Kimmig H, Biscaldi M, Mutter J, Doerr J P, Fischer B
Neurologische Universitätsklinik Freiburg, Breisacher Str. 64, 79106 Freiburg, Germany.
Exp Brain Res. 2002 Jun;144(3):373-84. doi: 10.1007/s00221-002-1059-z. Epub 2002 Apr 13.
A vast knowledge exists about saccadic reaction times (RT) and their bi- or multimodal distributions with very fast (express) and regular RT. Recently, there has been some evidence that the smooth pursuit system may show a similar RT behavior. Since moving targets usually evoke a combined pursuit/saccade response, we asked which processes influence the initiation of pursuit and saccadic eye movements. Furthermore, we investigated whether and how the pursuit and saccadic system interact during the initiation of eye movements to moving targets. We measured the RT of the initial smooth pursuit (iSP) response and of the first corrective saccade and compared the RT behavior of both. Furthermore we compared the behavior of the corrective saccades to moving targets to that of saccades to stationary targets, known from the literature. The stimulus consisted of a target that moved suddenly at constant velocity (ramp). In addition, prior to the movement, a temporal gap, a position step or a combination of both could occur (gap-ramp, step-ramp, gap-step-ramp, respectively). Differently from most previous studies, we chose step and ramp with the same direction to provoke competition between the pursuit and saccade system. For the first time we investigated pursuit initiation in "express-saccade makers" (ES makers), a subject group known to produce an abnormally high percentage of short-latency saccades in saccade tasks. We compared their results with subject groups who were either naive or trained with respect to saccade tasks. The iSP started at approximately 100 ms, which corresponds to express saccade latencies. These short iSP-RT occurred reflex-like and almost independent of the experimental task. A bimodal frequency distribution of RT with a second peak of longer iSP-RT occurred exclusively in the ramp paradigm. The RT of the first corrective saccades in a pursuit task were comparable with that in a saccade task and depended on the stimulus. The ability of ES makers to produce a high number of express saccades was transferred to corrective saccades in the pursuit task, but not to pursuit initiation. In summary, short-latency pursuit responses differ from express saccades with respect to their independence of experiment and subject group. Therefore, a simple analogy to express saccades cannot be drawn, although some mechanisms seem to act similarly on both the pursuit and the saccade system (such as disengagement of attention with the gap effect). Furthermore, we found evidence that the initial pursuit response and the first corrective saccade are processed independently of each other. The first corrective saccades to moving targets behave like saccades to stationary targets. Normal pursuit but abnormal saccade RT of ES makers can be explained by recent theories of superior colliculus (SC) function in terms of retinal error handling.
关于扫视反应时间(RT)及其具有非常快速(快速)和规则RT的双峰或多峰分布,已有大量知识。最近,有一些证据表明平稳跟踪系统可能表现出类似的RT行为。由于移动目标通常会引发跟踪/扫视的联合反应,我们询问哪些过程会影响跟踪和扫视眼动的启动。此外,我们研究了在眼动启动以跟踪移动目标时,跟踪和扫视系统是否以及如何相互作用。我们测量了初始平稳跟踪(iSP)反应和首次校正扫视的RT,并比较了两者的RT行为。此外,我们将对移动目标的校正扫视行为与文献中已知的对静止目标的扫视行为进行了比较。刺激由一个以恒定速度突然移动(斜坡)的目标组成。此外,在移动之前,可能会出现时间间隙、位置步长或两者的组合(分别为间隙 - 斜坡、步长 - 斜坡、间隙 - 步长 - 斜坡)。与大多数先前的研究不同,我们选择了相同方向的步长和斜坡来引发跟踪和扫视系统之间的竞争。我们首次在“快速扫视者”(ES扫视者)中研究了跟踪启动,这是一个已知在扫视任务中产生异常高比例短潜伏期扫视的受试者组。我们将他们的结果与对扫视任务不熟悉或经过训练的受试者组进行了比较。iSP大约在100毫秒开始,这与快速扫视潜伏期相对应。这些短的iSP - RT像反射一样出现,并且几乎与实验任务无关。RT的双峰频率分布以及较长iSP - RT的第二个峰值仅在斜坡范式中出现。跟踪任务中首次校正扫视的RT与扫视任务中的RT相当,并且取决于刺激。ES扫视者产生大量快速扫视的能力在跟踪任务中转移到了校正扫视上,但没有转移到跟踪启动上。总之,短潜伏期跟踪反应在实验和受试者组的独立性方面与快速扫视不同。因此,尽管一些机制似乎在跟踪和扫视系统上的作用相似(例如通过间隙效应使注意力脱离),但不能简单地与快速扫视进行类比。此外,我们发现证据表明初始跟踪反应和首次校正扫视是相互独立处理的。对移动目标的首次校正扫视的行为类似于对静止目标的扫视。ES扫视者正常的跟踪但异常的扫视RT可以根据上丘(SC)在视网膜误差处理方面的最新理论来解释。
