KIN 255 - Cumulated Notes PDF

Summary

These notes cover the nervous system, including its structure and function. They detail CNS and PNS components, sensory receptors, stimulus-evoked responses, and reflex actions, providing a general understanding of neurophysiology. The document is organized by modules and includes various concepts related to nerve pathways and responses within the body.

Full Transcript

LECTURE I INTRODUCTION TO THE NERVOUS SYSTEM

TheCNSintegrates stimulus transmitsmotorresponse
NSmadeupof 50 neurons 50 glialcells
Glialcells ProvideSupport Suppliesnutrients 02 insulates neurons cleandebris
Oligodendrocytes CNS SchwannCells PNS

ÉtSy pticPotential Gradedelectrochemical responseconvergesat axonhillock integration
ActionPotential AP All ornothingelectrochemicalresponsedueto changes in membranepotentialdue to ionPermeability

Greyversuswhitemattermm
GreyMatter bodies
Groupsof cell bodiesdendrites terminalendings jangi pts
nuclei cns
Site of integration and transformation
WhiteMatter
Bundleofmyelinatedaxon
Pathways connecting areas ofgreymatter
foundat difflevels of nervoussystem brain grayoutsidewhiteinside spinalcord whiteoutsidegreyinside

ain Components of the NS
utralnervoussystemCcns
SpinalCord brainstem within skeleton
Brain divided into hindbrain midbrain forebrain
PeripheralNervous system PNS
Outsideskeleton
Dividedintosomatic skeletalmuscle autonomic organssmoothmuscle glands Enteric GI tractbloodflow
AutonomicNervous systemdividedinto sympathetic NS fightorflight ParasympatheticNS rest digest

msfa.tn ftreaEsEndingto brain agent descendingfrombrain esserent
Entry exit to fromPNS

CNScomponentiBrainsteman
referstoPonsmedulla hindbrain
Collectively midbrain
Contains 12 Cranial nerves innervating eyeshead neck uppertrunk
criticalto autonomicfunction alertness eye headmovements

t.iiiiii.EE it
10 ofbrain size yetcontains 50 ofbrains neurons
containsdenseafferent efferentconnections w brainstem cortex
wrigefit.EEiiEEinatamusa
Contributes to the control
descendingmotortracts

of movementlearning cognition emotions
Gangliadespitebeing in CNS

utanCNScompuonentsThalamus Hypothalamose
Thalamus
Relay area between cortexandCNS
Plays a role in alertness
Essential to sensorimotor Processing exceptsmell
Hypothalamus
Contributes tocontrol
ofinternalbodyfunctions homeostasis
Linksnervoussystem endocrinesystem

Igtgsupercerebratarten decision making
Responsible for higherorderthinking behaviour executivepig s S's
Action Control bodymovement eye movement speech
Occipital lobe
Receives visualinput
Procte's's'estiour Penitimenton
motion
Parietallobe
Receives Processes sensory information relatingtouch taste
ReceivesProcessed visual auditoryinfo from occipital temporalcortices
Integrates info from senses for objectperception motorcontrol
Temporal lobe
Receives raw auditoryinputfromthalamus earlyProcessingofSound
Storage retreival of memories
Combinesvisual
info intoobjectPerceptions Vision Thalamus Occipital Parietal
EmotionProcessing groupingofobjects Audio Thalamus temporal Parietal
Amygdala hippocampus contributesto memorystorage
Brodmann Area
Region of Cortexgrouped byCytoarchitecture mirrorsfunctioncreating link betweenBrodmann area
functional Cortextaxonomy
Primary vs Secondary vs Association Cortex
Primary Firstarrival ofsensory input or laststop for motoroutput
Secondary ReceivesProcessed information
AssociationArea Secondary reflects integration ofinformation
 LECTURE 2 SENSORY RECEPTORS

or cell endings that convert stimulus to electricalPotentials
that can be transmitted and interpreted by nervous system
Mechanoreceptors Convertmechanical energy
Photoreceptors Converts lightenergy
Chemoreceptors Converts chemical energy
Thermoreceptors converts thermal energy
Mechanism stimulus energy leads to change in electrochemicalstate j e

Receptor can represent stimulus by h
Type of stimulus digg sensory diss type stimulus
Onset offset duration of stimulus receptoractivity depends on Presence of stimul
i
Intensity of the stimulus adjusting howmany action potentials are triggered Perunittime
Location ofstimulus

