Anthony T. Giduthuri scite author profile

Anthony T. Giduthuri

5Publications

51Citation Statements Received

222Citation Statements Given

How they've been cited

How they cite others

309

217

Affiliations

Washington State University, University of Idaho, Washington State University Tri-Cities

Publications

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Dielectrophoresis as a tool for electrophysiological characterization of stem cells

Giduthuri

Theodossiou

Schiele

et al. 2020

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Dielectrophoresis (DEP), a nonlinear electrokinetic technique caused by Maxwell–Wagner interfacial polarization of neutral particles in an electrolyte solution, is a powerful cell manipulation method used widely for various applications such as enrichment, trapping, and sorting of heterogeneous cell populations. While conventional cell characterization and sorting methods require tagging or labeling of cells, DEP has the potential to manipulate cells in a label-free way. Due to its unique ability to characterize and sort cells without the need of labeling, there is renewed interest in using DEP for stem cell research and regenerative medicine. Stem cells have the potential to differentiate into various lineages, but achieving homogeneous cell phenotypes from an initially heterogeneous cell population is a challenge. Using DEP to efficiently and affordably identify, sort, and enrich either undifferentiated or differentiated stem cell populations in a label-free way would advance their potential uses for applications in tissue engineering and regenerative medicine. This review summarizes recent, significant research findings regarding the electrophysiological characterization of stem cells, with a focus on cellular dielectric properties, i.e., permittivity and conductivity, and on studies that have obtained these measurements using techniques that preserve cell viability, such as crossover frequency. Potential applications for DEP in regenerative medicine are also discussed. Overall, DEP is a promising technique and, when used to characterize, sort, and enrich stem cells, will advance stem cell-based regenerative therapies.

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Dielectrophoretic Characterization of Tenogenically Differentiating Mesenchymal Stem Cells

et al. 2021

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Tendons are collagenous musculoskeletal tissues that connect muscles to bones and transfer the forces necessary for movement. Tendons are susceptible to injury and heal poorly, with long-term loss of function. Mesenchymal stem cell (MSC)-based therapies are a promising approach for treating tendon injuries but are challenged by the difficulties of controlling stem cell fate and of generating homogenous populations of stem cells optimized for tenogenesis (differentiation toward tendon). To address this issue, we aim to explore methods that can be used to identify and ultimately separate tenogenically differentiated MSCs from non-tenogenically differentiated MSCs. In this study, baseline and tenogenically differentiating murine MSCs were characterized for dielectric properties (conductivity and permittivity) of their outer membrane and cytoplasm using a dielectrophoretic (DEP) crossover technique. Experimental results showed that unique dielectric properties distinguished tenogenically differentiating MSCs from controls after three days of tenogenic induction. A single shell model was used to quantify the dielectric properties and determine membrane and cytoplasm conductivity and permittivity. Together, cell responses at the crossover frequency, cell morphology, and shell models showed that changes potentially indicative of early tenogenesis could be detected in the dielectric properties of MSCs as early as three days into differentiation. Differences in dielectric properties with tenogenesis indicate that the DEP-based label-free separation of tenogenically differentiating cells is possible and avoids the complications of current label-dependent flow cytometry-based separation techniques. Overall, this work illustrates the potential of DEP to generate homogeneous populations of differentiated stem cells for applications in tissue engineering and regenerative medicine.

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Dielectric Characterization and Separation Optimization of Infiltrating Ductal Adenocarcinoma via Insulator-Dielectrophoresis

2020

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The dielectrophoretic separation of infiltrating ductal adenocarcinoma cells (ADCs) from isolated peripheral blood mononuclear cells (PBMCs) in a ~1.4 mm long Y-shaped microfluidic channel with semi-circular insulating constrictions is numerically investigated. In this work, ADCs (breast cancer cells) and PBMCs’ electrophysiological properties were iteratively extracted through the fitting of a single-shell model with the frequency-conductivity data obtained from AC microwell experiments. In the numerical computation, the gradient of the electric field required to generate the necessary dielectrophoretic force within the constriction zone was provided through the application of electric potential across the whole fluidic channel. By adjusting the difference in potentials between the global inlet and outlet of the fluidic device, the minimum (effective) potential difference with the optimum particle transmission probability for ADCs was found. The radius of the semi-circular constrictions at which the effective potential difference was swept to obtain the optimum constriction size was also obtained. Independent particle discretization analysis was also conducted to underscore the accuracy of the numerical solution. The numerical results, which were obtained by the integration of fluid flow, electric current, and particle tracing module in COMSOL v5.3, reveal that PBMCs can be maximally separated from ADCs using a DC power source of 50 V. The article also discusses recirculation or wake formation behavior at high DC voltages (>100 V) even when sorting of cells are achieved. This result is the first step towards the production of a supplementary or confirmatory test device to detect early breast cancer non-invasively.

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Utilization of Dielectrophoresis for the Quantification of Rare Earth Elements Adsorbed on Cupriavidus necator

Adekanmbi

Giduthuri

Waymire

et al. 2019

ACS Sustainable Chem. Eng.

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A new method of quantifying rare earth elements (REEs): light REEs (neodymiumNd 3+ and samariumSm 3+ ) and heavy REE (europiumEu 3+ ) was investigated by utilizing native Cupriavidus necator as the biosorbent and dielectrophoresis as the quantification technique.C. necator was characterized as a control through the measurement of the first and second crossover frequencies in a polymer-based (PDMS) point-andplanar microwell platform at 8 V pp (peak-to-peak voltage) ac signal and variable frequencies. Allied C. necator in its metal-bound state was then characterized for each of the REEs adsorbed. The first crossover frequency (f co1 ) was correlated with the amount of metal adsorbed that was obtained through spectrophotometry. The influence of pH, biosorbent dosage, initial REE concentration, and REE incubation period was further investigated to study the effects of those on the biosorption process. It was found that the amount of metal biosorbed by the C. necator is directly proportional to the biosorbent dosage and metal incubation period. Exposure to higher REE concentration solutions resulted in higher biosorption, and higher pH of REE solutions (towards neutral range) resulted in abnormal behavior due to the formation of complex salts. The results obtained here, that is, the crossover frequency versus concentration curve would serve as a baseline for other researchers, such that when the crossover frequency of a biosorbent with a particular REE is known, the quantity of that particular REE adsorbed can be correlated without the need of expensive spectrophotometric analysis.

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Application of dielectrophoresis towards characterization of rare earth elements biosorption by Cupriavidus necator

Adekanmbi

Giduthuri

Carv

et al. 2020

Analytica Chimica Acta

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