) should be informed about their ability to drive. There are two important instructions to follow in this regard. Firstly, they must refrain from driving for a period of 6 months. Secondly, they must notify the appropriate authority, such as the DVLA or DVA in Northern Ireland. In the case of a single seizure, driving should be suspended for 6 months from the date of the seizure. However, if an underlying cause that increases the risk of seizures is identified, driving should be halted for 12 months. In the case of multiple seizures or epilepsy, driving should be ceased for 12 months from the most recent seizure.

Further Reading:

Blackouts are a common occurrence in the emergency department and can have serious consequences if they happen while a person is driving. It is crucial for doctors in the ED to be familiar with the guidelines set by the DVLA (Driver and Vehicle Licensing Agency) regarding driving restrictions for patients who have experienced a blackout.

The DVLA has specific rules for different types of conditions that may cause syncope (loss of consciousness). For group 1 license holders (car/motorcycle use), if a person has had a first unprovoked isolated seizure, they must refrain from driving for 6 months or 12 months if there is an underlying causative factor that may increase the risk. They must also notify the DVLA. For group 2 license holders (bus and heavy goods vehicles), the restrictions are more stringent, with a requirement of 12 months off driving for a first unprovoked isolated seizure and 5 years off driving if there is an underlying causative factor.

For epilepsy or multiple seizures, both group 1 and group 2 license holders must remain seizure-free for 12 months before their license can be considered. They must also notify the DVLA. In the case of a stroke or isolated transient ischemic attack (TIA), group 1 license holders need to refrain from driving for 1 month, while group 2 license holders must wait for 12 months before being re-licensed subject to medical evaluation. Multiple TIAs require 3 months off driving for both groups.

Isolated vasovagal syncope requires no driving restriction for group 1 license holders, but group 2 license holders must refrain from driving for 3 months. Both groups must notify the DVLA. If syncope is caused by a reversible and treated condition, group 1 license holders need 4 weeks off driving, while group 2 license holders require 3 months. In the case of an isolated syncopal episode with an unknown cause, group 1 license holders must refrain from driving for 6 months, while group 2 license holders will have their license refused or revoked for 12 months.

For patients who continue to drive against medical advice, the GMC (General Medical Council) has provided guidance on how doctors should manage the situation. Doctors should explain to the patient why they are not allowed to drive and inform them of their legal duty to notify the DVLA or DVA (Driver and Vehicle Agency in Northern Ireland). Doctors should also record the advice given to the patient in their medical record

When the paramedian branches of the basilar artery are blocked, it leads to a condition known as medial pontine syndrome. This syndrome is characterized by several symptoms. Firstly, there is contralateral hemiplegia, which refers to paralysis on the opposite side of the body due to damage to the pyramidal tracts. Additionally, there is contralateral loss of joint position sense, vibratory sense, and discriminatory touch, which occurs as a result of damage to the medial lemniscus. Lastly, individuals with medial pontine syndrome may experience double vision caused by paralysis of the lateral rectus muscle, which is due to damage to the sixth cranial nerve.

The patient’s history aligns with a generalized tonic-clonic seizure. The observer of the incident provided a detailed description, which is crucial in diagnosing epilepsy.

Diagnosing epilepsy can sometimes rely solely on the patient’s history. It is common to ask the patient to maintain a seizure diary to identify patterns and potential triggers. Additionally, EEG tests, along with an MRI scan or CT scan of the brain, can provide further insight into the type and possible cause of the seizures.

On average, the intracranial volume in adults is around 1400ml.

Intracranial pressure (ICP) refers to the pressure within the craniospinal compartment, which includes neural tissue, blood, and cerebrospinal fluid (CSF). Normal ICP for a supine adult is 5-15 mmHg. The body maintains ICP within a narrow range through shifts in CSF production and absorption. If ICP rises, it can lead to decreased cerebral perfusion pressure, resulting in cerebral hypoperfusion, ischemia, and potentially brain herniation.

The cranium, which houses the brain, is a closed rigid box in adults and cannot expand. It is made up of 8 bones and contains three main components: brain tissue, cerebral blood, and CSF. Brain tissue accounts for about 80% of the intracranial volume, while CSF and blood each account for about 10%. The Monro-Kellie doctrine states that the sum of intracranial volumes is constant, so an increase in one component must be offset by a decrease in the others.

