Physical limits on chemical sensing in bounded domains

arXiv - PHYS - Biological Physics Pub Date : 2024-08-20 DOI:arxiv-2408.10745

Daniel R. McCusker, David K. Lubensky

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Abstract

Cells respond to chemical cues, and the precision with which they can sense these cues is fundamentally limited by the stochastic nature of diffusion and ligand binding. Berg and Purcell famously investigated how well a small sensor in an infinite ligand bath can determine the ligand concentration, and a number of subsequent analyses have refined and built upon their classical estimates. Not all concentration sensing problems, however, occur in such an infinite geometry. At different scales, subcellular sensors and cells in tissues are both often confronted with signals whose diffusion is affected by confining boundaries. It is thus valuable to understand how basic limits on chemosensation depend on the sensor's size and on its position in the domain in which ligand diffuses. Here we compute how sensor size and proximity to reflecting boundaries affect the diffusion-limited precision of chemosensation for various geometries in one and three dimensions. We derive analytical expressions for the sensing limit in these geometries. Among our conclusions is the surprising result that, in certain circumstances, smaller sensors can be more effective than larger sensors. This effect arises from a trade-off between spatial averaging and time averaging that we analyze in detail. We also find that proximity to confining boundaries can degrade a sensor's precision significantly compared to the precision of the same sensor far from any boundaries.

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有界域中化学传感的物理限制

细胞会对化学线索做出反应，而它们感知这些线索的精确度从根本上受到扩散和配体结合随机性的限制。伯格和珀塞尔曾对无限配体浴中的小型传感器确定配体浓度的能力进行过著名的研究，随后的一些分析对他们的经典估计进行了改进和发展。在不同的尺度上，亚细胞传感器和组织中的细胞都经常面临扩散受封闭边界影响的信号。因此，了解化学感应的基本限制如何取决于传感器的大小及其在配体扩散域中的位置是非常有价值的。在这里，我们计算了传感器的尺寸和与反射边界的接近程度如何影响一维和三维各种几何形状的扩散限制化学感应精度。我们推导出了这些几何形状中传感极限的分析表达式。我们的结论中包括一个令人惊讶的结果，即在某些情况下，较小的传感器可能比较大的传感器更有效。这种效应源于空间平均和时间平均之间的权衡，我们对此进行了详细分析。我们还发现，与远离任何边界的同一传感器的精度相比，靠近限制边界会显著降低传感器的精度。

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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arXiv - PHYS - Biological Physics

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