Stimulus Modality
Toothictiorption changeto external or internal state of the body
Movement Proprioception Sense of bodies position
Orientation equilibrioception sense of movement Position in relation to gravity
Hearing audioception sense of environment from sound waves
sight opthalmoception Sense of objects from visible light
smell olfacoception chemical odorants in nasal cavity
Taste gustaoception substances chemically react in mouth
Pain nociception Pain due to injury damage
Somatosensory any Mechanoreceptor thermoreceptor or nociceptor in skin
fatty tissue beneath Skin Muscle or Msk tissue Lig tendon joint Capsule
Vestibular Mechanoreceptors within labyrinths of inner ear
visual Photoreceptors located in retina
Auditory Mechanoreceptors in cochlea
propertiesofPotenti
fshtefinfsdstf.nunge
fÉffIeswdptingeetf
Vigorous but transient response to changes in stimulus energy
Optimal to detect rate ofchange in stimulus energyintensity
Slow adapting
Measured but sustained response while stimulus energy is constant
Reflects actual stimulus energyintensity
Photoreceptors
AbsorbPhotons from lightwavelength leading to chemical reaction thatgenerates receptor
potential
Pigment absorbs light Initiates second messengerpathways that closes Natchannels
decreasing amp of receptor potential less neurotransmitter is released when receptorpoten
reaches end of receptor
Do not directly inShence Sensory nerve acts via intermediary bipolarcell
 MODULE 3 CENTRAL AND PERIPHERAL AFFERENT PATHWAYS

IEFffffffaffenftnff.fr
Amount of insulation around the
eaves cars depends on
Prevents
axon of afferent neuron
ions from
leaking out of axonmyelin sheath
Diameter of the axon of aggerent neuron Largerdiameterprovides room for axons to
flow
Proprioceptive afferent neurons are the quickest transmitters of afferent information

EÉtÉÉÉ
to
tjgfatter region for sensory system eventually converges in associatio
areas generate action

Divergence Same inputseparates disperses to multiplelocations
Convergence Multiple inputsproject to commonlocation
Topographic orderedProjection of a sensory Surface retina or skin within nuclei neuron
in CNS foundthroughout all levels in CNS
Ipsilateral belonging to or occurring on same side the body of
contralateral belonging to or occurring on opposite side of the body

ff.tn Eprojects to two ParallelPathways
Geniculostriate visual System 90 of fibers
Primary visual Pathway
Retina Lateralgeniculate LGN thalamic nucleus
Primary visual VI cortex
Tectopulvinar Visual system110 of fibers
Secondary VisualPathway
Retina Superiorcollious midbrain Pulvinar nucleus of thalamus
Information from contralateral visual field cross midlineat optic chiasm
Lefthemigield Rightthalamus v2 Right hemigield Leftthalamus v1
V1 is mirror of visualenvironment
Lesionog right optic nerve assets Épin it
strategies
right side
Lesion of optic chiasm results in loss ofPeripheral view tunnel vision
niai.mucsn88aegst visual space
Iysotinffh.tn tficti tm Ytws
Dorsal stream relate visual environmket 7858 dnyÉ'vision for action where or How
ventral stream emphasize objecting.gg vision for perception what
in fmaesmsifysgstImh

Prosopagnosia inabilityto recognizefaces is associated with damage to ventralvisual Pathway
 axons formingvestibular nerve ccnviiiiriiijpto.ge ss
It L is if in Ia.iemibntiuclear complex

Somatosensoryme
In somatosensory system mechanoreceptors are specialized cells that project to
an afferent neuron or are part of the afferent neuron itself
somatosensory nerves exceptfromhead enter spinal cord via dorsal horn
Nerves from headformtrigeminal nerve CN V
Somatosensory nerves layertoform the ascendingPathways but also have many
divergentprojections in spinal cord to help facilitate reflexes coordination among
muscle groups
Cell bodies of sensory neurons are outside spinalcord in dorsal rootganglion

Nerve bundles in PosteriorColumnPathwayConveyfine touch Vibration
proprioceptive afferentinfo
Third order neuron Axon that project fromthalamic nuclei to
Primary somatosensory cortex
Second order neuron axon that crosses bodymidline in medulla
Projects to thalamic nuclei
First order neuron Axon that Projects from receptor to medulla
AnteriorSpinothalamic tract Anterior medial Crude Poorly
localized information about touch
LateralSpinothalamic tract Information about noxious stimuli
temperature
Dorsal spinocerebellar tract IDSCT Projects to the inferior
peduncle of cerebellum
Proprioceptive info from lower limbs spindle fibers via
afferent neurons
Rostral spinocerebellar tract RSCT Projects to the inferior
Peduncle
of cerebellum
Proprioceptive info from upper limbs
Ventral spinocerebellar tract VSCTI Projects to the superior
Peduncle of the cerebellum
Proprioceptive info from lower limbs Golgitendon organs via Ib
aggerent neurons
 MODULE 4 STIMULUS EVOKED RESPONSES AND SIMPLE REFLEXES

