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Electric Field Effects on Microbial Cell Properties: Implications for Detection and Control in Wastewater Systems

Camelia Ungureanu, Silviu Răileanu, Daniela Simina Ștefan, Iosif Lıngvay, Attila Tókos, Mircea Ștefan

2025Environments10 citationsDOIOpen Access PDF

Abstract

Electric fields (EFs) have emerged as effective, non-chemical tools for modulating microbial populations in complex matrices such as wastewater. This review consolidates current advances on EF-induced alterations in microbial structures and functions, focusing on both vegetative cells and spores. Key parameters affected include membrane thickness, transmembrane potential, electrical conductivity, and dielectric permittivity, with downstream impacts on ion homeostasis, metabolic activity, and viability. Such bioelectrical modifications underpin EF-based detection methods—particularly impedance spectroscopy and dielectrophoresis—which enable rapid, label-free, in situ microbial monitoring. Beyond detection, EFs can induce sublethal or lethal effects, enabling selective inactivation without chemical input. This review addresses the influence of field type (DC, AC, pulsed), intensity, and exposure duration, alongside limitations such as species-specific variability, heterogeneous environmental conditions, and challenges in achieving uniform field distribution. Emerging research highlights the integration of EF-based platforms with biosensors, machine learning, and real-time analytics for enhanced environmental surveillance. By linking microbiological mechanisms with engineering solutions, EF technologies present significant potential for sustainable water quality management. Their multidisciplinary applicability positions them as promising components of next-generation wastewater monitoring and treatment systems, supporting global efforts toward efficient, adaptive, and environmentally benign microbial control strategies.

Topics & Concepts

Biochemical engineeringEnvironmental scienceWastewaterMicrobial population biologyMicrobial fuel cellSewage treatmentMultidisciplinary approachProcess engineeringMonitoring and controlField (mathematics)NanotechnologyEnvironmental engineeringChemical sensorEnvironmental monitoringBiotechnologyBioreactorKey (lock)Computer scienceMicrobial metabolismEngineeringChemistryEnvironmental chemistryWater qualityDielectrophoresisMicrofluidic and Bio-sensing TechnologiesPlant and Biological Electrophysiology StudiesMagnetic and Electromagnetic Effects
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