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Neural Circuitry underlying generation of saccades and pursuit Lab # 1 - Catching a ball - What to expect/ think about. Fixations exclusively on task-relevant objects (see Land chapter) - PowerPoint PPT Presentation
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Neural Circuitry underlying generation of saccades and pursuit
Lab # 1 - Catching a ball
- What to expect/ think about
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1. Fixations exclusively on task-relevant objects (see Land chapter)
2. Eye deal with one object at a time, corresponding to the duration of the manipulation.(Land: object-related actions)
3. Tight linkage between location of gaze and information needed at that moment. (Just-in-time strategy)
Cortical specialization
Brain Circuitry for Saccades
Oculomotor nuclei
V1: striate cortex
Basal ganglia
1. Neural activity related to saccade
2. Microstimulation generates saccade
3. Lesions impair saccade
target selection
signals to muscles
inhibits SC
saccade decision
saccade command
monitor/plan movements
Function of Different Areas
Superior colliculus
Frontal eye fields
Voluntary controlof saccades.Selection from multiple targetsRelates to behavioral goals.
-Saccades/Smooth Pursuit
-Planning/ Error Checking
-relates to behavioral goals
Supplementary eye fields
LIP: Lateral Intra-parietal AreaTarget selection for saccades: cells fire before saccade to
attended object
Posterior Parietal Cortex
reaching
grasping
Intra-Parietal Sulcus: areaof multi-sensory convergence
Smooth pursuit& Supplementary
Brain Circuitry for Pursuit
Smooth pursuit& Supplementary
Brain Circuitry for Pursuit
Velocity signal
Early motion analysis
How do we use our eyes to catch balls?What information the the brain need?
Neurophysiological experiments look at singlemovements in response to flashes of light.
Eye movements in cricket:
Batsman anticipate bounce point
Better batsman arrive earlier
Land & MacLeod, 2001
pursuitsaccade
Photoreceptors ganglion cells LGN
Primary visual cortex other cortical areas
mid-brain brain stem muscles
Why are eye movements predictive?
Analysis of visual signals takes a lot of time!
Round trip from eye to brain to muscles takes a minumumof 200 msec. Cricket ball only takes about 600 msec.Prediction gets around the problem of sensory delays.
Is prediction seen in cricket a general property of behavior, or onlyseen in skilled performance like cricket or baseball?
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Catching: Gaze Patterns
CatcherThrower
saccade X
X
smooth pursuit
X
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Unexpected bounce leads to poor performance, particularly in the
pursuit movement after the bounce.
Implications of this?
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After three trials, pursuit has improved a lot.
Implications of this?
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Different pattern of eye movements when watching (earlier, no pursuit).
Implications of this?
CatcherThrower
saccade
X
X
Gaze Patterns Different when Watching
X
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Throwing
saccade
catcherthrower
-440 ms
-330 ms
X
X
1.Dustin Banks
2.Jaclyn Roix3.Richard Besemer4.David Rodriguez5.Travis Mckinney6.Camille Gavin 7.Masayuki Inata8.Kyle Pieper9.James Campbell 10.Adam Conner11.Brenda Alarcon
Lab groups
1. What are the questions?• Is the behavior observed by Land in cricket also true for a simple
task like catching a ball?• What eye movements are made in this case?• Do subjects anticipate the bounce point? By how much? Does it
correlate with performance?• Do Subjects look at floor or above the bounce point?• What happens after bounce? • How do subjects adjust to different balls?• …..• Is there a difference between throwing and catching? Why?• What eye movements are made when observing others throw and catch?• What head movements are made? Do they anticipate the action?• Similarity between individuals? • When do the hands start to move?
• 2. Choice of task:• Catching and throwing a ball.
• 3. Procedure:• Select subject and calibrate eye tracker. Three people stand at equal
distances apart and throw the ball back and forth, with a bounce in the trajectory. Need to measure this distance.
• First throw in a predictable manner, about 8 times.• Then use a different ball, 8 trials.• Other balls…• Compare one versus two eyes???
2. Data analysis• Label your tape. Play it frame-by-frame on the VCR in the lab. • ….
• What to look for:– Describe eye movements sequence for each trial
• eg Trial 1: fixate near hands/saccade to bounce point/fixate/track portion of trajectory/fixate for last part of trajectory (??)
• Trial 2: fixate near hands/saccade to bounce point/fixate/track portion of trajectory/fixate for last part of trajectory (??)
• ….• B How regular is the sequence of movements?• C What is the timing of the saccades/fixations/tracking relative to
movement of the ball. How much do subjects anticipate the bounce point, if at all?
• D. How accurate are fixations near the bounce point? (Need to measure visual angle.)
– Compare different conditions.– What happens with the different balls? Do the eye movements change
with additional experience? How quickly do they adjust?
• Other Aspects:– Compare timing of eye and head movements?– When do hands start to move, relative to release of ball?– How similar are different individuals? Where would we expect
similarities/ differences?
• What is the role of the pursuit movement? If pursuit is made only on final bounce, implies pursuit is used to guide hands. Maybe position of eye in head.
• Binocular information versus monocular (looming)