Pathophysiology of Central
Nervous System
Brain pathophysiology
Stroke
Craniotrauma
Degenerative disseases of brain
Spinal cord pathophysiology
Stroke
http://wikipedia.org
Stroke
Stroke is an acute neurological dysfunction due to vascular disturbance resulting
in rapid loss of brain functions
Vascular pathologies
• Disturbance of vessel wall permeability
• Disturbance of vessel contractility
• Vessel occlusion
✓ Thrombosis
✓ Embolism
• Vessel rupture
Atherosclerosis
Types o f stroke
• Ischemic (70%)
• Hemorrhagic (30%)
✓ Intracerebral hematoma
✓ Subarachnoid hemorrhage
Ischemic Stroke
Critical parameters
➢ Extent of ischemia
➢ Duration of ischemia
Atherosclerosis
Focal ischemic stroke
• Transient
✓Transient ischemic attack (TIA)
✓Prolonged reversible neurological deficit
• Permanent
✓Cerebral infarction
❖Embolism
❖Thrombosis
Global ischemic stroke
• Transient
✓Syncope
• Permanent
✓Hypoxic ischemic encephalopathy
Why is brain sensitive to ischemia?
High metabolic activity
• Membrane potential maintaining – repolaristion (Na/K pumps)
• Almost exclusivelly oxidative phosphorylation
• Consumption
✓Oxygen- 20% of body consumption
✓Glucose – 25% of body consumption
Small amount of energy reserves
http://assassinscreed.ubi.com
Ischemic Stroke
Core of infarction (centre of ischemia)
• Ireversible neuronal damage
• Primary injury
Penumbra (periphery of ischemia)
• Reversible neuronal damage
• Risk of secondary injury development
Ischemic Cascade
↓ Oxygen and
Glucose
Na/K ATPase failure ↑ Glutamate ↑ Ca2+
Na influx Activation of proteolytic and ROS
producing enzymes
H2O influx ↑ ROS↑ Proteolysis
Damage of macromolecules
Mitochondrial dysfunctionMitochondrial dysfunction
↓ ATP Respiratory chain
leakage
↓ Glutamate
reuptake
↓ ATP
DepolarizationDepolarization
Necrosis
Apoptosis according
to level of damage
Cytotoxic edema
NEURONS - Core NEURONS - Penumbra
Excitotoxicity
Inflammation
ROS–reactieveoxygenspecies
↑ Pro-inflammatory
cytokines
Role of Inflammation in Ischemic Cascade
Neuronal damage
Mikcoglia, astrocytes Endothelial cell
↑ Pro-inflammatory
cytokines
↑ Adhesive
molecules
Neutrophil and macrophage
infiltration
↑ Proteolytic
enzymes
Endothelial cell
death
Blood – Brain barrier
disruption
Vasogenic Edema
Tissue damage Ischemia
↑ ROS
ROS
Mechanisms of Ischemic Damage
Excitotoxicity
Accumulation of excitatory neurotransmiters
in extracellular space
• Glutamate
• Aspartate
Neuronal dmage due to excessive
stimulation
Cause
• Depolarization
• Decreased reupteke
Consequence
• Stimulation of adjacent neurons
• Ca overload
• Proteolysis
• Excessive ROS production
• Cytotoxic edema www.nature.com
Mechanisms of Ischemic Damage
Reactive oxygen species (ROS)
ROS are highly reactive particles
ROS are mainlu produced during reperfusion
Cause
• Intracellular
✓ Respiratory chain leakage
❖Disruption of electron transport chains in mitochindria
✓ Ca – overload – activation of ROS producing enzymes
• Extracellular
✓ Inflammation
Consequence
• Lipid peroxidation – damage of membranes
• Protein oxidation – damage of enzymes and structural proteins
• Oxidation of purin a pyrimidine bases – damage of DNA
• Stimulation of inflammatory response
Mechanisms of Ischemic Damage
Inflammation
Cause
• Ischemia and tissue damage trigger production of
✓Pro – inflammatory cytokines – activation of leukocytes in
periphery
✓Adhessive molecules – attraction of leukocytes to dmaaged area
• Infiltrating leukocytes produce
✓Proteolytic enzymes – penetration through tissue
✓Pro – infl. Cytokines
✓ROS
Consequence
• Damage of
✓Endothelial cells
✓Blood – Brain barrier
✓Neuronal cells
http://3.bp.blogspot.com
Ischemic Cascade - Summary
Core of infarction
• Energetical failure of the cell
• Membrane failure
• Cytotoxic e´dema
✓ Necrosis
Penumbra
▪ Excitotoxicity
▪ ROS
▪ Damage of cellular macromolecules
▪ Inflammation
✓ Apoptosis potentialy
Hemorrhagic Stroke
Intracerebral hematoma (ICH)
Bleeding into the brain parenchyma (intraaxial)
The most often localization
• Basal ganglia
• Thalamus
http://umm.edu
Pathophysiology of ICH
Hematoma
InflammationCytotoxic blood componentsMass effect
↑ ICPMechanical
damage of brain
parenchyma
Complement
Etc.
