05d eye movement control
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Transcript of 05d eye movement control
Visual Tracking and Fixing
Visual Tracking
• Why Visual Tracking ?– To keep the image in the Fovea which is less than 1mm size and
detect visual field of less than diameter of full moon.– It keeps the eye still when the image is still and stabilizes the
image when the object moves in the world or when the head itself
moves.
• How Visual Tracking?– Oculomotor system: moves the eye in the orbit
– Head movement which moves the orbit in the space
– Information of head motion processed by the vestibular system
Three Axes of Eye Rotations
1. Ductions refer to monocular movements of each eye
2. Versions refer to binocular conjugate movements of both eyes
3. Vergences refer to binocular disjunctive movements
Extra Ocular Muscles
Extra-ocular muscles nerve supply
Actions of Extra-ocular muscles
Laws of Ocular Motor Control
1. Sherrington's law of reciprocal innervation
2. Hering's law of equal innervation
Six Cardinal Position
"Visual Accessing Cues"
Richard Bandler and John Grinder "Frogs into Princes: Neuro Linguistic Programming (NLP) "
Up and to the Left Indicates: Visually Constructed Images (Vc)
If you asked someone to "Imagine a purple buffalo", this would be the direction their eyes moved in while thinking about the question as they "Visually Constructed" a purple buffalo in their mind.
Up and to the Right indicates: Visually Remembered Images (Vr)
If you asked someone to "What color was the first house you lived in?", this would be the direction their eyes moved in while thinking about the question as they "Visually Remembered" the color of their childhood home.
To the Left Indicates: Auditory Constructed (Ac)
If you asked someone to "Try and create the highest the sound of the pitch possible in your head", this would be the direction their eyes moved in while thinking about the question as they "Auditorily Constructed" this this sound that they have never heard of.
To the Right Indicates: Auditory Remembered (Ar)
If you asked someone to "Remember what their mother's voice sounds like ", this would be the direction their eyes moved in while thinking about the question as they "AuditorilyRemembered " this sound.
Down and to the Left Indicates: Feeling / Kinesthetic (F)
If you asked someone to "Can you remember the smell of a campfire? ", this would be the direction their eyes moved in while thinking about the question as they used recalled a smell, feeling, or taste.
Down and To the Right Indicates: Internal Dialog (Ai)
This is the direction of someone eyes as they "talk to themselves".
Brain area participate in Visual Fixation
The cerebral structures involved in fixation are:� Parietal eye field (lateral interparietal area and area 7a in monkeys)� V5 and V5A (MT and MST in monkeys)� Supplementary eye field� Dorsolateral prefrontal cortex
The brainstem structures involved in fixation are:� Substantia nigra pars reticulata in the basal ganglia� Rostral pole of the superior colliculus
An Active Fixation System Keeps the Eyes on a Stationary Target
The Visual Fixation System
•The fixation system holds the image of a stationary object on the fovea when the head is immobile. •Steady fixation is actually an illusion. •Normal fixation consists of three distinct types of physiological miniature movements that are not detectable by the naked eye
Type of Eye MovementFunction of Eye Movement
"Version" (Conjugate) "Vergence" (Disjunctive)
"Holding" (slow)•Smooth Pursuit•Optokinetic Nystagmus(slow phase)•Vestibular Nystagmus
•Convergence•Divergence•Accommodative Vergence
"Catching" (fast)•Saccades•Optokinetic Nystagmus(quick phase)
"Sustaining" (miniature) •Microsaccades •Tremor
•Drift
voluntary eye movement; involuntary eye movement
Eye Movement
The Vestibular and Optokinetic Systems
• The vestibulo-ocular and optokinetic reflexes are the
earliest eye movements to appear phylogenetically
• The vestibulo-ocular reflex (VOR) stabilizes retinal
images during head motion by counter-rotating the eyes at
the same speed as the head but in the opposite direction
• Optokinetic eye movements stabilize the eyes during
tracking of a large moving visual scene, which causes an
illusionary sensation of self rotation (circularvection) in the
opposite direction
Types of Head Motion
1. Rotation : A change in orientation2. Translation: A change in position
Characteristics of the VOR
The VOR stabilizes retinal images during brief head movements bycounter-rotating the eyes at the same speed as the head but in theopposite direction
The Horizontal VOR Pathway
The Vertical and Torsional VOR Pathway
The Otolith-Ocular Pathway
VOR Adaptation and the Cerebellum
The Optokinetic System
•Optokinetic nystagmus is induced reflexively by motion of a large visual scene, which causes an illusionary sensation of self-rotation (circularvection) in the opposite direction
•Whereas the angular VOR responds best to brief, high-frequency head rotation, the optokinetic system maintains retinal image stability during sustained, low-frequency rotation
The Saccadic System Points the Fovea Toward Objects of Interest
Saccads during reading
Pulse-Step of Innervation for Saccadic Eye Movement
Extraocular Motor Signal Eye Position and Velocity
Central control of Horizontal Saccad
Brainstem Generation of Vertical and Torsional Saccades
Cortical Pathway for Saccades
Summary of Central Control of Saccades
The Smooth Pursuit System Keeps Moving Targets on the Fovea
Gaze Involves Combined Head and Eye Movements
Cortical control of Pursuit Eye movement
Summary of Central Control of Pursuit Eye Movement
Vergence Eye movment
Neural Substrate of Vergence Eye Movements
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