There are various causes of raised ICP, including hematomas, neoplasms, brain abscesses, edema, CSF circulation disorders, venous sinus obstruction, and accelerated hypertension. Symptoms of raised ICP include headache, vomiting, pupillary changes, reduced cognition and consciousness, neurological signs, abnormal fundoscopy, cranial nerve palsy, hemiparesis, bradycardia, high blood pressure, irregular breathing, focal neurological deficits, seizures, stupor, coma, and death.

Measuring ICP typically requires invasive procedures, such as inserting a sensor through the skull. Management of raised ICP involves a multi-faceted approach, including antipyretics to maintain normothermia, seizure control, positioning the patient with a 30º head up tilt, maintaining normal blood pressure, providing analgesia, using drugs to lower ICP (such as mannitol or saline), and inducing hypocapnoeic vasoconstriction through hyperventilation. If these measures are ineffective, second-line therapies like barbiturate coma, optimised hyperventilation, controlled hypothermia, or decompressive craniectomy may be considered.

Dementia with Lewy bodies (DLB) is characterized by several key features, including spontaneous fluctuations in cognitive abilities, visual hallucinations, and Parkinsonism. Visual hallucinations are particularly prevalent in DLB and Parkinson’s disease dementia, which are considered to be part of the same spectrum. While visual hallucinations can occur in other forms of dementia, they are less frequently observed.

Further Reading:

Dementia is a progressive and irreversible clinical syndrome characterized by cognitive and behavioral symptoms. These symptoms include memory loss, impaired reasoning and communication, personality changes, and reduced ability to carry out daily activities. The decline in cognition affects multiple domains of intellectual functioning and is not solely due to normal aging.

To diagnose dementia, a person must have impairment in at least two cognitive domains that significantly impact their daily activities. This impairment cannot be explained by delirium or other major psychiatric disorders. Early-onset dementia refers to dementia that develops before the age of 65.

The most common cause of dementia is Alzheimer’s disease, accounting for 50-75% of cases. Other causes include vascular dementia, dementia with Lewy bodies, and frontotemporal dementia. Less common causes include Parkinson’s disease dementia, Huntington’s disease, prion disease, and metabolic and endocrine disorders.

There are several risk factors for dementia, including age, mild cognitive impairment, genetic predisposition, excess alcohol intake, head injury, depression, learning difficulties, diabetes, obesity, hypertension, smoking, Parkinson’s disease, low social engagement, low physical activity, low educational attainment, hearing impairment, and air pollution.

Assessment of dementia involves taking a history from the patient and ideally a family member or close friend. The person’s current level of cognition and functional capabilities should be compared to their baseline level. Physical examination, blood tests, and cognitive assessment tools can also aid in the diagnosis.

Differential diagnosis for dementia includes normal age-related memory changes, mild cognitive impairment, depression, delirium, vitamin deficiencies, hypothyroidism, adverse drug effects, normal pressure hydrocephalus, and sensory deficits.

Management of dementia involves a multi-disciplinary approach that includes non-pharmacological and pharmacological measures. Non-pharmacological interventions may include driving assessment, modifiable risk factor management, and non-pharmacological therapies to promote cognition and independence. Drug treatments for dementia should be initiated by specialists and may include acetylcholinesterase inhibitors, memantine, and antipsychotics in certain cases.

In summary, dementia is a progressive and irreversible syndrome characterized by cognitive and behavioral symptoms. It has various causes and risk factors, and its management involves a multi-disciplinary approach.

Klumpke’s palsy, also known as Dejerine-Klumpke palsy, is a condition where the arm becomes paralyzed due to an injury to the lower roots of the brachial plexus. The most commonly affected root is C8, but T1 can also be involved. The main cause of Klumpke’s palsy is when the arm is pulled forcefully in an outward position during a difficult childbirth. It can also occur in adults with apical lung carcinoma (Pancoast’s syndrome).

Clinically, Klumpke’s palsy is characterized by a deformity known as ‘claw hand’, which is caused by the paralysis of the intrinsic hand muscles. There is also a loss of sensation along the ulnar side of the forearm and hand. In some cases where T1 is affected, a condition called Horner’s syndrome may also be present.