Hemoglobin ↑ Pro – infl.
cytokines
Transient ischemia Fe 2+ ↑ Proteolytic
enzymes
↑ ROSInflammation Excitotoxicity ↑ ROS
↑ ROS
(Neurons)
↑ Proteolysis
(Neurons)
Endothelial cell death Blood - Brain barrier
disruption
Neuronal cell death Edema
Hemorrhagic Stroke
Subarachnoid Hemorrhage (SAH)
Bleeding into the subarachnoid space (extraaxial)
The most often cause – cerebral aneurysm rupture
The most often localiztion of aneurysm - Willis circle
van Gijn J, Rinkel GJ. Subarachnoid haemorrhage: diagnosis, causes
and management. Brain.2001;124:249–278.
http://chicago.medicine.uic.edu
Pathophysiology of SAH
Accumulation of blood in subarachnoid space
InflammationCytotoxic blood componentsMass effect
↑ ICP Complement
Etc.
Hemoglobin ↑ Pro – Infl.
cytokines
Transient Ischemia Fe 2+ ↑ Proteolytic
enzymes
↑ ROSInflammation Excitotoxicitÿ ↑ ROS
↑ ROS
(Neurons)
↑ Proteolysis
(Neurons)
Endothelial cell death Blood – Brain barrier
disruption
Neuronal cell death Edema
Cerebral vasospasm
Stroke - Summary
Primary injury
• Ischemia
• Hemorrhage (mechanical damage of brain parenchyma)
Secondary injury
Cause
• Totxicity (excito- , cyto-)
• ROS
• Inflammation
Consequence
➢ Neuronal cell death
➢ Vasospasm
➢ Edema
✓ Ischemia
Intracranial Pressure and Cerebral Perfusion Pressure
Brain is enclosed in the skull…
… an advantage before trouble occurs…
… big problem after trouble occurs.
