Neurological Disorders

Question 1

Contrast the signs in patients with unilateral cerebellar damage and patients with damage to the vermis of the cerebellum.

Answer 1

Unilateral cerebellar damage = patient sways and tends to fall towards the SAME SIDE as the lesion

Damage to vermis of cerebellum = patient loses balance and falls BACKWARDS

Question 2

What can mimic cerebellar dysfunction/cause temporary cerebellar dysfunction?

Answer 2

Alcohol intoxication

Question 3

Describe the causes of vitamin B12 deficiency, and what effect this can have on the nervous system.

Answer 3

Aetiology:

• lack of intrinsic factor (congenital or due to gastrectomy) —> pernicious anaemia
• bacterial overgrowth competing for vitamin B12 (blind-loop syndrome)
• lack of absorption (ileal resection or Crohn’s disease)
• malnutrition

Can cause subacute combined degeneration of the cord (myelin degradation of the dorsal and lateral columns)

• spasticity, reduced coordination, and impaired sensation in the lower limbs
• optic atrophy
• cerebral changes —> psychiatric disease

Question 4

Describe what effects pyridoxine/vitamin B6 deficiency can have on the nervous system.

Answer 4

Reversible ataxia & progressive sensory neuropathy

Due to degeneration of dorsal columns (loss of light touch, 2-point discrimination, and conscious proprioception)

Question 5

Describe what effects syphilis (tertiary?) can have on the nervous system.

Answer 5

Dorsal column loss (tabes dorsalis)

S&S:

• dementia
• paraesthesia (“lightning”)
• weakness
• hyporeflexia
• locomotor ataxia
• degeneration of joints
• positive Romberg’s test
• episodes of intense pain & disturbed sensation
• urinary incontinence
• deafness
• visual impairment
• Argyll-Robertson pupil (loss of light reflex - consensual???)

Question 6

What is Friedreich’s ataxia?

Answer 6

Congenital degeneration of the spinal cord

S&S:

• progressive ataxia of limbs & gait (degeneration of dorsal root ganglia)
• dysarthria, dysphagia, visual & hearing loss (degeneration of cranial nerves)
• extensor plantar responses (positive Babinski reflex?)
• areflexia
• pyramidal weakness in lower limbs
• loss of joint position & vibration in lower limbs

note: vitamin E deficiency can present the same way but is treatable and reversible

Question 7

Describe which areas of the spinal cord can be affected by different neurological diseases.

Answer 7

Dorsal columns:

• subacute combined degeneration (vitamin B12 deficiency)
• Friedreich’s ataxia
• tabes dorsalis (syphilis)

Ventral horn cells:

• motor neurone disease
• spinomuscular atrophy

Ventral corticospinal tract:
- motor neurone disease

Spinocerebellar tract:
- Friedreich’s ataxia

Lateral corticospinal tract:

• motor neurone disease
• subacute combined degeneration (vitamin B12 deficiency)
• Friedreich’s ataxia

Question 8

What is syringomyelia?

Answer 8

Formation of a longitudinal cavity within the spinal cord (syrinx)

Congenital or acquired (via repeated trauma over ~15yrs-20yrs to the cervical cord —> scarring —> cyst formation)

Can expand ventrally to compress motor nerve cells & the spinothalamic tract —> weakness and wasting of the muscles in hands & loss of awareness of pain and temp.

Can cause effective transection of the spinal cord

Question 9

Give some examples of UMN signs.

Answer 9

Remove inhibitory effect

• spastic paralysis —> loss of voluntary control of muscles (but muscles are still innervated and contract reflexively, so there is no muscle wasting)
• hypertonia (spasticity) —> stiff joints (arms flexed and legs extended)
• hypereflexia (flexor reflexes predominate in upper limbs, extensor reflexes predominate in lower limbs; particularly evident when present on one side only)
• clonus
• Babinski’s sign
• choreiform movements
• facial paralysis will be forehead-sparing (UMNs to upper face project to facial nuclei bilaterally) and contralateral
• pronator drift
• loss of abdominal reflexes (inc. cremasteric reflex)
• sensory deficits involve quadrants or halves of the body

Question 10

Define spastic paralysis.