Klumpke’s palsy can be distinguished from Erb’s palsy, which affects the upper roots of the brachial plexus (C5 and sometimes C6). In Erb’s palsy, the arm hangs by the side with the elbow extended and the forearm turned inward (known as the ‘waiter’s tip sign’). Additionally, there is a loss of shoulder abduction, external rotation, and elbow flexion.

Subdural hematoma (SDH) occurs when the bridging veins in the cortex of the brain tear and cause bleeding in the space between the brain and the outermost protective layer. This is different from extradural hematoma (EDH), which is usually caused by a rupture in the middle meningeal artery.

Further Reading:

A subdural hematoma (SDH) is a condition where there is a collection of blood between the dura mater and the arachnoid mater of the brain. It occurs when the cortical bridging veins tear and bleed into the subdural space. Risk factors for SDH include head trauma, cerebral atrophy, advancing age, alcohol misuse, and certain medications or bleeding disorders. SDH can be classified as acute, subacute, or chronic depending on its age or speed of onset. Acute SDH is typically the result of head trauma and can progress to become chronic if left untreated.

The clinical presentation of SDH can vary depending on the nature of the condition. In acute SDH, patients may initially feel well after a head injury but develop more serious neurological symptoms later on. Chronic SDH may be detected after a CT scan is ordered to investigate confusion or cognitive decline. Symptoms of SDH can include increasing confusion, progressive decline in neurological function, seizures, headache, loss of consciousness, and even death.

Management of SDH involves an ABCDE approach, seizure management, confirming the diagnosis with CT or MRI, checking clotting and correcting coagulation abnormalities, managing raised intracranial pressure, and seeking neurosurgical opinion. Some SDHs may be managed conservatively if they are small, chronic, the patient is not a good surgical candidate, and there are no neurological symptoms. Neurosurgical intervention typically involves a burr hole craniotomy to decompress the hematoma. In severe cases with high intracranial pressure and significant brain swelling, a craniectomy may be performed, where a larger section of the skull is removed and replaced in a separate cranioplasty procedure.

CT imaging can help differentiate between subdural hematoma and other conditions like extradural hematoma. SDH appears as a crescent-shaped lesion on CT scans.

Extradural hematoma is most frequently caused by injury to the middle meningeal artery. This artery is particularly susceptible to damage as it passes behind the pterion.

Further Reading:

Extradural haematoma (EDH) is a collection of blood that forms between the inner surface of the skull and the outer layer of the dura, the dura mater. It is typically caused by head trauma and is often associated with a skull fracture, with the pterion being the most common site of injury. The middle meningeal artery is the most common source of bleeding in EDH.

Clinical features of EDH include a history of head injury with transient loss of consciousness, followed by a lucid interval and gradual loss of consciousness. Other symptoms may include severe headache, sixth cranial nerve palsies, nausea and vomiting, seizures, signs of raised intracranial pressure, and focal neurological deficits.

Imaging of EDH typically shows a biconvex shape and may cause mass effect with brain herniation. It can be differentiated from subdural haematoma by its appearance on imaging.

Management of EDH involves prompt referral to neurosurgery for evacuation of the haematoma. In some cases with a small EDH, conservative management may be considered. With prompt evacuation, the prognosis for EDH is generally good.

The initial indication of progressive compression on the oculomotor nerve is the dilation of the pupil. In cases where the oculomotor nerve is being compressed, the outer parasympathetic fibers are typically affected before the inner motor fibers. These parasympathetic fibers are responsible for stimulating the constriction of the pupil. When they are disrupted, the sympathetic stimulation of the pupil is unopposed, leading to the dilation of the pupil (known as mydriasis or blown pupil). This symptom is usually observed before the drooping of the eyelid (lid ptosis) and the downward and outward positioning of the eye.

Further Reading:

Intracranial pressure (ICP) refers to the pressure within the craniospinal compartment, which includes neural tissue, blood, and cerebrospinal fluid (CSF). Normal ICP for a supine adult is 5-15 mmHg. The body maintains ICP within a narrow range through shifts in CSF production and absorption. If ICP rises, it can lead to decreased cerebral perfusion pressure, resulting in cerebral hypoperfusion, ischemia, and potentially brain herniation.

