Neuron arbor geometry is sensitive to the limited-range fractal properties of their dendrites.

Conor Rowland, Julian H Smith, Saba Moslehi, Bruce Harland, John Dalrymple-Alford, Richard P Taylor
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Abstract

Fractal geometry is a well-known model for capturing the multi-scaled complexity of many natural objects. By analyzing three-dimensional images of pyramidal neurons in the rat hippocampus CA1 region, we examine how the individual dendrites within the neuron arbor relate to the fractal properties of the arbor as a whole. We find that the dendrites reveal unexpectedly mild fractal characteristics quantified by a low fractal dimension. This is confirmed by comparing two fractal methods-a traditional "coastline" method and a novel method that examines the dendrites' tortuosity across multiple scales. This comparison also allows the dendrites' fractal geometry to be related to more traditional measures of their complexity. In contrast, the arbor's fractal characteristics are quantified by a much higher fractal dimension. Employing distorted neuron models that modify the dendritic patterns, deviations from natural dendrite behavior are found to induce large systematic changes in the arbor's structure and its connectivity within a neural network. We discuss how this sensitivity to dendrite fractality impacts neuron functionality in terms of balancing neuron connectivity with its operating costs. We also consider implications for applications focusing on deviations from natural behavior, including pathological conditions and investigations of neuron interactions with artificial surfaces in human implants.

Abstract Image

Abstract Image

Abstract Image

神经元乔木几何对其树突的有限范围分形特性很敏感。
分形几何是一个众所周知的模型,用于捕获许多自然物体的多尺度复杂性。通过分析大鼠海马CA1区锥体神经元的三维图像,我们研究了神经元乔木内的单个树突如何与整个乔木的分形特性相关。我们发现树突表现出意想不到的温和的分形特征,由低分形维数量化。通过比较两种分形方法——一种传统的“海岸线”方法和一种检测树突在多个尺度上扭曲度的新方法——可以证实这一点。这种比较也允许树突的分形几何与更传统的复杂性度量相关联。相比之下,乔木的分形特征可以用更高的分形维数来量化。采用扭曲的神经元模型来修改树突模式,发现偏离自然树突行为会导致乔木结构及其在神经网络中的连通性发生大的系统性变化。我们讨论了这种对树突分形的敏感性如何影响神经元功能,以平衡神经元连接及其运行成本。我们还考虑了应用的影响,重点是偏离自然行为,包括病理条件和研究神经元与人工植入物表面的相互作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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