Answer 10

Weakness of limb associated with increased reflex activity

—> resistance to passive movement (agonist and antagonist muscles contract simultaneously? CHECK)

—> normal body posture and gait affected

Question 11

What is lead pipe rigidity? Give an example of disorder it occurs in.

Answer 11

Hypertonia causing sustained resistance to passive movement throughout whole range of motion (no fluctuations)

Parkinson’s disease

Question 12

What is cogwheel rigidity? Give an example of a disease it occurs in.

Answer 12

Lead pipe rigidity + resting tremor = jerky resistance to passive movement as muscles tense and relax

Parkinson’s disease

Question 13

Define clonus. What is the pathophysiology? CHECK!!!

Answer 13

Rhythmical contraction of a muscle in response to a suddenly applied and then sustained stretch stimulus caused by an exaggerated stretch reflex

Due to a loss of desc. inhibition (UMN lesion) —> polysynaptic reflexes are visible (successive contractions after the initial reflex)

Abnormal no. of beats = 2+???

Question 14

What is Babinski’s sign?

CHECK

Answer 14

Extension/fanning of toes in response to drawing a blunt, pointed object along the lateral sole and across the metatarsals (in an ADULT - normal response is curling inwards of the foot)

POSITIVE OR NEGATIVE?

Question 15

Define choreiform movements. Give an example of a disorder which has this as a feature.

Answer 15

Brief semi-directed, irregular movements that are not repetitive or rhythmic, but appear to flow from one muscle to the next

Involuntary spasmodic movements of the limb and face

Hyperkinetic movement disorder

Movement is sudden but the resulting posture may be prolonged for a few seconds

e.g. Huntington’s chorea

Question 16

Give some examples of LMN signs.

Answer 16

• flaccid muscle weakness or paralysis (total transection)
• hypotonia —> atonia (depends on no. of motor neurones affected)
• denervation muscle atrophy
• –> muscle wasting (reduced release of trophic factors at NMJ) —> contractures (muscle replaced by fibrous tissue)
• –> fasciculations (ACUTE) —> no fasciculations (CHRONIC)
• hyporeflexia
• associated sensory deficits likely to have a peripheral nerve pattern

Question 17

Define flaccid muscle weakness.

Answer 17

Absence of muscle tone in one or both limbs and absent tendon reflexes

Question 18

Define fasciculations.

Answer 18

Brief spontaneous contraction of a few muscle fibres, seen as a flicker of movement under the skin (ACUTE PHASE)

Question 19

Explain the pathophysiology of denervation muscle atrophy.

Answer 19

Reduced release of trophic factors at NMJ

• –> fasciculations (ACUTE)
• increased expression of nAChRs to compensate for reduced firing from nerve
• low threshold; so ACh-similar molecules also stimulate (inc. diffuse ACh in the blood supplying the muscles)
• –> no fasciculations (CHRONIC)
• muscle death has occurred

Question 20

What are some signs of cerebellar dysfunction?

Answer 20

DANISH

Dysmetria/dysdiadochokinesia 
Ataxia 
Nystagmus 
Intention tremor 
Scanning/slurred speech 
Hypotonia/hyporeflexia

note: no muscle atrophy/weakness (desc. pathways intact)
note: cannot learn new movements (cerebrocerebellum required to automate new movements)

Question 21

What are the features of cerebellar ataxia?

Answer 21

COORDINATION:

• clumsiness of voluntary movements
• wide-based “rolling” gait (lurching, reeling)
• maintaining balance difficult due to impaired muscle coordination timing (hypotonia)
• dysmetria (past-pointing)
• dysdiadochokinesis

Nystagmus common

Dysarthria = scanning speech (slow, monotonous)

Intention tremor (movements decomposed into a succession of separate movements instead of one smooth action)

Question 22

Define dysmetria. What part of the brain is damaged?

Answer 22

“Past-pointing”

Pointing past finger in finger-nose test due to impaired muscle coordination timing —> miss target/large scale error correction required

Contrast with intention tremor

Cerebellum damaged

Question 23

Define dysarthria. What part of the brain is damaged?

Answer 23

“Scanning speech”

Monotone speech due to impaired movement planning of muscles of face, mouth, and tongue

Cerebellum damaged

Question 24

Why do cerebellar disorders cause hypotonia and hyporeflexia?

Answer 24

Cerebellum involved in setting muscle tone

Question 25

What is true writer’s cramp?

