Stroke Review (KCP PDF)

Summary

This document reviews the blood supply of the brain and different types of strokes. It covers risk factors and treatment options. The document's content covers topics relevant to a medical class/review session on strokes. It includes detailed information pertaining to the central nervous system and its various components.

Full Transcript

Stroke
Review newer slide updated

Learning outcomes
1. Describe the blood supply of the brain
2. Recognise the difference between anterior and posterior circulations
3. Describe the structure of the cerebral cortex

4. Understand the sensory and motor functions of the cerebral cortex
5. Describe the language functions of the cerebral cortex
6. Describe the organisation of the motor and sensory pathways in the spinal cord
7. Recognise the features of Parkinson’s disease

8. Recognise presentation of a stroke and transient ischaemic attack
9. List the risk factors for a stroke
10. Outline initial investigation of a stroke
11. Describe the key features of a randomised, double blind, placebo-controlled
study
12. Outline initial treatment of an acute stroke

The brain
Uses 20% of total energy expenditure

Independent of how hard you think!

Blood supply critical to deliver oxygen and nutrients

Needs sleep

86 billion neurons with a quadrillion synapses ( a 1 with 15 “0”s)

Movement and balance

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 Hearing, vision, touch

Speech and language

Emotions and mood

Breathing, circulation, appetite, thirst

Dreams and ideas

We have a motor and a sensory cortex

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 Movement - how we interact with the world

Certain parts of the body are overrepresented in the brain eg face and hands

Stroke and TIA
Due to interruption of blood supply to the brain

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 TIA to stroke is on a spectrum

90% of TIA resolve within 90 minutes

Risk increases with age and more common in men

Treatment of a stroke
How do we decide how to treat a stroke?

Understand brain anatomy and physiology

Understand underlying pathogenesis

Arteries supplying the brain

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 Arterial blood supply to the heart

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 Treatment of stroke
Aspirin had been shown to be of benefit in myocardial infraction

Reduces the stickiness of platelets

Heparin thins blood and used to treat clots in veins

How could we find out if either is beneficial in strokes?

Conclusion
Aspirin reduced risk of further ischaemic strokes

Heparin reduced risk of further ischaemic strokes BUT increased risk of brain
haemorrhage

Standard treatment of stroke is oral aspirin initially

+
Stroke lifetime risk: 1 in 4 men, 1 in 5 women

A clinical stroke is characterised by:

Rapid onset focal neurological symptoms and/or signs

lasting >24 hours (or leading to death)

with no apparent cause other than vascular

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 Conditions that may mimic stroke:

Brain tumour, brain abscess

Bleed around the brain

Hypoglycaemia

Neurological condition affecting the brain eg multiple sclerosis

epileptic seizure

Modifiable risk factors for a stroke

Hypertension: lower blood pressure, salt

Smoking: stop smoking

Hyperlipidaemia: statins, diet, exercise

Diabetes melitus: weight loss, sugar content

Excessive alcohol intake: decrease alcohol

Atrial fibrillation: modify clotting of blood

10 factors for population attributable risk of stroke

1. Hypertension

2. Lack of Regular physical activity

3. Obesity

4. Hyper-lipidaemia

5. Smoking

6. Diet risk score

7. Cardiac causes

8. Diabetes

9. Stress, depression

Treatment after an acute stroke

Aspirin

Blood pressure control

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 Statins for increased cholesterol

Stroke unit vs conventional ward

Carotid surgery for Carotid stenosis

Anticoagulation for Atrial fibrillation

What are the causes of stroke?

Infarction (85%)

Atherothromboembolism 50%

Intracranial small vessel disease 25%

Embolism from heart 20%

Rarities 5%

Haemorrhage 15%

How do we decide how to treat a stroke

Understand brain anatomy and physiology

Understand underlying pathogenesis

The brain and spinal cord are delicate and so they have two protective
coverings

The outer covering consists of bone: cranial bones encase the brain;
vertebrae encase the spinal cord

The inner covering consists of membranes known as meninges. Three
distinct layers compose the meninges

Dura mater

the outermost, toughest and most durable layer

made of thick, dense connective tissue that helps protect the brain
and spinal cord

Arachnoid mater

Middle, web-like membrane

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 Thinner and more delicate than the dura mater

Pia mater

innermost layer, which is thin and tightly adheres to the surface of
the brain and spinal cord, following all the contours and folds of the
brain

Highly vascular, meaning it has many blood vessels that provide
nutrients and oxygen to the brain and spinal cord

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 The central nervous system

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 Coverings of the brain. A, Coronal (frontal) section of the superior portion of the head, as viewed
from the front. Both the bony and the membranous coverings of the brain can be
seen. B, Sagittal section of the skull, viewed from the left. The dura mater has been retained in
this specimen to show how it lines the inner roof of the cranium and the falx cerebri extending
inward.

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 Coverings of the spinal cord. The dura mater is shown in purple. Note how it extends to cover the
spinal nerve roots and nerves. The arachnoid mater is highlighted in pink and the pia mater in
orange.

