Abstract
This study aimed at evaluating the contribution of low voltage electric field, both alternating (AC) and direct (DC) currents, on the prevention of bacterial attachment and cell inactivation to highly electrically conductive self-supporting carbon nanotubes (CNT) membranes at conditions which encourage biofilm formation. A mutant strain of Pseudomonas putida S12 was used a model bacterium and either capacitive or resistive electrical circuits and two flow regimes, flow-through and cross-flow filtration, were studied. Major emphasis was placed on AC due to its ability of repulsing and inactivating bacteria. AC voltage at 1.5 V, 1 kHz frequency and wave pulse above offset (+0.45) with 100Ω external resistance on the ground side prevented almost completely attachment of bacteria (>98.5%) with concomitant high inactivation (95.3 ± 2.5%) in flow-through regime. AC resulted more effective than DC, both in terms of biofouling reduction compared to cathodic DC and in terms of cell inactivation compared to anodic DC. Although similar trends were observed, a net reduced extent of prevention of bacterial attachment and inactivation was observed in filtration as compared to flow-through regime, which is mainly attributed to the permeate drag force, also supported by theoretical calculations in DC in capacitive mode. Electrochemical impedance spectroscopy analysis suggests a pure resistor behavior in resistance mode compared to involvement of redox reactions in capacitance mode, as source for bacteria detachment and inactivation. Although further optimization is required, electrically polarized CNT membranes offer a viable antibiofouling strategy to hinder biofouling and simplify membrane care during filtration.
Highlights
Biofouling control is considered to be one of the greatest challenges in membrane filtration of water (Flemming et al, 1997)
carbon nanotubes (CNT) fibers were fabricated by direct spinning from chemical vapor deposition (CVD) synthesis using a liquid source of carbon and an iron nanocatalyst, as described by Li et al (2004)
The effect of AC, i.e., polarizing electric field, in resistive mode on the attachment of bacteria on CNT membranes and biofilm formation was first thoroughly studied in flow-through regime in order to find the most effective operational conditions
Summary
Biofouling control is considered to be one of the greatest challenges in membrane filtration of water (Flemming et al, 1997). Electrical current has been described to influence bacterial adhesion to conductive surfaces in medical and industrial applications. In the last decade there is a growing interest in applying low electrical fields (mV/cm range) to control bacterial adhesion and biofilm formation on conductive surfaces, such as surgical stainless steel and gold, platinum and indium-tin oxide electrodes, especially for detachment of bacteria (Poortinga et al, 2001; Busalmen and De Sánchez, 2001; van der Borden et al., 2004; Pérez-Roa et al, 2006; Hong et al, 2008; Kang et al, 2011; Shim et al, 2011). In the water treatment field, the application of a low alternating current (AC) potential (1.5 V, square wave) on a conductive NF membrane to control biofilm formation was reported
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