Figure 3.
Adaptation in response to intrasaccadic target jump. A, Vertical endpoint of saccades during adaptation trials and postadaptation catch trials. Gray shading indicates SEM for each trial (n = 11 subjects). B, Saccades from two representative subjects. Top row, Primary saccade trajectories of the last three adaptation trials (blue) and the last two catch trials (red). Bottom row, Average primary saccade position in the last 10% of adaptation trials and the catch trials in the same trial range, overlaid on average trajectories to preadaptation control trials to oblique targets at (15°, 2°) (gray) and (15°, 3°) (gray). C, Top, Quantifying trajectory curvature. Each primary saccade trajectory was divided into four segments (four chords), and the slopes of the chords were labeled. Curvature is represented as relative change in slope from initial segment (white; S1) of the saccade to the final segment (black; S4). Bottom, Average preadaptation oblique saccades to each vertical eccentricity. Error bars represent SEM (n = 11). Before adaptation, oblique trials showed no tendency toward curvature (comparison of S2, S3, and S4 slopes with S1, p > 0.2 for all cases). D, During adaptation, S4 became increasingly larger than S1. S4 is significantly greater than S3 during the early, middle, and late 10% adaptation trials (48 trials each) at p = 0.002, p = 0.0003, and p = 0.000003 (1-tailed paired t test). “Late-training catch” refers to the 10 catch trials given during the last one-third of the adaptation block. S4 is significantly greater than S3 in the late-training and posttraining catch trials at p = 0.0002 and p = 0.002, respectively. Error bars represent SEM (n = 11).