Vestibular System Flashcards
Vestibular System 5 Components
– essential for posture, balance, and movement
o Peripheral receptor apparatus – converts mechanical energy into electrical
Hair cells located in vestibular labyrinth innervated by vestibular nerve (CN8)
o Central vestibular nuclei – primary sensory nuclei for vestibular system
o Vestibulo-thalamo-cortical network – brainstem thalamus cortex (central network)
o Vestibulo-ocular network – via semi-circular canals; involved with dynamic function
o Vestibulospinal network – via efferent muscle control; involved with balance/posture
Vestibular Organization
o 2 components – bony labyrinth and membranous labyrinth
o 2 vestibules each side – detect translational/linear acceleration in horizontal & vertical plane
Utricle – horizontal plane mainly
Saccule – vertical mainly
o 3 semicircular canals (anterior, posterior, horizontal) – detect rotational acceleration in 3-D
o 2 fluids – perilymph (CSF) and endolymph
Hair Cell Characteristics and Innervation
o Hair cells are specialized sensory receptor
o Macula – internal structure of static system that contains specialized sensory hair cells
o Crista ampullaris – internal structure for dynamic system that contains specialized hair cells
o Innervated by peripheral proceses of CN 8 (vestibular division)
o Cell bodies reside in Scarpa’s ganglion
o Receive Efferent innervation from brainstem areas
Otolithic Membrane and Hair Cells
– encapsulates the kinocilia & stereocilia and contains carbonate crystals that prevent non-specific movement; helps detect gravity; and adds extra weight to allow detection of movement changes; ONE kinocilium and many stereocilia
o Type I – circular; contain large afferent nerve fiber that forms a cup around the hair cell
Increases the sensitivity and amplifies the signal
Efferent fiber synapses on the afferent fiber
Located close to the middle of the cupula
o Type II – columnar; contain a smaller afferent nerve terminal
Efferent nerve fiber synapses directly onto the hair cell
Located closer to the edges of the cupula
Transduction Mechanism and Adaptation
o Tip link – “spring like” connection between kinocilium and adjacent stereocilium
Connected to a “trapdoor” of mechanically sensitive K+ ion channel on stereocilia
Movement of stereocilia towards kinocilium pulls open the trapdoor, K+ influx, depolarizing the hair cell
o Adaptive Mechanism – occur during hyper- and depolarization
Sustained depolarization leads to Ca+ channels staying open in stereocilia
As Ca+ increases it causes slippage of the motor protein and tension decreases causing the channel (“trapdoor”) to close; takes 5-10 seconds for slippage to occur
As Ca+ decreases the motor can now retension the spring so that it is ready to detect change again
Static Vestibular Functions
o Detection of linear acceleration (translational motion)
o Vestibulocolic reflexes – vestibular apparatus to motor neurons of neck muscles
o Vestibulospinal reflexes – vestibular apparatus to motor neurons in spinal cord controlling anti-gravity muscles (axial muscles of trunk)
o Maintains postural status quo (detection of head and body orientation)
Keeps head upright on body
Keeps trunk upright & centered over pelvis
Sensory Apparatus for Static Vestibular Functions
o Striola – indentation in the macula structure that divides the saccule/utricle into 2 polarities Polarity flips as you pass the striola so depolarization occurs on one side and hyperpolarization on the other Kinocilia located on the same side of every cell on one side of striola and on opposite side on the other side of the striola Turn head to left left side discharge frequency decreases and right side discharge frequency increase allows brain to interpret head movement from these 2 signals Each side of striola is innervated separated o Spontaneous (constant) firing occurs even when stereocilia is not moving o Stereocilia move towards kinocilia trapdoor opens and hair cells depolarize Mechanism: cilia movement opens mechanosensitive K+ channels K+ enters the hair cell causing depolarization opens voltage-gated Ca+ channels opening of Ca+ dependent K+ channels allows K+ to leave the cell to repolarize the hair cell o Stereocilia move away from kinocilia reflexive loosening of the spring channel is closed hair cell hyperpolarizes
