Approaching object acceleration differentially affects the predictions of neuronal collision avoidance models.

IF 1.7 4区 工程技术 Q3 COMPUTER SCIENCE, CYBERNETICS Biological Cybernetics Pub Date : 2023-04-01 Epub Date: 2023-04-08 DOI:10.1007/s00422-023-00961-0
Fabrizio Gabbiani, Thomas Preuss, Richard B Dewell
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Abstract

The processing of visual information for collision avoidance has been investigated at the biophysical level in several model systems. In grasshoppers, the (so-called) [Formula: see text] model captures reasonably well the visual processing performed by an identified neuron called the lobular giant movement detector as it tracks approaching objects. Similar phenomenological models have been used to describe either the firing rate or the membrane potential of neurons responsible for visually guided collision avoidance in other animals. Specifically, in goldfish, the [Formula: see text] model has been proposed to describe the Mauthner cell, an identified neuron involved in startle escape responses. In the vinegar fly, a third model was developed for the giant fiber neuron, which triggers last resort escapes immediately before an impending collision. One key property of these models is their prediction that peak neuronal responses occur at a fixed delay after the simulated approaching object reaches a threshold angular size on the retina. This prediction is valid for simulated objects approaching at a constant speed. We tested whether it remains valid when approaching objects accelerate. After characterizing and comparing the models' responses to accelerating and constant speed stimuli, we find that the prediction holds true for the [Formula: see text] and the giant fiber model, but not for the [Formula: see text] model. These results suggest that acceleration in the approach trajectory of an object may help distinguish and further constrain the neuronal computations required for collision avoidance in grasshoppers, fish and vinegar flies.

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接近物体的加速度会对神经元避撞模型的预测产生不同影响。
在几个模型系统中,人们从生物物理层面研究了避免碰撞的视觉信息处理。在蚱蜢中,(所谓的)[公式:见正文]模型很好地捕捉到了被称为小叶巨动探测器的识别神经元在追踪接近物体时所进行的视觉处理。在其他动物中,类似的现象学模型也被用来描述负责视觉引导避撞的神经元的发射率或膜电位。具体来说,在金鱼中,[公式:见正文]模型被用来描述毛特纳细胞,这是一种参与惊吓逃逸反应的神经元。在醋蝇中,第三个模型是针对巨纤维神经元提出的,该神经元在即将发生碰撞前触发最后的逃逸反应。这些模型的一个关键特性是,它们预测神经元的峰值反应会在模拟物体接近视网膜达到阈值角尺寸后的一个固定延迟时间内出现。这一预测对以恒定速度接近的模拟物体有效。我们测试了当接近物体加速时,这一预测是否仍然有效。在分析和比较了模型对加速和匀速刺激的反应后,我们发现[公式:见正文]和巨纤维模型的预测成立,而[公式:见正文]模型则不成立。这些结果表明,物体接近轨迹中的加速度可能有助于区分和进一步限制蚱蜢、鱼和醋蝇避免碰撞所需的神经元计算。
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来源期刊
Biological Cybernetics
Biological Cybernetics 工程技术-计算机:控制论
CiteScore
3.50
自引率
5.30%
发文量
38
审稿时长
6-12 weeks
期刊介绍: Biological Cybernetics is an interdisciplinary medium for theoretical and application-oriented aspects of information processing in organisms, including sensory, motor, cognitive, and ecological phenomena. Topics covered include: mathematical modeling of biological systems; computational, theoretical or engineering studies with relevance for understanding biological information processing; and artificial implementation of biological information processing and self-organizing principles. Under the main aspects of performance and function of systems, emphasis is laid on communication between life sciences and technical/theoretical disciplines.
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