The dura mater has three important inward extensions:

Falx cerebri

projects downward into the longitudinal fissure to form a kind of
partition between the two cerebral hemispheres

Falx cerebelli

sickle-shaped extension that separates the two hemispheres of the
cerebllum

Tentorium cerebelli

Separates the cerebellum from the cerebrum.

A number of spaces lie between and around the meninges. Three of the
spaces are the following:

Epidural space

Subdural space

Subarachnoid space

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 Formation of cerebrospinal fluid occurs mainly by separation of fluid from
blood in the choroid plexuses

Choroid plexuses are a network of capillaries that project from the pia
mater into the lateral ventricles and into the roofs of the third and fourth
ventricles.

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 A, The CSF produced by filtration of blood by the choroid plexus of each ventricle
flows inferiorly through the lateral ventricles, interventricular foramen, third
ventricle, cerebral aqueduct, fourth ventricle, and subarachnoid space and to the
blood. B, Inset showing arachnoid villus, where CSF is reabsorbed into the blood
of the superior sagittal sinus. C, Simplified diagram showing flow of CSF.

The cerebrum consists of the right and left cerebral hemispheres

The surface of the cerebrum - called the cerebral cortex - is made up of grey
matter only 2 to 4 mm thick

Though, cerebral cortex has 6 layers, each composed of millions of axon
terminals synapsing with millions of dendrites and cell bodies of other
neurones

Wrinkling in the surface of the brain regions provide great advantages

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 Such folding increases the total amount of grey-matter surface area and
thereby increasing the processing power of cerebrum and cerebellum

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 Beneath the cerebral cortex lies the large interior of the cerebrum

It is mostly white matter made up of numerous tracts

Tracts that make up the cerebrum’s internal white matter are of three
types

projection

association

commissural

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 A, Lateral perspective, showing various association fibres. B, (Coronal)
perspective, showing commissural fibres that make up the corpus callosum and
the projection fibres that communicate with lower regions of the nervous
system. C, Magnetic resonance (MR) tractography image showing a three-
dimensional view of tracts colour-coded by direction, as seen in a brain viewed
from above. Note the band of fibres in the corpus callosum connecting the two
cerebral hemispheres.

Projection tracts are extensions of the ascending, or sensory, spinothalamic
tracts and descending, or motor, corticospinal tracts

Association tracts

Most numerous of cerebral tracts

Extend from one convolution to another in the same hemisphere

Commissural tracts

Extend from a point in one hemisphere to a point in the other hemisphere

Compose the corpus collosum and the anterior and posterior commissures

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 A, The basal nuclei seen through the cortex of the left cerebral hemisphere. B, The basal nuclei
seen in a coronal (frontal) section of the brain.

The caudate nucleus, internal capsule, and lentiform nucleus constitute the
corpus striatum

Basal nuclei is involved in regulating voluntary motor functions, thinking and
learning

Cerebral plasticity - brains ability to adapt and reorganise its functions in
response to injury, experience, or change over time

The postcentral gyrus functions mainly as a general somatic sensory area

It receives impulses from receptors activated by heat, cold and touch
stimuli

The precentral gyrus functions as the somatic motor area.

Impulses from neurons in this area descent over motor tracts and
eventually stimulate somatic effectors, the skeletal muscles

The transverse gyrus of the temporal lobe serves as the primary auditory area.

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 The primary visual areas are in the occipital lobe.

It is important to remember that no part of the brain functions alone. Many
structures of the central nervous system must function together for any one part
of the brain to function normally.

The somatic senses include sensations of touch, pressure, temperature, body
position, and similar perceptions that do not require complex sensory organs

The special senses include vision, hearing, and other types of perception
that require complex sensory organs, such as the eye and the ear

Sensory fibres carrying information from receptors in specific parts of the
body terminate in specific regions of the somatic sensory area

Areas such as the face and hand have a proportionally larger number of
sensory receptors, so their part of the somatic sensory map is larger

Likewise, information regarding vision is mapped in the visual cortex, and
auditory information is mapped in the primary auditory area

Information sent to the primary sensory areas is in turn relayed to the various
sensory association areas, as well as to other parts of the brain.

There the sensory information is compared and evaluated.

Eventually, the cortex integrates separate bits of information into whole
perceptions

The precentral gyrus constitutes the primary somatic motor area

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 A secondary motor area lies in the gyrus immediately anterior to the
precentral gyrus

Neurons in the premotor area just anterior to the precentral gyrus are thought
to activate groups of muscles simultaneously.

Consciousness depends on excitation of cortical neurons by impulses
conducted to them by a network of neurons known as the reticular activating
system.

The reticular activating system (RAS) consists of centres in the brainstem’s
reticular formation that receive impulses from the spinal cord and relay them
to the thalamus and from the thalamus to all parts of the cerebral cortex

Both direct spinal reticular tracts and collateral fibres from the sensory
tracts (spinothalamic, lemniscal, auditory, and visual) relay impulses over
the reticular activating system to the cortex

Without continual excitation of cortical neurons by reticular activating
impulses, an individual is unconscious and cannot be aroused

Two current concepts about the reticular activating system

Functions as the arousal or alerting system for the cerebral cortex

Its functioning is crucial for maintaining consciousness

Drugs known to depress the reticular activating system decrease
alertness and induce sleep.

