Detection of Microbes in Ice Using Microfabricated Impedance Spectroscopy Sensors

ECS sensors plus Pub Date : 2023-10-19 DOI:10.1149/2754-2726/ad024d

Lauren B. Kaiser-Jackson, Markus Dieser, Matthew McGlennen, Albert E. Parker, Christine M. Foreman, Stephan Warnat

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Abstract

During the growth of a polycrystalline ice lattice, microorganisms partition into veins, forming an ice vein network highly concentrated in salts and microbial cells. We used microfabricated electrochemical impedance spectroscopy (EIS) sensors to determine the effect of microorganisms on the electrochemical properties of ice. Solutions analyzed consisted of a 176 μ S cm −1 conductivity solution, fluorescent beads, and Escherichia coli HB101-GFP to model biotic organisms. Impedance spectroscopy data were collected at −10 °C, −20 °C, and −25 °C within either ice veins or ice grains (i.e., no veins) spanning the sensors. After freezing, the fluorescent beads and E. coli were partitioned into the ice veins. The corresponding impedance data were discernibly different in the presence of ice veins and microbial impurities. The presence of microbial cells in ice veins was evident by decreased electrical characteristics (electrode polarization between electrode and ice matrix) relative to solid ice grains. Further, this electrochemical behavior was reversed in all bead-doped solutions, indicating that microbial processes influence sensor response. Linear mixed-effects models empirically corroborated the differences in polarization associated with the presence and absence of microbial cells in ice. We show that EIS has the potential to detect microbes in ice and differentiate between veins and solid grains.

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用微阻抗光谱传感器检测冰中的微生物

在多晶冰格生长过程中，微生物分裂成脉状，形成高度集中于盐和微生物细胞的冰脉网络。我们采用微结构电化学阻抗谱(EIS)传感器来测定微生物对冰的电化学性质的影响。分析的溶液包括176 μ S cm−1电导率溶液、荧光珠和大肠杆菌HB101-GFP来模拟生物有机体。阻抗谱数据在- 10°C， - 20°C和- 25°C时在跨越传感器的冰脉或冰粒(即没有冰脉)中收集。冷冻后，荧光珠和大肠杆菌被分割到冰脉中。在冰纹和微生物杂质存在的情况下，相应的阻抗数据有明显的差异。与固体冰粒相比，冰脉中微生物细胞的存在明显降低了电特性(电极与冰基质之间的极化)。此外，这种电化学行为在所有掺杂的溶液中被逆转，表明微生物过程影响传感器的响应。线性混合效应模型从经验上证实了冰中微生物细胞的存在与不存在相关的极化差异。我们表明，EIS有潜力检测冰中的微生物，并区分静脉和固体颗粒。

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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ECS sensors plus

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