Answer 25

Antagonist muscles co-activated —> fine precision movements impaired —> hand locks up

Question 26

Define dysdiadochokinesia. What part of the brain is damaged?

Answer 26

Abnormal agonist/antagonist muscle coordination —> clumsiness performing rapidly alternating movements

Cerebellum = matches motor output with motor intention and corrects errors (loss of function —> errors not corrected and get worse as action is repeated)

Question 27

What is an intention tremor? What part of the brain is damaged?

Answer 27

When approaching target in finger-nose test, there is a tremor (increased tremor the closer to the target)

Contrast with resting tremor

Cerebellum = movements decomposed into a succession of movements instead of one smooth action

Question 28

Give some examples of causes of cerebellar dysfunction.

Answer 28

Tumours

Cerebrovascular disease e.g. stroke

Alcohol (cerebellar atrophy)

Genetic e.g. Friedreich’s ataxia (degeneration of pathways in cerebellum)

Question 29

What can basal ganglia dysfunction cause?

Answer 29

HYPOkinetic disorders e.g. Parkinson’s disease

HYPERkinetic disorders e.g. Huntington’s disease

Question 30

Outline the pathophysiology of Parkinson’s disease.

Answer 30

Progressive degeneration of dopaminergic neurones (pigmented) of the pars compacta of the substantia nigra, locus ceruleus, and other brainstem nuclei (50%+ loss —> symptomatic)

Reduced inhibition in neostriatum —> loss of inhibition in neostriatum —> increased ACh production and increased excitation —> chain of abnormal signalling —> impaired mobility

DIRECT PATHWAY:
—> reduced activation of D1 receptors of striatum —> reduced inhibition of globus pallidus interna and pars reticulata of substantia nigra —> increased inhibition of thalamus —> reduced stimulation of striatum and cerebral cortex —> bradykinesia

INDIRECT PATHWAY:
—> reduced inhibition of D2 receptors of striatum —> increased inhibition of globus pallidus externa —> reduced inhibition if subthalamic nucleus —> increased stimulation of globus pallidus interna and substantia nigra

Surviving neurones contain Lewy bodies (round eosinophilic inclusions containing alpha-synuclein) —> becomes widespread —–> diffuse Lewy body disease/dementia

Question 31

What are the signs and symptoms of Parkinson’s disease?

Answer 31

Triad:

• slow resting tremor (begins in hands - “pill-rolling tremor”); reduced by purposeful movements (basal ganglia involved in planning of movements; so tremor improves once movement begins)
• hypertonia —> lead pipe rigidity
• bradykinesia/akinesia
• postural instability (late change)
• mood changes
• pain
• cognitive change
• sleep disorder
• sweating
• mask-like face (eyes wide open, infrequent blinking)

Lead pipe rigidity + resting tremor = cog-wheel rigidity

Parkinsonian gait

• slow, shuffling gait (marche a petit pas)
• difficult to stop movement (festination)
• slow pedestal turning (unsteady when changing direction)
• difficult to get up from a chair and start walking
• stooped shoulders (flexed posture)
• reduced arm swing
• improved using visual aids e.g. lines on the floor (cerebellum used more)

note: coordination is preserved (bradykinesia may be confused with lack of coordination)
note: usually presents unilaterally initially but becomes bilateral gradually e.g. tremor presents unilaterally and then becomes generalised over months-years (basal ganglia affect the corticospinal and rubrospinal tracts, which decussate —> contralateral side affected initially)

Question 32

What is Brown-Séquard syndrome? CHECK!!!

Answer 32

Hemisection of the spinal cord causing sensory dissociation causing sensory loss & flaccid weakness in the areas of the body supplied by the damaged segment

Aetiology:

• idiopathic spinal cord herniation
• trauma
• spinal cord mass
• MS
• degenerative e.g. disc herniation
• cystic disease
• haemorrhage/ischaemia
• infection

S&S:

• loss of pain & temp. below the lesion on the CONTRALATERAL side (due to loss of spinothalamic tract - decussates at the approximate level of the lesion)
• spastic paralysis below the lesion & positive Babinski sign on the CONTRALATERAL side (due to loss of corticospinal tract)
• absent position sense, vibration, 2-point discrimination, & light touch at the level of the lesion (CHECK!!!!!) on the IPSILATERAL side (due to of dorsal column - decussates in the medulla)
• pyramidal tract weakness at the level of the lesion (CHECK!!!) on the IPSILATERAL side (due to loss of corticospinal tract)

Dependent on level of lesion:

• sphincter disturbances (nerve roots????)
• sympathetic fibres in neck damaged —> ipsilateral Horner’s syndrome

Question 32

What is the prognosis of Parkinson’s disease?

