Straube A, Fuchs A F, Usher S, Robinson F R
Regional Primate Research Center, University of Washington, Seattle 98195, USA.
J Neurophysiol. 1997 Feb;77(2):874-95. doi: 10.1152/jn.1997.77.2.874.
We adapted the saccadic gain (saccadic amplitude/target step amplitude) by requiring monkeys to track a small spot that stepped to one side by 5, 10, or 15 degrees and then, during the initial targeting saccade, jumped either forward or backward by a fixed percentage of the initial step. Saccadic gain increased or decreased, respectively, as a function of the number of adapting saccades made in that direction. The relation between gain and the number of adapting saccades was fit with an exponential function, yielding an asymptotic gain and a rate constant (the number of saccades to achieve 63% of the total change in gain). Backward intrasaccadic target jumps of 15, 30, and 50% of the initial target step reduced the asymptotic gain by an average of 12.2, 23.1, and 36.4%, respectively, with average rate constants of 163, 368, and 827 saccades, respectively. During 50% backward jumps, some saccades, especially those to larger target steps, became slower and lasted longer. Forward intrasaccadic jumps of 30% increased the asymptotic gain by 23.3% (average rate constant of 1,178 saccades). After we had caused adaptation, we induced recovery of gain toward normal by requiring the animal to track target steps without intrasaccadic jumps. Recovery following forward adaptation required about one third fewer saccades than the preceding gain increase. Recovery following backward adaptation required about the same average number of saccades as the preceding gain decrease. The first saccades of recovery were slightly less adapted than the last saccades of adaptation, suggesting that a small part of adaptation might have been strategic. After 50% backward jumps had reduced saccadic gain, the hypometric primary saccades during recovery were followed by hypometric corrective saccades, suggesting that they too had been adapted. When saccades of only one size underwent gain reduction, saccades to target steps of other amplitudes showed much less adaptation. Also, saccades in the direction opposite to that adapted were not adapted. Gain reductions endured if an adapted animal was placed in complete darkness for 20 h. These data indicate that saccadic gain adaptation is relatively specific to the adapted step and does not produce parametric changes of all saccades. Furthermore, adaptation is not a strategy, but involves enduring neuronal reorganization in the brain. We suggest that this paradigm engages mechanisms that determine saccadic gain in real life and therefore offers a reversible means to study their neuronal substrate.
我们通过要求猴子追踪一个向一侧移动5度、10度或15度的小光点来调整扫视增益(扫视幅度/目标步幅),然后在初始目标扫视期间,向前或向后跳跃初始步幅的固定百分比。扫视增益分别根据在该方向上进行的适应性扫视次数而增加或减少。增益与适应性扫视次数之间的关系符合指数函数,得出渐近增益和速率常数(达到增益总变化的63%所需的扫视次数)。初始目标步幅的15%、30%和50%的向后扫视内目标跳跃分别使渐近增益平均降低12.2%、23.1%和36.4%,平均速率常数分别为163、368和827次扫视。在50%向后跳跃期间,一些扫视,尤其是那些针对较大目标步幅的扫视,变得更慢且持续时间更长。30%的向前扫视内跳跃使渐近增益增加23.3%(平均速率常数为1178次扫视)。在我们引起适应性变化后,通过要求动物追踪无扫视内跳跃的目标步幅来诱导增益恢复到正常水平。向前适应性变化后的恢复所需的扫视次数比之前增益增加所需的扫视次数少约三分之一。向后适应性变化后的恢复所需的扫视次数与之前增益降低所需的平均扫视次数大致相同。恢复的第一个扫视比适应性变化的最后一个扫视的适应性略低,这表明适应性变化的一小部分可能是策略性的。在50%向后跳跃降低扫视增益后,恢复期间的欠幅初级扫视之后跟着欠幅校正扫视,这表明它们也发生了适应性变化。当只有一种大小的扫视经历增益降低时,针对其他幅度目标步幅的扫视显示出的适应性变化要少得多。此外,与适应性变化方向相反的扫视没有发生适应性变化。如果将适应后的动物置于完全黑暗中20小时,增益降低会持续存在。这些数据表明,扫视增益适应性相对特定于适应的步幅,不会对所有扫视产生参数变化。此外,适应性变化不是一种策略,而是涉及大脑中持久的神经元重组。我们认为,这种范式涉及在现实生活中决定扫视增益的机制,因此提供了一种可逆的方法来研究其神经元基础。
