Abstract
In the field of computational biology, electronic modeling of bio-cellular processes is in vogue for about a couple of decades. Fast, efficient and scalable electronic mimetics of recurrently found bio-chemical reactions are expected to provide better electronic circuit simulators that can also be used as bio-sensors or implantable biodevices at cellular levels. This paper presents some possible electronic circuit equivalents to model dynamics of one such bio-chemical reaction commonly involved in many bio-cellular processes, specifically pathways in living cells, known as the Hill process. The distinguishing feature of this process is cooperativity which has been modeled in silicon substrate using a pair of transistors, one transistor driving current in the other the same way ligand binding to one receptor site controls the binding affinity of the other receptor sites. Two possible circuits have been proposed and compared to electronically model cooperativity of a Hill reaction. The main idea is to exploit the natural analogies found between structures and processes of a bio-cell and electronic transistor mechanics, to efficiently model fundamental bio-chemical reactions found recurring in bio-processes. These circuits can then be combined and rearranged quickly to form larger, more complex bio-networks, thus mitigating the intricacies involved in modeling of such systems.
Highlights
Study of various life forms has always been a subject of colossal interest to the researchers
This research endeavor has put forth some possible electronic models for the bio-cellular reaction called Hill process
To model dynamics of Hill process, two transistors have been used in cascade, one controlling the activation of the other
Summary
Study of various life forms has always been a subject of colossal interest to the researchers. Simulation of one whole-cell cycle of the smallest bacteria on earth, using an over simplified model, was run on a 128-node Linux cluster in 10 hours [6] To overcome these issues an alternate direction in vogue nowadays is modeling of bio-cellular processes functionalities in specialized analog [2, 7,8], digital [9,10,11] or mixed IC electronic hardware [12,13]. Mimicking the functionalities of bio-cellular networks in analog and mixed IC hardware can help in producing improved simulators for bio-cellular networks and processes [7,8] that can aid in better understanding of biological behaviors and drug testing This kind of specialized hardware, due to size compactness and power efficiency, would be easier to integrate with synthetic biological circuits [2,9,12]; can be used as bio-sensors, and as implantable bio-devices as well
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