The cranium, which houses the brain, is a closed rigid box in adults and cannot expand. It is made up of 8 bones and contains three main components: brain tissue, cerebral blood, and CSF. Brain tissue accounts for about 80% of the intracranial volume, while CSF and blood each account for about 10%. The Monro-Kellie doctrine states that the sum of intracranial volumes is constant, so an increase in one component must be offset by a decrease in the others.

There are various causes of raised ICP, including hematomas, neoplasms, brain abscesses, edema, CSF circulation disorders, venous sinus obstruction, and accelerated hypertension. Symptoms of raised ICP include headache, vomiting, pupillary changes, reduced cognition and consciousness, neurological signs, abnormal fundoscopy, cranial nerve palsy, hemiparesis, bradycardia, high blood pressure, irregular breathing, focal neurological deficits, seizures, stupor, coma, and death.

Measuring ICP typically requires invasive procedures, such as inserting a sensor through the skull. Management of raised ICP involves a multi-faceted approach, including antipyretics to maintain normothermia, seizure control, positioning the patient with a 30º head up tilt, maintaining normal blood pressure, providing analgesia, using drugs to lower ICP (such as mannitol or saline), and inducing hypocapnoeic vasoconstriction through hyperventilation. If these measures are ineffective, second-line therapies like barbiturate coma, optimised hyperventilation, controlled hypothermia, or decompressive craniectomy may be considered.

Radial nerve injuries often occur in conjunction with fractures of the humerus. The most common cause of a radial nerve palsy is external compression or trauma to the radial nerve as it passes through the spiral groove in the middle of the humerus.

There are several factors that can lead to damage of the radial nerve in the spiral groove. These include trauma, such as a fracture in the middle of the humerus, compression known as Saturday night palsy, and iatrogenic causes like injections.

When the radial nerve is injured within the spiral groove, it results in weakness of the wrist and metacarpophalangeal joints. However, elbow extension is not affected because the branches to the triceps and anconeus muscles originate before the spiral groove. The interphalangeal joints remain unaffected as well, as they are supplied by the median and ulnar nerves. Sensory loss will be experienced over the dorsal aspect of the forearm, extending from below the elbow to the 1st dorsal interosseous.

In contrast, injury to the radial nerve in the axilla will also cause weakness of elbow extension and sensory loss in the distribution of the more proximal cutaneous branches. This helps distinguish it from injury in the spiral groove.

In the forearm, the posterior interosseous branch of the radial nerve can also be damaged. This can occur due to injury to the radial head or entrapment in the supinator muscle under the arcade of Frohse. However, this type of injury can be easily distinguished from injury in the spiral groove because there is no sensory involvement and no wrist drop, thanks to the preservation of the extensor carpi radialis longus. Nonetheless, there will still be weakness in the wrist and fingers.

Obstruction of the long circumferential branches of the basilar artery leads to the lateral pontine syndrome. This condition is characterized by several symptoms. Firstly, there is ataxia, which is caused by damage to the cerebral peduncles. Additionally, there is ipsilateral loss of pain and temperature sense on the face, resulting from damage to CN V. Another symptom is ipsilateral paralysis of the upper and lower face, which occurs due to damage to CN VII. Furthermore, vertigo, nystagmus, tinnitus, deafness, and vomiting are present, all of which are caused by damage to CN VIII. Lastly, there is contralateral sensory loss to the body, which is a result of damage to the spinothalamic tracts.

For individuals who have been in contact with patients diagnosed with Neisseria meningitidis meningitis, the recommended medication to prevent the infection is rifampicin 600 mg taken orally twice a day for two days. Alternatively, a single oral dose of ciprofloxacin 500 mg can also be administered. However, it is important to note that both rifampicin and ciprofloxacin should not be used during pregnancy and are contraindicated in such cases. Therefore, in situations involving pregnant individuals, the preferred option is a single 250 mg dose of ceftriaxone given intramuscularly.

Guillain-Barré syndrome (GBS) affects approximately 1-2 individuals per 100,000 annually and is a condition that primarily affects the peripheral nervous system, including the autonomic system. The most common initial symptom is weakness in the hands or feet, often accompanied by pain and tingling sensations as the paralysis spreads. Miller Fisher syndrome, a variant of GBS, is characterized by a triad of symptoms: ataxia, areflexia, and ophthalmoplegia.

