Barnes G R, Barnes D M, Chakraborti S R
Medical Research Council Human Movement and Balance Unit, Institute of Neurology, London WC1N 3BG, United Kingdom.
J Neurophysiol. 2000 Nov;84(5):2340-55. doi: 10.1152/jn.2000.84.5.2340.
The link between anticipatory smooth eye movements and prediction in sinusoidal pursuit was investigated by presentation of series of identical, single-cycle, sinusoidal target motion stimuli. Stimuli occurred at randomized intervals (1.2-2.8 s) but were preceded by an audio warning cue 480 ms before each presentation. Cycle period (T) varied from 0.64 to 2.56 s and target displacement from 4 to 20 degrees in separate series. For T </= 1.28 s, responses to the first stimulus of each series exhibited a time delay across the whole cycle (mean = 121 ms for T = 0.8 s). But, in the second and subsequent (steady-state) presentations, anticipatory movements, proportional to target velocity, were made and time delay was significantly reduced (mean = 43 ms for T = 0.8 s). Steady-state time delays were comparable to those evoked during continuous sinusoidal pursuit and less than pursuit reaction time. Even when subjects did not follow the target in the first presentation, they responded to the second presentation with reduced time delay. Throughout the experiments, three types of catch trial (A-C) were introduced. In A, the target failed to appear as expected after the warning cue. Anticipatory smooth movements were initiated, reaching a peak velocity proportional to prior target velocity around 200 ms after expected target onset. In B, the target stopped midway through the cycle. Even if the target remained on and was stationary, the eye movement continued to be driven away from the stationary target with a velocity similar to that of prior responses, reaching a peak velocity that was again proportional to expected target velocity after >/=205 ms. In C, the amplitude of the single sinusoid was unexpectedly increased or decreased. When it decreased, eye velocity throughout the first half-cycle of the response was close to that executed in response to prior stimuli of higher velocity and did not return to an appropriate level for 382-549 ms. Conversely, when amplitude increased, eye velocity remained inappropriately low for the first half-cycle. Results of A and C indicate that subjects are able to use velocity information stored from prior presentations to initiate an oculomotor drive that predominates over visual feedback for the first half-cycle. Results of B indicate that the second part of the cycle is also preprogrammed because it continued despite efforts to suppress it by fixation. The results suggest that initial retinal velocity error information can be sampled, stored, and subsequently replayed as a bi-directional anticipatory pattern of movement that reduces temporal delay and could account for predictive control during sinusoidal pursuit.
通过呈现一系列相同的单周期正弦目标运动刺激,研究了预期性平滑眼动与正弦跟踪中的预测之间的联系。刺激以随机间隔(1.2 - 2.8秒)出现,但在每次呈现前480毫秒会有一个音频警告提示。在不同系列中,周期(T)从0.64秒变化到2.56秒,目标位移从4度到20度。对于T≤1.28秒,每个系列中对第一个刺激的反应在整个周期内都表现出时间延迟(T = 0.8秒时平均为121毫秒)。但是,在第二次及后续(稳态)呈现中,会做出与目标速度成比例的预期运动,并且时间延迟显著减少(T = 0.8秒时平均为43毫秒)。稳态时间延迟与连续正弦跟踪期间诱发的延迟相当,且小于跟踪反应时间。即使受试者在第一次呈现时没有跟踪目标,他们对第二次呈现的反应时间延迟也会减少。在整个实验过程中,引入了三种类型的捕捉试验(A - C)。在A中,警告提示后目标未按预期出现。会启动预期性平滑运动,在预期目标开始后约200毫秒达到与先前目标速度成比例的峰值速度。在B中,目标在周期中途停止。即使目标保持开启且静止,眼动仍会以与先前反应相似的速度继续偏离静止目标,在≥205毫秒后达到再次与预期目标速度成比例的峰值速度。在C中,单个正弦波的幅度意外增加或减小。当幅度减小时,反应前半周期的眼速度接近对先前较高速度刺激所执行的速度,并且在382 - 549毫秒内未恢复到适当水平。相反,当幅度增加时,前半周期的眼速度保持不适当的低水平。A和C的结果表明,受试者能够利用先前呈现中存储的速度信息启动眼动驱动,在前半周期中这种驱动占视觉反馈主导。B的结果表明,周期的第二部分也是预先编程的,因为尽管通过注视努力抑制它,但它仍继续进行。结果表明,初始视网膜速度误差信息可以被采样、存储,随后作为一种双向预期运动模式重新播放,这种模式减少了时间延迟,并可以解释正弦跟踪期间的预测控制。
