2PP-Hydrogel Covered Electrodes to Compensate for Media Effects in the Determination of Biomass in a Capillary Wave Micro Bioreactor

Biosensors Pub Date : 2024-09-09 DOI:10.3390/bios14090438
Sven Meinen, Steffen Brinkmann, Kevin Viebrock, Bassant Elbardisy, Henning Menzel, Rainer Krull, Andreas Dietzel
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Abstract

Microbioreactors increase information output in biopharmaceutical screening applications because they can be operated in parallel without consuming large quantities of the pharmaceutical formulations being tested. A capillary wave microbioreactor (cwMBR) has recently been reported, allowing cost-efficient parallelization in an array that can be activated for mixing as a whole. Although impedance spectroscopy can directly distinguish between dead and viable cells, the monitoring of cells in suspension within bioreactors is challenging because the signal is influenced by the potentially varying properties of the culture medium. In order to address this challenge, an impedance sensor consisting of two sets of microelectrodes in a cwMBR is presented. Only one set of electrodes was covered by a two-photon cross-linked hydrogel to become insensitive to the influence of cells while remaining sensitive to the culture medium. With this impedance sensor, the biomass of Saccharomyces cerevisiae could be measured in a range from 1 to 20g/l. In addition, the sensor can compensate for a change in the conductivity of the suspension of 5 to 15mS/cm. Moreover, the two-photon cross-linking of hydroxyethyl starch methacrylate hydrogel, which has been studied in detail, recommends itself for even much broader sensing applications in miniaturized bioreactors and biosensors.
在毛细管波微型生物反应器中测定生物量时补偿介质效应的 2PP 水凝胶覆盖电极
微生物反应器可提高生物制药筛选应用中的信息产出,因为它们可以并行操作,而无需消耗大量正在测试的药物制剂。最近报道了一种毛细管波微型生物反应器(cwMBR),它可以在一个阵列中实现具有成本效益的并行化,该阵列可以作为一个整体激活进行混合。虽然阻抗光谱法可以直接区分死亡细胞和存活细胞,但要监测生物反应器内的悬浮细胞却具有挑战性,因为信号会受到培养基潜在变化特性的影响。为了应对这一挑战,本文介绍了一种由 cwMBR 中的两组微电极组成的阻抗传感器。只有一组电极被双光子交联水凝胶覆盖,从而对细胞的影响不敏感,同时对培养基保持敏感。利用这种阻抗传感器,可在 1 至 20 克/升的范围内测量酿酒酵母的生物量。此外,该传感器还能补偿悬浮液中 5 至 15mS/cm 的电导率变化。此外,我们还对羟乙基淀粉甲基丙烯酸酯水凝胶的双光子交联技术进行了详细研究,该技术有望在微型生物反应器和生物传感器中实现更广泛的传感应用。
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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