Static Vestibular Signaling Pathway: General
utricle/saccule CN 8 lateral/medial/descending nuclei of primary vestibular nucleus Medial/Lateral vestibulospinal tracts (MVST, LVST)
Some fibers go from CN8 to the flocculonodular cerebellum bypassing the primary vestibular nucleus
Utricle and saccule send afferent fibers that branch to innervate lateral/medial/descending nuclei of primary vestibular nucleus
• Superior nucleus NOT innervated by the static portion of vestibular system
Static Vestibular Signaling Pathway: MVST and LVST
o Lateral Vestibulospinal Tracts (LVST) – descending AND lateral nuclei of primary vestibular nuclei sends signal via Lateral VST to innervate only the ipsilateral side motor neurons
Innervate alpha motor neurons; responsible for body posture
o Medial Vestibulospinal Tracts (MVST) – medial nuclei of primary vestibular nucleus sends signal via Medial VST to innervate both the ipsilateral and contralateral sides
Innervate interneurons and gamma motor neurons; keeps head upright
Dynamic Vestibular Functions
o Detection of angular acceleration – roll, pitch, and yaw
o Detects CHANGE
o Uses semicirucular canals for detection
o Vestibulo-ocular reflex (VOR) – help controlling eye movement
Acts on extrinsic eye muscles through outputs to CN 3,4,6
Causes eye movements that are compensatory to head movements
Reflexively stabilizes the visual field on the retina during movement of the head
Vestibulo-ocular Reflex Pathway
o Detects in semicircular canals vestibular nuclei nuclei of CN 3,4,6
o Axons travel in ascending medial longitudinal fasciculus (MLF)
o Innervate extraocular eye muscles
Semicircular Canals Function
o Detect angular acceleration in any spatial dimension (X, Y, Z)
Vector analysis of activity on the 6 canals computes the position of the head in space
Maximum response in canals which are in parallel planes
• Right anterior canal and left posterior canal
Head must be tilted down at 30 degrees to orient the horizontal canal parallel to ground
• Evolutionarily Derived – look slightly down so we can see where we are walking
o Cristae ampullaris – found within the ampulla of each canal
• Area where the specialized sensory hair cells are embedded
Cupula – gelatinous structure within the ampulla; encapsulates the kino- and stereocilia
• Synonymous with macula in utricle and saccule
• Fluid stays in same position; cupula actually moves when we move
Dynamic Vestibular Signaling Pathway: General
o Semicircular canal (cristae ampullaris hair cell) CN 8 superior/medial and descending vestibular nuclei ascending medial longitudinal fasciculus (MLF) nuclei of CN 3/4/6
Superior medial nuclei – involved when maintaining eye fixture during head movments
Some axons bypass the primary vestibular nucleus and send signal directly to flocculonodular cerebellum
NO INFORMATION BEING SENT TO SPINAL CORD
Afferent fibers from horizontal & anterior canals synapse on the superior and medial nuclei of the primary vestibular nucleus
Afferent fibers from posterior canal branch to innervate superior/medial/descending nuclei of the primary vestibular nucleus
o Complex connections and integrations exist between dynamic nuclei of the 2 hemispheres of the brain; also involves connections from other areas of brain such as cerebellum and spinal cord
o Vestibular Thalamo-cortical Pathway
Dynamic Vestibular Signaling Pathway: Thalamo-cortical
From superior/lateral/descending vestibular nuclei ventral posterolateral nucleus in thalamus area 3a and 2v of postcentral gyrus (relatively small area) in cortex
• Helps us recognize why certain motions are occurring and allows us to have a bit of control as to how we feel at times (ex: car sickness)
Vestibular Deficits (Trauma, schwannoma, cellular composition, vestibular dysfunction)
o Damage to petrous portion of temporal bone may result in vestibular deficits
o Vestibular schwannoma – vestibulocochlear deficits and deficits indicative of potential damage to facial nerve
o Disturbance in the ionic content of endolymph
o Nystagmus – indiciator of vestibular system dysfunction