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 Reticular activating system (RAS). Consists of centres in the brainstem’s reticular formation plus
fibres that conduct to the centres from below and fibres that conduct from the centres to
widespread areas of the cerebral cortex. Functioning of the RAS is essential for regulating levels
of consciousness.

Emotions involve functioning of the cerebrum’s limbic system

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 Structures of the limbic system

The cortex is capable of storing and retrieving both short-term and long-term
memory.

Short-term memory involves the storage of information over a few
seconds or minutes

Region Structure Function

Elongated cylinder extending
from the brainstem through the
foramen magnum of the skull; Integration of simple, subconscious
Spinal cord grey matter interior surrounded spinal reflexes; conduction of nerve
by white matter; 31 pairs of impulses
spinal nerves attached by dorsal
and ventral nerve roots

Numerous synapses and
interneurons arranged into Integration of spinal reflexes and
Grey matter anterior, lateral, and posterior filtering of information going to higher
grey columns linked by a grey centres (as in gated pain control)
commissure

Myelinated nerve tracts Ascending tracts conduct sensory
arranged into anterior, lateral, information to higher CNS centres;
White matter
and posterior white columns descending tracts conduct motor
(funiculi) information from higher CNS centres

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 Extends inferiorly from
diencephalon to foramen
magnum of skull, where it meets
the spinal cord; central grey Subconscious integration of basic
Brainstem
matter nuclei surrounded and vital functions
connected by white matter
tracts; 10 of the 12 pairs of
cranial nerves attached here

Inferior region of brainstem Integration of cardiac, vasomotor
Medulla
between the spinal cord and the (vessel muscle), respiratory, digestive
oblongata
pons and other reflexes

Integration of numerous autonomic
Intermediate region of brainstem
reflexes mediated by cranial nerves V,
Pons between the medulla and the
VI, VII, and VIII (see Chapters 21 and
midbrain
22 ) and respiration

Integration of numerous cranial nerve
Superior region of the brainstem
reflexes, such as eye movements,
Midbrain between the pons and the
pupillary reflex, ear (sound muffling)
diencephalon
reflexes

Roughly cylindrical network of
Operates the reticular activating
Reticular nerve pathways and centres
system (RAS) that regulates state of
formation extending through the brainstem
consciousness
and into the diencephalon

Roughly spherical structure Coordinates many functions of
attached at the posterior of the cerebrum, including planning and
brainstem; wrinkled grey matter control of skilled movements, posture,
Cerebellum
cortex, branched network of balance, coordination of sensory
white fibres inside (arbor vitae), information relating to body position
and several small grey nuclei and movement

Brain region in the central part
of the brain, between the
Numerous coordinating and
Diencephalon cerebrum and brainstem
integrating functions
(midbrain); made up of various
grey-matter nuclei

Thalamus Large ovoid of grey matter, Crude sensations, coordination of
divided into two large lateral sensory information relayed to
masses connected by an cerebrum; involved in emotional
intermediate mass response to sensory information;

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 involved in arousal; general
processing of information to/from
cerebrum

Integration/coordination of many
Numerous grey-matter nuclei autonomic reflexes, hormonal
Hypothalamus
clustered below the thalamus functions; involved in arousal,
appetite, thermoregulation

Single nucleus of Produces melatonin, a timekeeping
Pineal gland neuroendocrine tissue posterior hormone, as part of the body’s
to the thalamus biological clock

Largest, most superior region of
Complex processing of sensory and
brain; divided into right and left
Cerebrum motor information; complex
hemispheres, connected by the
integrative functions
corpus callosum

Highly wrinkled grey-matter Higher-level processing of sensory
surface of the cerebrum; and motor information, including
divided into five major lobes per conscious sensation and motor
Cerebral cortex
hemisphere; functionally control; complex integrative functions
mapped based on concept of such as consciousness, language,
localization memory, emotions

White-matter tracts connect
Conduction information between CNS
various regions of the cortex
Cerebral tracts areas to facilitate complex processing
with each other and with inferior
and integration
CNS structures

Integration and regulation of
conscious motor control, especially
Grey-matter nuclei deep in the
Basal nuclei posture, walking, other repetitive
cerebrum
movements; possible roles in thinking
and learning

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 Anterior Circulation Stroke

Motor &/OR Senesory loss affecting

Face

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 Arm

Hand

Leg

Posterior Circulation Stroke

Any of:

Facial weakness

Disorder of eye movement

Contra-lateral motor / sensory loads

Co-ordination loss

Treatment of stroke

Aspirin had been shown to be of benefit in myocardial infraction

Reduces the stickiness of platelets

Heparin thins blood and used to treat clots in veins

How could we find out if either is beneficial in strokes?

Conclusion of stroke treament

Aspirin reduced risk of further ischaemic strokes

Heparin reduced risk of further ischaemic strokes BUT increased risk of brain
haemorrhage

Stroke 30
 Standard treatment of stroke is oral aspirin initially

Stroke 31