11- Paediatric Neurology (2/3)

Question 1

intracranial pressure

Answer 1

‘The pressure within the cranium of the skull’

Question 2

monroe kellie doctrine

Answer 2

** sum of volumes of (1) Brain, (2 CSF and (3) Intracranial blood is constant**
- Skull is a rigid box
- If one of these components is lost e.g. a bleed or tumour (SOL) , other components of this volume will need to reduce to make sure the sum of volume stays constant

Question 3

intracranial elastance curve

Answer 3

• As intracranial volume increases initially ICP stays the same due to compensatory mechanisms
• After mechanisms exhausted the ICP will increase

Question 4

ICP and (1) Blood

Answer 4

Need constant blood supply to supply neurones and brain tissue. Incredibly sensitive to low oxygen.

Cerebral perfusion pressure (CCP) represents cerebral blood flow.
- CPP = Mean arterial pressure (MAP)- ICP

If ICP increased, perfusion of the brain decreases (without cerebral autoregulation)- BV will vasodilate

Question 5

cerebral autoregulation

Answer 5

• If MAP increases then CPP increases, triggering cerebral autoregulation to maintain cerebral blood flow (vasoconstriction)
• If ICP increases then CPP decreases, triggering cerebral autoregulation to maintain cerebral blood flow (vasodilatation)  will result in having to increase MAP- therefore hypertension
• If CPP <50 mmHg then cerebral blood flow cannot be maintained as cerebral arterioles are maximally dilated
• ICP can be maintained at a constant level as an intracranial mass expands, up to a certain point beyond which ICP will rise at a very rapid (exponential) rate
• Damage to the brain can impair or even abolish cerebral autoregulation

Question 6

ICP and (2) CSF

Answer 6

• CSF produced by the choroid plexus into the lateral ventricles
• Around 500mls produced each day
• Homeostasis, protection, buoyancy and waste clearance

Question 7

ICP and (3) brain

Answer 7

• If herniating, usually high pressure inside
• Types of herniation
  o Subfalcine herniation (commonest)
  o Tonsillar herniation (aka coning)
  o Uncal herniation

Question 8

raised ICP is due to

Answer 8

• Too much blood
• Too much CSF
• Too much brain

Question 9

presentation of RICP

Answer 9

• Headaches (At night time, waking and bending over)
• Nausea + vomiting
• Visual disturbances e.g. double vision
• Drop of >2 in GCS
  o Confusion
  o Seizures
  o Amnesia
• Papilledema
• Focal neurological signs
  o E.g. CN3 palsy – papillary dilatation
• Abnormal posturing (decorticate, decerebrate)
• CushinGs reflex

Question 10

3 Primary signs of RICP

Answer 10

Cushings triad
- hypertension
- bradycardia
- irregular breathing

LATE SIGNS

Question 11

pathophysiology of (1) too much blood

Answer 11

1) Too much blood within cerebral vessels (rare)
- Raised arterial pressure- malignant hypertension
- Raised venous pressure- SVC obstruction

2) Too much blood outside the cerebral vessels (haemorrhage)
- Extradural
- Subdural
- Subarachnoid

Question 12

causes of too much blood within cerebral vessels

Answer 12

• malignant hypertension
• superior vena cava obstruction

Question 13

Malignant (accelerated) hypertension

Answer 13

• Systolic >180mmHg or Diastolic >120mmHg
  * Usually renal cause in children
• Signs of target organ damage
  o Retinal haemorrhages
  o Encephalopathy
  o Left ventricular hypertrophy
  o Reduced renal function
• Urgent referral

Question 14

Superior vena cava (SVC) obstruction

Answer 14

• Reduction in venous return from head & neck & upper limbs
• Most common cause is malignancy
  o Non-Hodgkin’s in children
• Oncology Emergency
• Presentation
  o Local oedema of the face and upper limbs
  o Dilated veins in the arm and neck and anterior chest wall
  o SoB
  o Difficulty swallowing
  o After lifting arms the signs will get worse

Question 15

(2) Too much CSF also known as

Answer 15

hydrocephalus

Question 16

hydrocephalus background

Answer 16

• CSF build up abnormally in the brain and spinal cord
• Due to over-production or problems draining or absorbing CSF

Question 17

hydrocephalus pathophysiology

Answer 17

*- Congenital
- Acquired
- Non-communicating vs communicating
**

Question 18

hydrocephalus pathophysiology

Answer 18

*- Congenital
- Acquired
- Non-communicating vs communicating
**

Question 19

congenital hydrocephalus

Answer 19

• Present at birth
• Genetic and non-genetic factors e.g. mutation in L1CAM gene linked to aqueductal stenosis

Question 20

pathophysiology of congenital hydrocephalus

Answer 20

• Most common cause is aqueductal stenosis ->Insuff drainage of CSF
• Cerebral aqueduct which connect third and fourth ventricle is stenosed

Question 21

presentation of congenital hydrocephaly

Answer 21

• Enlargement of head circumference- sutures not fused – occipito-frontal circumference (macrocephaly)
   Bulging from anterior fontanelles
   Poor feeding and vomiting
   Poor tone
   Sleepiness
• Downward gaze
• Delay in neurological development

Question 22

management of hydrocephalus

Answer 22

• VP shunt- ventricles- peritoneum
• VA shunt- ventricles- atria

Question 23

Normal CSF Physiology

Answer 23

There are four ventricles in the brain: two lateral ventricles, the third and the fourth ventricles.
The ventricles contain CSF.
The CSF provides a cushion for the brain tissue. CSF is created in the four choroid plexuses (one in each ventricle) and by the walls of the ventricles.
CSF is absorbed into the venous system by the arachnoid granulations.

