Electrophoretic Transport Through Fibrocartilage Driven by Square and Sawtooth Pulses With Decreased Joule Heating

IF 3 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC
Prince M. Atsu;Zachary Nicolella;Maya Webb;Nicholas Brady;Eunice Nepomuceno;Connor Mowen;Gary L. Thompson
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Abstract

Measurement of molecular transport through tissues can be performed using gel electrophoresis techniques but is subject to substantial changes of temperature over the course of an experiment due to conversion of electrical to thermal energy. The objective of this study is to mitigate thermal generation and accumulation while determining the electrophoretic mobility of charged molecules within annulus fibrosus cartilage tissue. By using electrical pulses as compared to direct current (DC), less total energy is input and more heat can dissipate in a given amount of time. Temperature measurements confirm that use of DC leads to higher rates of temperature change during electrophoresis, with Joule heating responsible for the thermal rise. The measured electrophoretic mobilities of two small, charged dye molecules are found to be similar among DC, square and sawtooth pulsed electrophoresis. One significant difference occurs between square and sawtooth pulses for the dye that interacts less with the cartilage tissue. Results herein suggest that accurate measurements with reduced temperature changes of thermally-sensitive tissues can be made using pulsed electrophoresis, which can lead to a better understanding of molecular transport under physiological conditions.
方脉冲和锯齿脉冲驱动的纤维软骨电泳输运
通过组织的分子传输的测量可以使用凝胶电泳技术进行,但由于电能转化为热能,在实验过程中温度会发生显著变化。本研究的目的是在确定纤维环软骨组织内带电分子的电泳迁移率的同时,减轻热的产生和积聚。与直流电(DC)相比,通过使用电脉冲,输入的总能量更少,并且在给定的时间内可以耗散更多的热量。温度测量证实,在电泳过程中,使用直流电会导致更高的温度变化率,焦耳加热会导致热上升。在直流、方形和锯齿脉冲电泳中,两个带电荷的小染料分子的电泳迁移率是相似的。对于与软骨组织相互作用较少的染料,在方形和锯齿形脉冲之间出现了一个显著的差异。本文的结果表明,使用脉冲电泳可以在降低热敏组织温度变化的情况下进行准确的测量,这可以更好地了解生理条件下的分子转运。
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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来源期刊
CiteScore
5.80
自引率
9.40%
发文量
58
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