Stimulus evoked behaviour involuntary automatic immediate consequence of
stimulation
Stimulus driven stimulus defines the characteristics of response
Stimulus released Characteristics of response can be independent of some
stimulus Characteristics
Many are examples of reflexes Produced as direct automatic relativelyimmediat
response to stimulation
ways to measure differentelements of the stimulus responsetransformation
Behavioral measures of the stimulus responseProcess timingaccuracy stimulus
response characteristic response modifiability
Electrophysiology assessment of the stimulus response pathways H reflex evoke
Potentials brain hemodynamics non invasive brain stimulation

Timing
Tapsedtime between diggpoints of stimulus to response
process provides info about each specific partof the
process
conduction time time it takes to conduct
signal along
axon Pathways
Synapse time time it takes for info to be exchangedby
neurons processing time
Reaction time time btw stim onset motor system response latency orpremoto
Movement time btw onset of motor system response and movement outcome
Response time Reaction time movement time btw stim movement outcome

4f
ffffgngreactiontimem. n
More choices longer reaction time Hicks law logarythmic relationship
I
keep it simplestupid kiss principle
Simple reaction time one stimulus one response
Choice reaction time one stimulus multipleresponses
stimulus response compatibility
R T is quicker the closer stimulus is in relation to response
stimulusmodality
Stimulus modalities takes diff amount of time to be identified and associated w
reaction
stimulus intensity predictability
More intense stimuli quicker response time
knowing when response is required leads to quickerresponse Preloaded response
tEsgPÉh fnapsesdirectly wt motor
Extragosal fibers
neuron one
synapse
contractile
ex stretch reflex
responsible forgenerating force
Intragosal specialized muscle spindlefibers that detectstretch
More extragusal fibers than in tragusal afferent nerves diverge to act on
motorneurons innervating multiple extragusal fibers
many
requires Coordinated action w agesftp.psyneygifkp mono synaptic antagonist disynaptic
Homonymous reflex pathway HORP Afferent excitation of sensory neuron excite motor
neuron projecting back to same muscle
Heteronymous reflexPathway HERP afferent excitation of sensory neuron excites inhibits
motor neuron projecting to diff muscle
Alphamotor neurons Innervate extragusalfibers to shorten Ap or lengthen AP
Gammamotor neurons specialsegments at the end of Intragusal fiber to keeptaught
as muscle Contracts Pulls ion Channels open to generate receptorpotential Fusimotordrive
Musclespindle fibers gamma motor neuron fusimotor system
Alpha gamma coactivation Coordinated action during muscle contraction
Tonic or fusimotor bias Increase in spindle fibre tension due to alpha motorCoactivation
during contraction
Modification of stimulus responserelationship
Changestogamma motor neuron activity changesspindlereceptorsensitivity alters tautness
ofspindle samestretchresults in weaker afferent response
Inhibitthe reflex decreasesstrengthof the effectofsensoryafferenton motor neuron gai
Facilitatethereflex increasethe gain at the sensory to motor synapsel

