A surface acoustic wave biofilm sensor integrated with a treatment method based on the bioelectric effect

Kim, Young‐Wook; Meyer, Mariana T.; Berkovich, Andrew; Subramanian, Sowmya; Iliadis, A.A.; Bentley, William E.; Ghodssi, Reza

doi:10.1016/j.sna.2015.12.001

Cited by 46 publications

(36 citation statements)

References 33 publications

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“…One of the most recent setups for real-time E. coli and P. aeruginosa biofilm biomass growth evaluation was achieved through a sensing microsystem in which a microfluidic flow reactor employs a surface acoustic wave (SAW) sensor and electrodes constituting a source for current signals. This electric field is coupled with the use of gentamicin, and therefore this integrated sensing platform serves for biofilm growth monitoring and biofilm elimination (424). A novel impedimetric sensing system based on the interdigitated microelectrode microsystem envisions paving the way for the development of smart biosensors for rapid implant-associated biofilm identification and removal.…”

Section: Extending Beyond Commonplace Platformsmentioning

confidence: 99%

Options and Limitations in Clinical Investigation of Bacterial Biofilms

et al. 2018

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Bacteria can form single- and multispecies biofilms exhibiting diverse features based upon the microbial composition of their community and microenvironment. The study of bacterial biofilm development has received great interest in the past 20 years and is motivated by the elegant complexity characteristic of these multicellular communities and their role in infectious diseases. Biofilms can thrive on virtually any surface and can be beneficial or detrimental based upon the community's interplay and the surface. Advances in the understanding of structural and functional variations and the roles that biofilms play in disease and host-pathogen interactions have been addressed through comprehensive literature searches. In this review article, a synopsis of the methodological landscape of biofilm analysis is provided, including an evaluation of the current trends in methodological research. We deem this worthwhile because a keyword-oriented bibliographical search reveals that less than 5% of the biofilm literature is devoted to methodology. In this report, we (i) summarize current methodologies for biofilm characterization, monitoring, and quantification; (ii) discuss advances in the discovery of effective imaging and sensing tools and modalities; (iii) provide an overview of tailored animal models that assess features of biofilm infections; and (iv) make recommendations defining the most appropriate methodological tools for clinical settings.

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Section: Extending Beyond Commonplace Platformsmentioning

confidence: 99%

Options and Limitations in Clinical Investigation of Bacterial Biofilms

et al. 2018

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“…To date, a wide variety of biological targets have been studied, including proteins 86,87 , DNA 88 , and large cells and bacteria 89,90,91,92 , as well as biological warfare agents (BWAs) 93 and aflatoxins. 94 From a diagnostic and therapeutic perspective, there are multiple approaches that have been explored.…”

Section: Saw-based Sensorsmentioning

confidence: 99%

Surface acoustic wave devices for chemical sensing and microfluidics: a review and perspective

et al. 2017

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Surface acoustic waves (SAWs), are electro-mechanical waves that form on the surface of piezoelectric crystals. Because they are easy to construct and operate, SAW devices have proven to be versatile and powerful platforms for either direct chemical sensing or for upstream microfluidic processing and sample preparation. This review summarizes recent advances in the development of SAW devices for chemical sensing and analysis. The use of SAW techniques for chemical detection in both gaseous and liquid media is discussed, as well as recent fabrication advances that are pointing the way for the next generation of SAW sensors. Similarly, applications and progress in using SAW devices as microfluidic platforms are covered, ranging from atomization and mixing to new approaches to lysing and cell adhesion studies. Finally, potential new directions and perspectives on the field as it moves forward are offered, with a specific focus on potential strategies for making SAW technologies for bioanalytical applications.

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“…Additionally, a linear relationship between the energy of the applied electrical signal and the treatment efficacy of the BE was demonstrated [29]. We have also demonstrated real-time micro-scale detection of biofilm growth and inhibition when treated with the BE, using an integrated surface-acoustic-wave (SAW) microsystem [31] .…”

Section: Introductionmentioning

confidence: 90%

An optical microfluidic platform for spatiotemporal biofilm treatment monitoring

Kim

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Subramanian

et al. 2015

J. Micromech. Microeng.

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Bacterial biofilms constitute in excess of 65% of clinical microbial infections, with the antibiotic treatment of biofilm infections posing a unique challenge due to their high antibiotic tolerance. Recent studies performed in our group have demonstrated that a bioelectric effect featuring low-intensity electric signals combined with antibiotics can significantly improve the efficacy of biofilm treatment. In this work, we demonstrate the bioelectric effect using sub-micron thick planar electrodes in a microfluidic device. This is critical in efforts to develop microsystems for clinical biofilm infection management, including both in vivo and in vitro applications. Adaptation of the method to the microscale, for example, can enable the development of localized biofilm infection treatment using microfabricated medical devices, while augmenting existing capabilities to perform biofilm management beyond the clinical realm. Furthermore, due to scale-down of the system, the voltage requirement for inducing the electric field is reduced further below the media electrolysis threshold. Enhanced biofilm treatment using the bioelectric effect in the developed microfluidic device elicited a 56% greater reduction in viable cell density and 26% further decrease in biomass growth compared to traditional antibiotic therapy. This biofilm treatment efficacy, demonstrated in a micro-scale device and utilizing biocompatible voltage ranges, encourages the use of this method for future clinical biofilm treatment applications.

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A surface acoustic wave biofilm sensor integrated with a treatment method based on the bioelectric effect

Cited by 46 publications

References 33 publications

Options and Limitations in Clinical Investigation of Bacterial Biofilms

Options and Limitations in Clinical Investigation of Bacterial Biofilms

Surface acoustic wave devices for chemical sensing and microfluidics: a review and perspective

An optical microfluidic platform for spatiotemporal biofilm treatment monitoring

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