Question 24

acquired causes of hydrocephaly

Answer 24

Acquired causes
- Intraventricular haematoma
- Tumour
- Infection
- Trauma

Question 25

too much CSF caused by obstruction (non-communicating)

Answer 25

Question 26

too much CSF- communicating hydrocephalus

Answer 26

Too much CSF- Communicating hydrocephalus
* Overproduction of CSF or
* Reduced absorption of CSF

Examples of cause
- Choroid plexus papilloma
- Infection and inflammation leading to scarring at subarachnoid space

Question 27

Ventriculoperitoneal Shunt

Answer 27

Placing a VP shunt that drains CSF from the ventricles into another body cavity is the mainstay of treatment for hydrocephalus. Usually the peritoneal cavity is used to drain CSF, as there is plenty of space and it is easily reabsorbed. The surgeon places a small tube (catheter) through a small hole in the skull at the back of the head and into one of the ventricles. A valve on the end of this tube is placed subcutaneously, and a catheter on the other side of the valve runs under the skin into the peritoneal cavity. The valve helps to regulate the amount of CSF that drains from the ventricles.

VP Shunt Complications
* Infection
* Blockage
* Excessive drainage
* Intraventricular haemorrhage during shunt related surgery
* Outgrowing them (they typically need replacing around every 2 years as the child grows)

Question 28

(3) too much brain

Answer 28

• Usually causes by cerebral oedema= swelling of the brain
• 4 types

Question 29

example causes of too much brain

Answer 29

• brain tumour e.g. primary, metastatic and intra
• cerebral abscess
• hypoxic brain injury causing oedema

Question 30

investigations for raised ICP

Answer 30

Bedside
- vital signs
- ECG
- fundoscopy

Bloods
- FBC
- UEs
- CRP
- clotting
- Group and save
- cross match
- blood culture

Imaging
- CT scan
- MRI

Question 31

CT head scan indication

Answer 31

• Acute presentation
  e.g. Head injury
• Chronic presentation

Question 32

management of RICP

Answer 32

Question 33

visual field defects

Answer 33

• Named based on the area of visual loss rather than site of lesion

e.g.
monocular blindness
bitemporal hemianopia
homonomous hemianopia

Question 34

causes of visual field defects

Answer 34

epilepsy
cerebral palsy
tumour
stroke

Question 35

anatomy of the central visual pathway

Answer 35

comprised of:
1. The optic nerve (CN II)
2. The optic chiams
3. The optic tracts
4. Optic radiations

Question 36

the optic nerve (CN II)

Answer 36

• Split into diff divisions (different fibres of the retina)
• Temporal (lateral)- orange
• Nasal (medial)- green
• Also have up and down

Question 37

otpic chiasm

Answer 37

• Nasal fibres decussate
• Temporal fibres remain ipsilateral

Question 38

optic tracts

Answer 38

• From optic chiasm to lateral geniculate nucleus (LGN
• Contains temporal fibres from the ipislateral side
• Contains nasal fibres from tbe contralateral side

Question 39

optic radiations

Answer 39

From LGN to primary visual cortex (x2 ) in the occipital lobe (x2 lobes)
- 2 routes to the occipital lobe
1. Superior route via the parietal (superior optic radiations)
- Continuation of superior quadrant fibres (temporal and nasal)
- ‘Baums loop’
2. Inferior route via the temporal (inferior optic radiations)
- Continuation of inferior quadrant fibres (temporal and nasal)
- “meyes loop’

Question 40

visual fields

Answer 40

Visual fields relate to peripheral vision (also called temporal and nasal). Each eye has its own set of visual filed
- These overlap to form binocular vision
- Good for depth perception

LIGHT TRAVELS IN STRAIGHT LINES… therefore:
- If we want to detect something in the temporal visual field, light will travel through the pupil straight to the nasal retinal fibres (temporal visual field detected by nasal retinal fibres)
- If we want to detect something in the nasal visual field, light will travel through the pupil straight to the temporal retinal fibres (nasal visual field detected by temporal retinal fibres)

Question 41

monocular blindness

Answer 41

Background
- blindness in one eye

Causes
- Optic nerve lesion

Pathophysiology
- lesion disrupts tmeproal and nasal fibres on the ipsilateal (same) side affected and vision lost

Question 42

bitemporal heminanopia

Answer 42

Background
- loss of temporal vision
- ‘tunnel vision’ only

Cause
- pituitary adenoma

Pathophysiology
- nasal fibres on both sides affected
- temporal visual field loss on both sides

Question 43

Homonymous hemianopia

Answer 43

background
- loss of both left or loss of both right

Cause
- lesion of the optic tract on the right or left hand side

Pathophysiology
- Left nasal retinal fibres (contralateral) and right temporal retinal fibres (ipsilateral) affected
- Left temporal (contralateral) visual field lost and right nasal (ipsilateral) field loss
- ‘left homonomous hemianopia’- even though lesion is on the right- due to decussation
o Name the visual defect on visual loss not lesion

Question 44

Optic radiation lesion

Answer 44

• Superior visual fields are detected by inferior retinal fibres
• Inferior visual fields are detected by superior retinal fibres

examples:
- Homonymous inferior quadrantanopias
- Homonymous superior quadrantanopias

Question 45

Homonomous inferior quadrantanopia (left)

Answer 45

Lesion on right superior optic radiation (parietal lobe)
- Superior ipsilateral temporal fibre affected
o Loss of inferior nasal visual field
- Superior contralateral nasal fibre affected
o Loss of inferior temporal visual fields

Question 46

Homonomous superior quadrantanopia (left)

Answer 46

• Inferior temporal fibres on ipsilateral side affected
  o Loss of superior nasal visual field
• Inferior nasal fibre on contralateral side is affected
  o Loss of superior temporal visual field