照亮分子间的交流

Bhuvana Krishnaswamy, Megan N. McClean
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引用次数: 1

摘要

分子和分子的组合是微生物天然的交流货币;微生物经过进化和改造,能够感知各种化合物,通常具有极高的灵敏度。微生物生物传感器的可用性,加上基因工程生物电路处理信息的能力,使微生物成为通过分子通信(MC)网络传播信息的有吸引力的生物机器。然而,完全由生物组成的MC网络有许多局限性。由于处理和传播延迟,它们非常缓慢,并且由于生物电路的计算能力仍然有限,它们必须采用简单的算法。在这项工作中,我们提出了一种混合生物电子框架,它利用生物组件进行传感,但将处理和计算卸载到传统的电子系统和通信基础设施。这是通过使用新兴的光遗传学领域的工具来实现的,通过光电接口触发生物传感,减轻了生物领域对计算和通信的需求。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Shining light on molecular communication
Molecules and combinations of molecules are the natural communication currency of microbes; microbes have evolved and been engineered to sense a variety of compounds, often with exquisite sensitivity. The availability of microbial biosensors, combined with the ability to genetically engineer biological circuits to process information, make microbes attractive bionanomachines for propagating information through molecular communication (MC) networks. However, MC networks built entirely of biological components suffer a number of limitations. They are extremely slow due to processing and propagation delays and must employ simple algorithms due to the still limited computational capabilities of biological circuits. In this work, we propose a hybrid bio-electronic framework which utilizes biological components for sensing but offloads processing and computation to traditional electronic systems and communication infrastructure. This is achieved by using tools from the burgeoning field of optogenetics to trigger biosensing through an optoelectronic interface, alleviating the need for computation and communication in the biological domain.
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