Intracranial pressure (ICP) is pressure inside
the skull
Intracranial compartments
• Brain
• Cerebrospinal fluid (CSF)
• Blood
Cerebral perfusion pressure
• The pressure gradient through which blood flows to the brain
CPP = MAP - ICPCPP = MAP - ICP
Cerebral perfusion pressure
Mean arterial pressure
Intracranial pressure
http://ars.els-cdn.com
Causes of Intracranial Hypertension
Brain compartment
• Edema
• Tumor
• Hemorrhage
• Infection
CSF compartment
• Hydrocephalus
Compartment of blood
• Venous sinus thrombosis
• Acidosis - ischemia
Causes of Intracranial Hypertension
Brain Edema
Cytotoxic (intracellular)
• Na/K ATPase failure
• Na or Ca influx
• H2O
• Mainly occurs in first 24 h. following insult
Vazogenic (extracellular)
• Damage of endothelial cells and Blood – Brain
barrier
• Extravasation of proteins and electrolytes into
Interstitial space
• Mainly occurs at 24 h. after insult and later
Interstitial
• Obstruction of CSF circulation
• Mechanical damage of CSF- brain barrier
• Infiltration of CSF into intersticial space
Causes of Intracranial Hypertension
Hydrocephalus
Abnormal accumulation of CSF in liquor space
CSF production
• Choroid plexus (CP)
• 450-750 ml/day
CSF resorption
• Archnoid granulations (AG)
Hydrocephalus
• Obstructive (Non- communicating)
✓Impaired CSF circulation due to obstruction
✓For example: ventricular obstruction
• Non – obstructive (Communicating)
✓Impaired CSF resorption
Acute X Chronic
http://www.control.tfe.umu.se
CP
AG
Causes of Intracranial Hypertension
Hydrocephalus
http://drugline.org
Compression
of adjacent tissue
Infratentorial lesions
• Allvays acute
• Risk of brain
• stem compression
Cerebral herniation
• Subfalcine
• Transtentorial
• Tonsillar
• Central
✓ Permanent damage of brain
✓ Risk of brain stem compression
Consequences of Intracranial Hypertension
http://slideshare.net
http://edutoolanatomy.wikispaces.com
Central Herniation
Traumatic Brain Injury
Traumatic Brain Injury
Introduction
The most often causes
• Traffic accidents
• Falls
• Sport injuries
Classificarion
• Primary
✓ Results from trauma…
• Sekundární
✓ Results from reactions
initiated by trauma
• Focal
• Difuse
http://www.seattlecaraccidentlawyerblog.com
Primary Brain Injury
Mechanism of production
• Contact injury
✓Head hits the object or head is hited by the object
✓Risk skull fracture
❖Impressive – small objects
❖Linear – big objects
✓Gunshot injury
➢ Par coup injury
✓ Contusion close to impact site
➢ Par contre coup
• Contusion opposite to impact site
• Noncontact injury
• Acceleration – deceleration injury
http://www.yalescientific.org
Focal injury
Contusion
• Mechanical damage of brain tissue, pia – arachnoid
membranes not damaged
• Smoot transition between contusion and ICH
• The most often localizations
✓Frontal lobe
✓Temporal lobe
Laceration
• The most severe grade of contusion
• Mechanical damage of both brain tissue
and pia-arachnoid membranes
• Contusion + traumatic subarachnoid (subdural)
hemorrhage
Diffuse Brain Injury
Diffuse axonal injury
• Structural damage of axons (white matter)
• Acceleration – deceleration, rotational forces
• No macroscopically detectable pathology
• Microscopicly detectable axonal swelling
• Wallerian degeneration develops later
✓Degeneration of axon distally to injury
✓No axonal regeneration inCNS
Concussion
• The mildest grade of diffuse axonal injury
• No structural tissue damage
• Transient functional damage (loss of consciousness not
longer than 10 minutes)
http://www.givengain.com
Secondary Brain Injury
Edema
• Cytotoxic
• Vasogenic
Ischemia
Brain swelling
• Causes
✓ Acidosis - vasodilatation
✓ Diffuse microvascular injury
➢ Vascular autoregulation failure
✓ Damage brain areas responsible for vasoregulation
➢ Thalamus, brain stem
➢ Vasoparalysis
Secondary injury results in ICP increase
Traumatic Hematomas
Intraaxial
• Intracerebral
Extraaxial