Due to the potential serious consequences of autonomic involvement, such as fluctuations in blood pressure and cardiac arrhythmias, patients with GBS are typically hospitalized. As the diaphragm becomes paralyzed and swallowing becomes difficult, patients may require ventilation and nasogastric feeding.

GBS is an autoimmune disease that usually develops within three weeks of an infection. The leading cause is Campylobacter jejuni, followed by Epstein-Barr virus, cytomegalovirus, and Mycoplasma pneumoniae. While the patient’s immune response effectively targets the initial infection, it also mistakenly attacks the host tissue.

Symptoms of GBS typically peak around four weeks and then gradually improve. Diagnosis is based on clinical examination, which confirms the presence of areflexia and progressive weakness in the legs (and sometimes arms). Nerve conduction studies and lumbar puncture can also aid in diagnosis, with the latter often showing elevated protein levels and few white blood cells.

Treatment for GBS is primarily supportive, with the use of immunoglobulins to shorten the duration of the illness being common. Plasma exchange may also be utilized, although it has become less common since the introduction of immunoglobulin therapy.

Approximately 80% of patients with GBS make a full recovery, although this often requires a lengthy hospital stay. The mortality rate is around 5%, depending on the availability of necessary facilities such as ventilatory support during the acute phase. Additionally, about 15% of patients may experience some permanent disability, such as weakness or pain.

This woman is displaying symptoms and signs that are in line with a diagnosis of meningococcal septicaemia. In the United Kingdom, the majority of cases of meningococcal septicaemia are caused by Neisseria meningitidis group B.

The implementation of a vaccination program for Neisseria meningitidis group C has significantly reduced the prevalence of this particular type. However, a vaccine for group B disease is currently undergoing clinical trials and is not yet accessible for widespread use.

The ulnar nerve provides innervation to several muscles in the hand. These include the palmar interossei, dorsal interossei, medial two lumbricals, and abductor digiti minimi. On the other hand, the median nerve innervates the opponens pollicis, lateral two lumbricals, and flexor pollicis brevis. Lastly, the radial nerve is responsible for innervating the extensor digitorum muscle.

Status epilepticus is a condition characterized by continuous seizure activity lasting for 5 minutes or more without the return of consciousness, or recurrent seizures (2 or more) without a period of neurological recovery in between. In such cases, it is important to address any low blood glucose levels urgently by administering intravenous glucose. While the patient may require additional antiepileptic drug (AED) therapy, the management of status epilepticus involves several general measures.

During the early stage of status epilepticus (0-10 minutes), the airway should be secured and resuscitation measures should be taken. Oxygen should be administered and the cardiorespiratory function should be assessed. It is also important to establish intravenous access. In the second stage (0-30 minutes), regular monitoring should be instituted and the possibility of non-epileptic status should be considered. Emergency AED therapy should be initiated and emergency investigations should be conducted. If there are indications of alcohol abuse or impaired nutrition, glucose and/or intravenous thiamine may be administered. Acidosis should be treated if severe.

In the third stage (0-60 minutes), the underlying cause of status epilepticus should be identified. The anaesthetist and intensive care unit (ITU) should be alerted. Any medical complications should be identified and treated, and pressor therapy may be considered if appropriate. In the fourth stage (30-90 minutes), the patient should be transferred to intensive care. Intensive care and EEG monitoring should be established, and intracranial pressure monitoring may be initiated if necessary. Initial long-term, maintenance AED therapy should also be initiated.

Emergency investigations for status epilepticus include blood tests for blood gases, glucose, renal and liver function, calcium and magnesium, full blood count (including platelets), blood clotting, and AED drug levels. Serum and urine samples should be saved for future analysis, including toxicology if the cause of the convulsive status epilepticus is uncertain. A chest radiograph may be taken to evaluate the possibility of aspiration. Additional investigations, such as brain imaging or lumbar puncture, may be conducted depending on the clinical circumstances.

Monitoring during the management of status epilepticus involves regular neurological observations and measurements of pulse, blood pressure, and temperature.