Crawford J D, Vilis T
Department of Physiology, University of Western Ontario, London, Canada.
Exp Brain Res. 1993;96(3):443-56. doi: 10.1007/BF00234112.
The neural signals that hold eye position originate in a brainstem structure called the neural integrator, so-called because it is thought to compute these position signals using a process equivalent to mathematical integration. Most previous experiments have assumed that the neural integrator reacts to damage like a single mathematical integrator: the eye is expected to drift towards a unique resting point at a simple exponential rate dependent on current eye position. Physiologically, this would require a neural network with uniformly distributed internal connections. However, Cannon et al. (1983) proposed a more robust modular internal configuration, with dense local connections and sparse remote connections, computationally equivalent to a parallel array of independent sub-integrators. Damage to some sub-integrators would not affect function in the others, so that part of the position signal would remain intact, and a more complex pattern of drift would result. We evaluated this parallel integrator hypothesis by recording three-dimensional eye positions in the light and dark from five alert monkeys with partial neural integrator failure. Our previous study showed that injection of the inhibitory gamma aminobutyric acid agonist muscimol into the mesencephalic interstitial nucleus of Cajal (INC) causes almost complete failure of the integrators for vertical and torsional eye position after approximately 30 min. This study examines the more modest initial effects. Several aspects of the initial vertical drift could not be accounted for by the single integrator scheme. First, the eye did not initially drift towards a single resting position; rapid but brief drift was observed towards multiple resting positions. With time after the muscimol injection, this range of stable eye positions progressively narrowed until it eventually approximated a single point. Second, the drift had multiple time constants. Third, multiple regression analysis revealed a significant correlation between drift rate and magnitude of the previous saccade, in addition to a correlation between drift rate and position. This saccade dependence enabled animals to stabilize gaze by making a series of saccades to the same target, each with less post-saccadic drift than its predecessor. These observations were predicted and explained by a model in which each of several parallel integrators generated a fraction of the eye-position command.(ABSTRACT TRUNCATED AT 400 WORDS)
维持眼球位置的神经信号起源于脑干中一个名为神经整合器的结构,之所以这样称呼是因为人们认为它通过一种等同于数学积分的过程来计算这些位置信号。此前的大多数实验都假定神经整合器对损伤的反应类似于单一的数学积分器:预计眼球会以取决于当前眼球位置的简单指数速率朝着一个独特的静止点漂移。从生理角度来看,这需要一个内部连接均匀分布的神经网络。然而,坎农等人(1983年)提出了一种更稳健的模块化内部结构,具有密集的局部连接和稀疏的远程连接,在计算上等同于一组独立子整合器的并行阵列。对一些子整合器的损伤不会影响其他子整合器的功能,这样部分位置信号将保持完整,从而会产生更复杂的漂移模式。我们通过记录五只患有部分神经整合器功能障碍的警觉猴子在明视和暗视条件下的三维眼球位置,来评估这种并行整合器假说。我们之前的研究表明,向中脑 Cajal 间质核(INC)注射抑制性γ-氨基丁酸激动剂蝇蕈醇,大约30分钟后会导致垂直和扭转眼球位置的整合器几乎完全失效。本研究考察了更轻微的初始效应。初始垂直漂移的几个方面无法用单一整合器方案来解释。首先,眼球最初并非朝着单一的静止位置漂移;观察到朝着多个静止位置有快速但短暂的漂移。随着蝇蕈醇注射后的时间推移,这个稳定眼球位置的范围逐渐变窄,直到最终接近一个单点。其次,漂移有多个时间常数。第三,多元回归分析显示,除了漂移速率与位置之间的相关性外,漂移速率与前一次扫视的幅度之间也存在显著相关性。这种扫视依赖性使动物能够通过对同一目标进行一系列扫视来稳定注视,每次扫视后的漂移都比前一次小。这些观察结果由一个模型进行了预测和解释,在该模型中,几个并行整合器中的每一个都生成部分眼球位置指令。(摘要截选至400字)