Answer 32

15yr follow-up

• 94% dyskinesia
• 81% falls
• 84% cognitive decline (50% hallucinations)
• 80% drowsiness
• 50% dysphagia
• 27% dysarthria

Question 33

How is Parkinson’s disease diagnosed?

Answer 33

Clinical features

Exclude other causes of Parkinsonism

Response to treatment

Structural neuroimaging is normal

Functional neuroimaging e.g. PET

Question 34

What are the pharmacological treatments of Parkinson’s disease?

Answer 34

L-dopa/levodopa

note: add peripheral DOPA decarboxylase inhibitor to allow majority to reach the brain

Dopamine receptor agonists e.g. bromocriptine, ropinirole

MAO-B inhibitors e.g. selegiline
- enhance dopamine action by preventing breakdown by MAO-B

COMT inhibitors e.g. entacapone

• reduces peripheral breakdown of L-DOPA
• reduces wearing off L-DOPA (prolongs motor response)

Anticholinergics e.g. procyclidine

• ?antagonistic effect to dopamine
• treats tremor
• ADRs = confusion, drowsiness, usual anticholinergic effects

Amantadine

• ?increased dopamine release
• ?ACh NMDA inhibition

Question 35

Describe the pharmacokinetics, ADRs, and drug-drug interactions associated with levodopa.

Answer 35

Dopamine replacement

PHARMACOKINETICS:

• actively transported across blood-brain barrier
• converted to dopamine in substantia nigra (9% converted to dopamine in peripheral tissues)
• PO (must add peripheral DOPA decarboxylase inhibitor e.g. co-careldopa, co-beneldopa to increase amount reaching the brain)
• t1/2 = ~2hrs

ADRs:

• limited to functionality of dopaminergic neurones —> treatment failure will eventually result —> akinesia (frozen)
• can cause hyperkinesia (excessive activation of direct pathway and inhibition of indirect pathway; e.g. involuntary movements, dyskinesias, dystonias) alternating with hypokinesia (freezing - stop suddenly; feel as if feet are glued to the floor) (ON/OFF FLUCTUATIONS)
• protein deposits —> Lewy body dementia (fluctuating cognition, visual hallucinations, Parkinsonism)
• wearing off (as L-dopa wears off at end of dose, motor fluctuations occur)
• impulse control behaviours affected (frontal lobe disinhibition) e.g. pathological gambling, hypersexuality
• N&V
• hypotension
• psychosis (schizophrenic-like effects e.g. hallucinations, delusions, paranoia)
• tachycardia

DDIs:

• pyridoxine (vitamin B6) increases peripheral breakdown of L-dopa
• MAO inhibitors —> hypertensive crisis
• anti-psychotics block dopamine receptors —> Parkinsonism

Question 36

Describe the pharmacokinetics and ADRs associated with dopamine receptor agonists.

Answer 36

e.g. bromocriptine, ropinirole

• de novo or adjuvant
• ergot-derived or non-ergot-derived (reduced ADRs)

ADRs:

• fewer dyskinesia/motor complications than L-DOPA (but less effective)
• impulse control disorders e.g. pathological gambling, hypersexuality, punding, compulsive shopping
• psychiatric symptoms (dose-limiting) e.g. hallucinations, confusion
• sedation e.g. excessive daytime sleepiness
• hypotension
• nausea
• ergot-derived = fibrotic reactions inc. pulmonary fibrosis, retroperitoneal fibrosis, pericardial fibrosis

Question 37

Define punding. When does it occur?

Answer 37

• intense fascination with repetitive manipulations of technical equipment
• continual handling, examining, and sorting of common objects
• excessive grooming
• hoarding
• fidgeting
• pointless driving/walking
• extended monologues devoid of rational content

Associated with dopamine receptor agonists

Question 38

What are the surgical treatments of Parkinson’s disease? When is it indicated?