MODULE 4 STIMULUS EVOKED BEHAVIOUR

WEEhys.IE ltorolto assess the stimulus response characteristic of myotatic
reflexpathways
stimulatingthe nerve rather than mechanicallystretching the muscle removesinfluence
ofspindlefiberProvides a controlled inputto study stim response relationship
Amplitude is sensitive to intensitystimulus
Hreflex motor response
byelectricalstimulus on afferentsensory nerve
M wave Motor response
byelectrical stimulus on efferentmotor nerve
Inversemyotaticreglexen
AKA Golgitendon organ GTO reflex
strong excitationof lb aggerentdue to extreme muscle tension overrides the alpha
motor neuron excitation of the muscle
Initial inverse myotaticreflex done w muscle at rest alpha motor neuron inhibition
however excitation of Ib afferent nerve actually facilitates alpha motor neuron
excitation
agegptep.in hgeFEires ipsilateral contralateral
muscle coordination
stimulus initiates pain receptors sensory neuron activatesmultiple
Interneurons Ipsilateral motor neurons toflexorexcited ipsilateral flexor
Contracts Contralateral mn to extensor excited extension of
leg
Eye Movements
Fovea is the portionof retina w highestdensity of cone photoreceptor responsible for
high visual acuity
Visual axis straightPath frompointoffixation to fovea changes
optical axis straightlinepassingthrough center of lens
Direction of Gaze directionof visual axis relative to environment
Gaze angle angular measurement ofdirection ofgaze in horizontal or verticalplane
Effectors
extraocular muscles controlhorizontalvertical rotational movement of
the
eye
Abducens nerve V1 Lateral rectus
Oculomotor nerve 111 Medial rectus Superior rectus inferior rectus
Inferioroblique
Trochlear nerve IV Superioroblique
Classification of movements
Conjugate or version Coordinatedeye movement in same direction
through same angle
Disconjugate or vergence coordinated
eye movement in opposite
directions throughmirrored angles
Classes
Vestibulo ocularreflex stabilizes
gaze in responseto headrotation
Optokinetic reflex Combination of slow fast eye movement to
keepmoving scene stationary
Saccades Rapid ballistic
eye movementchangingPointof fixation
SmoothPursuit eye movements that keeps eyes fixated on movingobject
vergence Coordinated disconjugated movement of botheyes to obtain or
Maintain binocular vision
vestibulo ocular reflex VOR
Rapidcompensatory eye movements to stabilize direction of the gaze
Controlled by nuclei in the brain stene
Eyes rotate to oppositedirection of head cancelling out velocity no
InputHeadrotation vestibular nerve output extraocularmuscleactivity
abducens oculomotor trochlear nerves Afterabducens
Agonistmuscle s leftmedialrectus via oculomotornucleus rightlateral rectus
via abducensnuclei
Antagonistmuscles excitatoryafferentinputexcitesinhibitoryinterneurons to
relax left lateral rectus rightmedial rectus
 Saccades
Rapid movement 900 or 75mph of eyes in samedirection a involvesuperietangdentalcortices
exogenously driven bysomethingoutsidethebody endogenouslydriven
Input retina output oculomotornuclei
Exogenously driven
Express saccade bypassescortex 70 100ms
Prosaccades reflex saccades traversestheCortes longerroutethroughvisual Cortex 150 200ms

Endogenously driven
Predictive saccade stimulusexpected but not yet occurring
memory guidedsaccade stimulus was located but not anymore
Anti Saccade oppositedirection inhibition of reflex
saccade sequence fixate on a series ofPoints in space learned

MODULE G MODULATION OF STIMULUS EVOKED BEHAVIOUR

i
iEEet 1gtgt ttPEI.IE g net
s inhibitory
g
multiple separate synapses be can
Temporal summation Aggregation ofmultiplePost synapticPotentials
occurring close in time

weather.tt toEexcitatoryNT
GABA mostcommon inhibitory NT
Glycine inhibitory NT in spinalcord
Acetylcholine muscle contraction
Dopamine Serotonin norepinephrine
NT bind to specific sites on receptors ionotropic or to a coupled receptoractivation
2nd
messengersystem metabotropic

netflix.tt fess tendon positive more
Positivecharge opens cat gated ion channels allowing cart to
flow into Post Synaptic neuron
Gagy
Influx of cart signals vesicles holding glutamate excitory NT to
release content synapse
Glutamate binds to receptors on ion channels of Post synaptic neuron opening
them upallowing Nat to flow into Post synaptic neuron
Natgenerates excitatory Post SynapticPotential EPSP diffusing down dendrite
If largeenough will initiate actionPotential
 neihehstEimnn
MEE Ij ÉI.it
tsmtktifinternalenv ve
Cast less open fewer vesicles release
likely to glutamate
lessglutamate released fewer receptors on Post Synaptic
ions bound Fewer ion channels open on Post Synapti neuron
fewer ion Channels lead to smaller influx of Nat smaller
EPS P less likely to trigger AP

YEEIaTghthEEnEE E.EEtEttgpresynaptic
neuron Positive
more
Cation channels more likely to open more glutamate released
More glutamate more receptors bound more Post synaptic ion
Channel opened larger influx of Nat
Larger EPSP triggers AP

YEIET.int EEEE i YI
inica ve
ve ct summates tre Nat
we
flowing due glutamate release
to
opposite charges cancel out resulting EPSP lower than it
wouldve been without inhibition
less
likely to trigger AP Is

shff.itfttsfaptic
Macitatigettetpernest more
Positive
thecharge summate w the Nat already flowing from
glutamate release
Resulting EPSP is larger and more likely to be big enouph to
trigger AP

netflix.EE esetfhttfmIsacilitatory neuron comes from
Sensory inputs centripetal Inputs from Primaryagerent or interneurons
mediated by afferent input
Central 1descending centrifugal inputs arise fromhigher Centres cortex cerebell
brain stem

ifeng.it EsEEtonmrepext Plantar flexor
anterior exerts inhibitory influence over soleus conditioned reflex
Tibialis
Pre synapticcentripetalmodulations
Soleus reflex is measured alone controlreflex Plantar flexor
Quadriceps exerts facillitoryinfluence conditioned reflex