Hall Lauren A, Karl Jenni M, Thomas Brittany L, Whishaw Ian Q
Canadian Centre for Behavioural Neuroscience, Department of Neuroscience, University of Lethbridge, Lethbridge, AB, T1K 3M4, Canada.
Exp Brain Res. 2014 Sep;232(9):2807-19. doi: 10.1007/s00221-014-3945-6. Epub 2014 May 4.
The dual visuomotor channel theory proposes that prehension consists of a Reach that transports the hand in relation to an object's extrinsic properties (e.g., location) and a Grasp that shapes the hand to an object's intrinsic properties (e.g., size and shape). In central vision, the Reach and the Grasp are integrated but when an object cannot be seen, the movements can decompose with the Reach first used to locate the object and the Grasp postponed until it is assisted by touch. Reaching for an object in a peripheral visual field is an everyday act, and although it is reported that there are changes in Grasp aperture with target eccentricity, it is not known whether the configuration of the Reach and the Grasp also changes. The present study examined this question by asking participants to reach for food items at 0° or 22.5° and 45° from central gaze. Participants made 15 reaches for a larger round donut ball and a smaller blueberry, and hand movements were analyzed using frame-by-frame video inspection and linear kinematics. Perception of targets was degraded as participants could not identify objects in peripheral vision but did recognize their differential size. The Reach to peripheral targets featured a more dorsal trajectory, a more open hand, and less accurate digit placement. The Grasp featured hand adjustments or target manipulations after contact, which were associated with a prolonged Grasp duration. Thus, Grasps to peripheral vision did not consist only of a simple modification of visually guided reaching but included the addition of somatosensory assistance. The kinematic and behavioral changes argue that proprioception assists the Reach and touch assists the Grasp in peripheral vision, supporting the idea that Reach and Grasp movements are used flexibly in relation to sensory guidance depending upon the salience of target properties.
双视觉运动通道理论提出,抓握动作包括一个与物体外在属性(如位置)相关的手部移动动作(即伸手动作)和一个使手部适应物体内在属性(如大小和形状)的手部塑形动作(即抓握动作)。在中央视觉中,伸手动作和抓握动作是整合在一起的,但当物体不可见时,动作可能会分解,先使用伸手动作来定位物体,抓握动作则推迟到通过触觉辅助时进行。在周边视野中伸手去拿物体是一种日常行为,尽管据报道抓握孔径会随着目标偏心度而变化,但尚不清楚伸手动作和抓握动作的组合是否也会改变。本研究通过要求参与者在距中央注视点0°、22.5°和45°的位置伸手去拿食物来检验这个问题。参与者对一个较大的圆形甜甜圈球和一个较小的蓝莓各进行15次伸手动作,并使用逐帧视频检查和线性运动学分析手部动作。由于参与者无法识别周边视野中的物体,但能识别它们的大小差异,因此目标的感知能力有所下降。伸向周边目标的伸手动作具有更靠背部的轨迹、更张开的手部以及不太准确的手指放置。抓握动作的特点是在接触后进行手部调整或目标操作,这与抓握持续时间延长有关。因此,伸向周边视野的抓握动作不仅包括对视觉引导伸手动作的简单修改,还包括增加了体感辅助。运动学和行为学上的变化表明,本体感觉在外周视野中辅助伸手动作,触觉辅助抓握动作,这支持了这样一种观点,即伸手动作和抓握动作会根据目标属性的显著性,灵活地用于与感觉引导相关的动作中。