Answer 38

Sterotactic (use of 3D coordinates to locate small targets; minimally invasive) = targets thalamus for tremor and globus pallidus interna for dyskinesias

Deep brain stimulation targets subthalamic nucleus

Useful in people who are dopamine responsive but have significant side-effects to L-DOPA with no psychiatric illness

Question 39

Give some examples of disorders which are encompassed in Parkinson Plus. What are some red flags for Parkinson Plus?

Answer 39

Drug-induced e.g. dopamine blockers/depleters, anti-psychotics e.g. haloperidol

CO poisoning (mental impairment and residual Parkinsonism as a consequence of hypoxia)

Organic solvent poisoning e.g. carbon disulfide

Progressive supranuclear palsy:

• Parkinsonism
• postural instability with early falls
• rigidity in extension only
• vertical supranuclear gaze palsy
• pseudobulbar palsy
• dementia

Multiple system atrophy:

• Parkinsonism
• ataxia and autonomic symptoms e.g. postural hypotension, urinary incontinence, pyramidal tract dysfunction (Shy-Drager syndrome)
• cerebellar involvement
• disappointing response to L-dopa (due to degeneration of post-synaptic neurones in basal ganglia)

Corticobasal degeneration:

• alien limb phenomenon
• myoclonus
• dementia

Wilson’s disease = screen all under 50yrs with akinetic-rigid syndrome

Red flags:

• symmetrical presentation
• absence of tremor
• poor response to levodopa
• early falls (first yr)
• additional neurological features

Question 40

Outline the pathophysiology of Huntington’s chorea.

Answer 40

Autosomal dominant

Expansion of trinucleotide repeat

Accumulation of abnormal protein

Affects neostriatum, substantia nigra, hippocampus, cerebral cortex, hypothalamus, thalamus

Symptoms begin in early middle age

Question 41

What are the signs and symptoms of Huntington’s chorea?

Answer 41

• unsteady gait
• hyperkinetic, jerky, arrhythmic involuntary movements (choreiform)
• behavioural changes e.g. anxiety, depression, blunted affect (reduced display of emotions), aggression, compulsive behaviours
• progressive dementia

Question 42

Define hemiballismus. What part of the brain is damaged? Give some examples of causes.

Answer 42

Violent involuntary movement usually restricted to one arm and primarily involving the proximal muscles

Basal ganglia

Causes:

• stroke
• haemorrhage
• trauma

Question 44

Describe the diagnosis and pharmacological management of myasthenia gravis.

Answer 44

Fluctuating, fatiguable weakness of skeletal muscle

• extraocular muscles
• bulbar involvement e.g. dysphagia, dysphonia, dysarthria
• limb weakness
• resp. muscle involvement

DIAGNOSIS: give IV ACh-ase inhibitor and see if muscle weakness improves

Drugs affecting neuromuscular transmission exacerbate e.g.

• aminoglycosides
• beta-blockers
• quinidine, chloroquine
• succinylcholine
• magnesium
• ACE inhibitors

Acute exacerbation —> myasthenic crisis = worsening of muscle weakness resulting in resp. failure that requires intubation and mechanical ventilation

Management = ACh-ase inhibitors

• pyridostigmine = PO; 30min onset, 3-6hr duration
• neostigmine = PO, IV; 4hr duration
• ADRs = SSLUDGE = Salivation, Sweating, Lacrimation, Urinary incontinence, Diarrhoea, GI upset/hypermobility, Emesis

Over-treatment —> cholinergic crisis = over-stimulation at NMJ due to excess ACh —> flaccid paralysis, resp. failure, increased sweating and salivation, miosis

Question 45

Define: akinesia, apraxia, agnosia, aphasia, areflexia, and ataxia.

Answer 45

AKINESIA = absence or loss of power of voluntary muscles

APRAXIA = loss of purposeful movements despite the preservation of muscle power, sensation, and coordination

AGNOSIA = lack of the perceptual ability to recognise objects

APHASIA = impaired speech communication

AREFLEXIA = absence of reflexes

ATAXIA = loss of muscular coordination

Question 46

Define: dysphagia, dysarthria, dysphonia, dysdiadochokinesis, dyslexia.

