开发一种电流控制刺激装置,用于研究电流对由生物膜引起的植入物感染的影响

Maxim Fenko, Constantin Wiesener, Rima Fanaei Pirlar, Andrej Trampuz, Markus Valtin, Thomas Schauer
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引用次数: 0

摘要

生物膜是一种细菌群落,它们转化成一种被细胞外聚合物质包围的状态,这使得它们对抗生素不那么敏感。这些细菌通常在金属植入物上形成,并导致慢性感染。由于抗生素对生物膜的影响严重降低,电刺激(单独使用和与抗菌素联合使用)的效果需要进一步观察,因为现有的研究表明了积极的效果。方法:因此,本工作研究了六通道电流控制刺激装置的发展,这使得进一步的体外研究电刺激对生物膜的影响成为可能。该装置通过负载控制所需的刺激电流,以抵消不断改变其电阻和电容特性的电化学过程。结果:刺激器的每个通道能够在50 A至1 mA的幅度范围内工作,频率范围为0 Hz至1 kHz,脉冲宽度范围为50 s至1 ms。电流控制为三种不同的刺激模式提供了3.3 s的上升时间:恒定直流电(DC),脉冲直流电(DC)和双相脉冲交流电(AC)。此外,图形用户界面使用户能够在连接刺激器装置的计算机上调节和观察刺激。结论:在同一设备上实现多种刺激参数,可以分析不同刺激模式对生物膜的影响,从而进行更多的体外研究,为生物膜感染患者提供充分的治疗是必然的。
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Development of a current controlled stimulation setup for investigating the effect of electrical currents on implant infections caused by biofilms
Abstract Introduction: Biofilms are bacterial communities that transform into a state enclosed in an extracellular polymeric substance, which makes them less susceptible to antibiotics. Those bacterial formations often develop on metal implants and cause chronic infections. Due to the severely reduced impact of antibiotics against biofilms, the effect of electric stimulation (on its own and in combination with antimicrobials) needs to be further observed, as available studies indicate a positive effect. Methods: Therefore, this work examined the development of a six-channel current-controlled stimulation setup, which enables further in vitro research on the effects of electric stimulation on biofilms. The setup controls the desired stimulation current through the load to counteract electrochemical processes, which constantly change its resistive and capacitive properties. Results: Each channel of the stimulator is able to operate within an amplitude range of 50 A to 1 mA, a frequency range of 0 Hz to 1 kHz, and a pulse width range of 50 s to 1 ms. The current control provides a sufficient rise time of 3.3 s for three different stimulation modes: constant direct current (DC), pulsed DC, and biphasic-pulsed alternating current (AC). Furthermore, a graphical user interface enables the user to regulate and observe the stimulation on a computer to which the stimulator device is connected. Conclusion: The achieved variety of stimulation parameters in one device makes it possible to analyze the effect of different stimulation paradigms on biofilms and therefore enables more in vitro research which is inevitable to develop a sufficient treatment for patients with biofilm-infected implants.
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来源期刊
Current Directions in Biomedical Engineering
Current Directions in Biomedical Engineering Engineering-Biomedical Engineering
CiteScore
0.90
自引率
0.00%
发文量
239
审稿时长
14 weeks
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