Modeling of Inactivation of Biofilm Composing Bacteria with Low Intensity Electric Field: Prediction of Lowest Intensity and Mechanism

Tirono, Mokhamad; Suhariningsih,

doi:10.47836/pjst.29.1.08

JST

2021

DOI: 10.47836/pjst.29.1.08

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Modeling of Inactivation of Biofilm Composing Bacteria with Low Intensity Electric Field: Prediction of Lowest Intensity and Mechanism

Mokhamad Tirono¹,

Suhariningsih Suhariningsih²

Abstract: Sterilization using high-intensity electric fields is detrimental to health if safety is inadequate, so it is necessary to study the possibility of sterilization using low-intensity electric fields. This study aims to determine the lowest electric field intensity and treatment time to deactivate the bacteria that make up the biofilms and explain the mechanism of inactivation. The study samples were biofilms from the bacteria Pseudomonas aeruginosa and Staphylococcus epidermidis grown on the catheter. The model… Show more

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A Highly Efficacious Electrical Biofilm Treatment System for Combating Chronic Wound Bacterial Infections

Zhao

Wang

et al. 2022

Advanced Materials

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Biofilm infection has a high prevalence in chronic wounds and can delay wound healing. Current treatment using debridement and antibiotic administration imposes a significant burden on patients and healthcare systems. To address their limitations, a highly efficacious electrical antibiofilm treatment system is described in this paper. This system uses high‐intensity current (75 mA cm−2) to completely debride biofilm above the wound surface and enhance antibiotic delivery into biofilm‐infected wounds simultaneously. Combining these two effects, this system uses short treatments (≤2 h) to reduce bacterial count of methicillin‐resistant S. aureus (MRSA) biofilm‐infected ex vivo skin wounds from 1010 to 105.2 colony‐forming units (CFU) g−1. Taking advantage of the hydrogel ionic circuit design, this system enhances the in vivo safety of high‐intensity current application compared to conventional devices. The in vivo antibiofilm efficacy of the system is tested using a diabetic mouse‐based wound infection model. MRSA biofilm bacterial count decreases from 109.0 to 104.6 CFU g−1 at 1 day post‐treatment and to 103.3 CFU g−1 at 7 days post‐treatment, both of which are below the clinical threshold for infection. Overall, this novel technology provides a quick, safe, yet highly efficacious treatment to chronic wound biofilm infections.

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A Highly Efficacious Electrical Biofilm Treatment System for Combating Chronic Wound Bacterial Infections

Zhao

Wang

et al. 2022

Advanced Materials

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Sterilization Effects of Micro-Electrolysis Process on Simulated Industrial Circulating Cooling Water

et al. 2021

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Modeling of Inactivation of Biofilm Composing Bacteria with Low Intensity Electric Field: Prediction of Lowest Intensity and Mechanism

Cited by 2 publications

References 39 publications

A Highly Efficacious Electrical Biofilm Treatment System for Combating Chronic Wound Bacterial Infections

A Highly Efficacious Electrical Biofilm Treatment System for Combating Chronic Wound Bacterial Infections

Sterilization Effects of Micro-Electrolysis Process on Simulated Industrial Circulating Cooling Water

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