Answer 46

DYSPHAGIA = difficulty swallowing

DYSARTHRIA = slowing/slurring of speech due to loss of coordination of muscles of speech

DYSPHONIA = any disorder in voice production

DYSDIADOCHOKINESIS = difficultly performing repetitive movements

DYSLEXIA = showing a level of reading/writing below expected for measured IQ

Question 47

Contrast the definitions of hypotonia and hypertonia.

Answer 47

HYPOTONIA = weakened/dampened reflexes
- arise when any component of the muscle stretch reflex is compromised

HYPERTONIA = abnormally high muscle tone
- most commonly seen as spastic paralysis following a stroke damaging UMNs

Question 48

What is motor neurone disease?

Answer 48

a.k.a amyotrophic lateral sclerosis (ALS), Lou Gehrig’s disease, supranuclear palsy

Damage to lateral (and ventral) part of nervous system causing reduced muscle growth due to denervation atrophy

Lateral = autonomic motor 
Ventral = somatic motor

• ocular motor nerves & anal sphincter function preserved
• death occurs when respiratory muscles are affected

Question 49

What areas of the nervous system are damaged in polio myelitis?

Answer 49

Selectively affects motor neurones (in ~0.1%-0.5% of cases)
—> acute flaccid paralysis (spinal, bulbar, or bulbospinal)

note: causes lesion on cell body of alpha-motoneurones (limb muscles and resp. muscles equally vulnerable) —> loss of neuronal innervation —> loss of ability to produce force acutely and chronically (no chance of recovery)

Question 50

Define: paraplegia, hemiplegia, quadriplegia, ophthalmoplegia.

Answer 50

PARAPLEGIA = paralysis of both of a pair of limbs (usually the legs)

HEMIPLEGIA = paralysis of ipsilateral limbs (arm and leg on the same side)

QUADRIPLEGIA = paralysis affecting all four limbs (also known as tetraplegia)

OPHTHALMOPLEGIA = weakness of extraocular muscles of the eye

Question 51

Define: paresis, hemiparesis, palsy.

Answer 51

PARESIS = muscular weakness

HEMIPARESIS = weakness affecting one side of the body or face

PALSY = weakness

Question 52

Contrast spasticity and rigidity.

Answer 52

SPASTICITY = resistance to passive movement of a limb which is maximal at the beginning of movement and gives way as more pressure is applied

RIGIDITY = resistance to passive movement of a limb which persists throughout range

Question 53

What is a positive Romberg sign? What does it indicate?

Answer 53

Inability to stand with feet together without swaying when eyes are closed.

Patient maintains posture when eyes are open (visual aspect is compensating for loss of balance from vestibular or cerebellar systems)

Lesion in vestibular or cerebellar systems (but cerebellar system damage can be so severe that it causes truncal instability even whilst eyes are open)

Question 54

What is the classical presentation of a sensory ataxia gait? Give some examples of causes.

Answer 54

• difficulty picking feet up
• stamp feet down
• “stick and stamp”
• exacerbated in the dark (cannot see feet)

Due to impaired sensation in lower limbs

• dorsal columns lost (loss of proprioceptive input) e.g. vit. B12 deficiency —> subacute combined degeneration of the cords
• peripheral nerves lost (loss of sensation) e.g. diabetic peripheral neuropathy

Question 55

What is the classical presentation of a hemiplegic gait? Give some examples of causes.

Answer 55

Circumductive gait

• unilateral weakness on affected side
• arm flexed, adducted, and internally rotated
• leg extended with plantarflexion

Whilst walking, patient will hold arm to one side and drag affected leg in a semicircle (circumduction) due to footdrop and extensor hypertonia in lower limb

e.g. stroke

Question 56

What is the classical presentation of a diplegic gait? Give some examples of causes.

Answer 56

• involvement on both sides
• spasticity in lower limbs worse than upper limbs
• extreme tightness of hip adductors —> scissor gait

Patient walks with abnormally narrow base, dragging both legs and scraping toes along the ground.

e.g. cerebral palsy

Question 57

What is the classical presentation of a neuropathic gait? Give some examples of causes.