• Epidural
• Subdural
• Subarachnoid
www2.aofoundation.org
http://cs.wikipedia.org
Intracerebral Hemorrhage
➢ Smoot transition between contusion and ICH
according to sverity of injury
The most often localization
• Temporal lobe
• Frontal lobe
Epidural Hematoma
➢ Blood collection between the skull and dura mater
➢ The most often cause is skull fracture, which leads to damage of
meningeal artery (contact injury)
➢ Separation of dura from the skull – convex shape
The most often localization
• Temporo - basal
• Temporo - parietal
Subdural Hematoma
➢ Blood collection between dura mater and arachnoidea
➢ The most often results from tears in briding veins which cross subdural
space (acceleration – deceleration injury)
Acute – fresh blood
Chronic – colliquated blood
Traumatic Subarachnoid Hemorrhage
➢ Blood collection between arachnoidea
and pia mater
➢ Often associates with brain laceration
➢ No vasospasm occurs in traumatic SAH
http://cs.wikipedia.org
Consequences of Brain Injury
➢ Impairment of consciousness
➢ Focal neurological deficit
Impairment of Consciousness
Qualitative
➢ Normal vigility, impairment of content
• Disorientation
Quantitative
➢ Impairment od vigility
• Somnolence – state of near-sleep, responsivnes
• Stupor – responsivness only to base stimuli (pain)
• Coma - unresponsivness
Glasgow Coma Scale
Best eye opening Best verbal Best motor
1 - None 1 - None 1 - None
2 – To pain 2 - Incomprehensible 2 – Extensor (decerebrate)
3 – To speech 3 - Inappropriate 3 – Flexion (decorticate)
4 - Spontaneous 4 - Confused 4 – Withdraws to pain
5 - Oriented 5 – Localizes pain
6 - Obeys
Focal Neurological Deficit
http://www.modernfamilyideas.com
Focal Neurological Deficit
http://www.emunix.emich.edu
Focal Neurological Deficit
http://www.ims.uni-stuttgart.de
Focal Neurological Deficit
Examples of Ishcemia
Arteria cerebri anterior
✓ Contralateral hemiparesis accentes on lower limb (FL)
✓ Behavioral impairment- billateral oclusion (FL)
Arteria cerebri media
✓ Contralateral hemiparesis accentes on upper limb (FL)
✓ Impairment of speech functions – left side occlusion (FL, TL)
✓ Impairment of writing, counting, right – left orientation (TL)
✓ Impairment of spatial orientation when non-dominant parietal
lobe affected
Arteria cerebri posterior
✓ Impairment of vision (OL)
✓ Poruchy čtení (Corpus callosum, PL)
Vertebrobazilární povodí
✓ Mozečková symptomatologie
✓ Brain stem symptomatology
✓ Vertigo, nystagmus, diplopia, bilateral hemiaresis, paresis of cranial nerves
respiratory disorders
Spinal Cord Injury
Spinal Cord Injury
The most often causes
• Traffic accidents
• Work and sports injuries
Mechanisms of injury
• Extensive Flection, extension or rotation
• Direct impact
Back injury
• Vertebrae
✓ Fracture
✓ Dislocation
• Ligaments
• Intervertebral disc
Spinal cord injury
• Streetch
• Pressure
The most often localization of injury C4-C6 a Th11-L2
www.bodyinmotion.co.uk
Spinal Cord Injury
Commotion
• Transient functional disability
• Reversible
Contusion
• Incomplete spinal cord injury
• Complete spinal cord injury
✓ Phase 1 – spinal shock
❖Areflexia and loss of descending facilitation distally from injury
❖Atony of urinary bladder detrusor with retention of urine and
ishuria paradoxa
✓ Phase 2 – spinal automatism
❖ Hyperreflexia/spasticity distally from injury, loss voluntary
motoric activity and loss of descending facilitation
❖ Spasticity of urine bladder
Consequences of Spinal Cord Injury
Paralysis
➢ Loss of muscle function most often caused by damage of nervous system
Plegia
• Total paralysis
Paresis
• Partial paralysis
• Mono-, di-, quadru-, para-, hemi•
Central
✓Loss of upper motor neuron
✓First flaccid
❖Spinal shock
✓Then spastic
❖Activity of lower motor neuron
• Peripheral
✓Loss of lower motor neuron
✓Flaccid
http://medical-dictionary.thefreedictionary.com
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