Photovoltaic Stimulation Induces Overdrive Suppression in Embryonic Chicken Cardiomyocytes

Q4 Engineering Current Directions in Biomedical Engineering Pub Date : 2023-12-01 DOI:10.1515/cdbme-2023-1204

M. Polz, D. Ziesel, Niroj Shrestha, B. Pelzmann, Petra Lang, S. Scherübel, M. Üçal, Karin Kornmüller, J. Schröttner, Vedran Đerek, Aleksandar Opančar, Eric Daniel Głowacki, Christian Baumgartner, T. Rienmüller

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Abstract

Abstract In this study, we employed calcium imaging to investigate the dynamics of intracellular calcium levels in embryonic chicken cardiomyocytes upon extracellular, optoelectronic stimulation. A photovoltaic layer of donoracceptor pigments on a flexible PET substrate was used as a wireless stimulation electrode. Our findings revealed a distinct change in their spontaneous activity pattern in cardiac cells following asynchronous light stimulation. A short pause in cellular activity, indicative of overdrive suppression, was observed in recordings from several different cells. The pause in activity signifies a transient refractory period induced by stimulation of the photovoltaic device with red light. These findings suggest that photovoltaic electrodes can be used to effectively modulate the electrical activity of cardiac cells in a wireless, non-pharmacological manner. This opens new avenues for non-invasive and precise light-modulated control of cellular electrophysiology as well as potential therapeutic applications for cardiac rhythm disorders.

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光电刺激诱导胚胎鸡心肌细胞过速抑制

在这项研究中，我们采用钙成像技术研究细胞外光电刺激下胚胎鸡心肌细胞内钙水平的动态变化。采用柔性PET衬底上的供受体颜料光伏层作为无线刺激电极。我们的研究结果显示，在异步光刺激后，心肌细胞的自发活动模式发生了明显变化。在几个不同细胞的记录中观察到细胞活动的短暂停顿，表明过度驱动抑制。活动的暂停表示由红光刺激光伏装置引起的短暂不应期。这些发现表明，光伏电极可以通过无线、非药物的方式有效地调节心脏细胞的电活动。这为细胞电生理的非侵入性和精确光调制控制以及心律失常的潜在治疗应用开辟了新的途径。

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