Answer 57

“Steppage gait”

Occurs in foot drop - patient attempts to lift leg high enough during walking so that the foot does not drag on the floor

Unilateral e.g. peroneal nerve palsy, L5 radiculopathy
Bilateral e.g. ALS, Charcot-Marie-Tooth, diabetic peripheral neuropathy

Question 58

What is the classical presentation of a myopathic gait? Give some examples of causes.

Answer 58

“Waddling gait”

• unilateral weakness in gluteus medius and minimus causes pelvis to drop on the contralateral side during walking (Trendelenburg sign)
• bilateral weakness in gluteus medius and minimus causes pelvis to drop on both sides during walking —> waddling gait
  e. g. muscular dystrophy

Question 59

What is the classical presentation of a Parkinsonian gait? Give some examples of causes.

Answer 59

Rigidity + bradykinesia

• stooped
• head and neck forward
• upper limbs in flexion with finger extended
• walks with slow little steps (marche a petits pas)
• difficulty initiating steps
• involuntary acceleration (festination)

e.g. Parkinson’s disease, Parkinson plus, drugs

Question 60

What is the classical presentation of a choreiform gait? Give some examples of causes.

Answer 60

Irregular, jerky movements in all extremities.

Walking may accentuate baseline movement disorder

e.g. Huntington’s chorea

Question 61

What is the classical presentation of an ataxic gait? Give some examples of causes.

Answer 61

Cerebellar

• wide based
• clumsy
• staggering
• titubations whilst standing still (truncal instability - vermis of cerebellum affected)
• not be able to walk heel to toe or in a straight line

e.g. alcohol intoxication, cerebellar lesion

Question 62

What is spinal shock?

Answer 62

Loss of sensation accompanied by motor paralysis with initial loss but gradual recovery of reflexes following a spinal cord injury

Initial stage of hyporeflexia following acute lesions

Then there is hyperreflexia

Question 63

Explain how cervical arthritis can present. How would this be treated?

Answer 63

Spinal nerves emerging from intervertebral foramina of the cervical vertebrae compressed by enlarged apophyseal joints

Presentation depends on nerves affected

e.g. 
C8/T1 nerves affected: 
- absent triceps reflex 
- weak extension and abduction of wrist 
- weakness of whole hand 
- paraesthesia of medial side of arm and hand 

+ occipital headache
+ neck pain

Treatment:
- cervical collar to limit movement

Question 64

Describe the presentation and pathophysiology of multiple sclerosis.

Answer 64

Autoimmune destruction of myelin causing formation of scar tissue (sclerosis), resulting in slowed or blocked transmission of impulses.

Genetic and environmental factors e.g. viral infections

S&S:

• visual (optic nerve demyelination) = blindness, hemianopia, optic neuritis
• extraocular = diplopia, symmetrical horizontal jerking nystagmus, lateral rectus palsy
• facial = Bell’s palsy, trigeminal neuralgia, paroxysmal dysarthria
• vestibular = deafness, unsteadiness, positional vertigo, vomiting, ataxia, headache
• cognitive = memory loss
• depression
• spinal tracts = tightness/burning/twisting/pulling sensations or loss of sensation (dorsal columns), loss of pain and temperature sensation (spinothalamic tracts), numbness of perineum and genitalia, altered sphincter function
• transverse myelitis (acute episode of weakness/paralysis of both legs with sensory loss and urinary/faecal incontinence)
• ANS = urgency and frequency urinary incontinence, impotence, loss of thermoregulation
• Horner’s syndrome
• arrhythmias
• acute pulmonary oedema (abnormal vascular responses)
• weight loss
• inappropriate ADH secretion

Relapsing-remitting MS (80%) = periods of remission, but each relapse leaves disability which compound over time (50% develop secondary progressive MS where there are fewer remissions and worsening of symptoms)

Primary progressive MS (10%-15%) = symptoms gradually develop and worsen over time

note: scattered neurological signs are typical of a demyelinating disorder, and the most common explanation is MS

Question 65

What is the most common cause of lower back pain? How can it be differentiated from other causes?

Answer 65

Soft tissue injury (muscles, ligaments, tendons)

• occurs following back muscle spasms
• no loss of sensation (loss of sensation occurs in sciatica)
• more pain on active movement (use of muscles)
• negative straight leg raise test (sciatic pain between 30-70 degrees indicates sciatica)
• no loss of reflexes (ankle jerk reflex may be lost in sciatica)