More Like this

1. Dielectrophoretic trapping of particles flowing through an array of conductive cylinders

   https://doi.org/10.1063/5.0305604  

   Mondal, Tonoy K; Williams, Stuart J (December 2025, Physics of Fluids)

   Dielectrophoresis (DEP) is a label-free electrokinetic method for selectively trapping polarizable particles using non-uniform electric fields. While co-planar electrode systems are common, their inherent DEP force distribution limits throughput. This study presents a computationally efficient framework for modeling two-dimensional DEP-based particle trapping in ordered arrays of conductive cylinders. These cylinders are modeled at a range of sizes, from micrometers to nanometers, to represent microfluidic systems consisting of conductive pillars, nanofibers, etc. Analytical solutions for fluid flow and electric potential were derived using eigenfunction expansions and collocation, then used in a particle tracking model that includes hydrodynamic drag, Brownian motion, and multipolar DEP forces. Although focused on conductive arrays, this framework is extensible to other configurations. This work provides a foundation for future work in the design of high-throughput DEP systems. Both dimensionless and dimensional analyses were performed across a wide range of particle sizes (30 nm to 3 μm), voltages (10 mV to 100 V), and array geometries. No specific optimal cylinder size was found; instead, optimal performance arises from a balance between DEP force distribution and flow through the cylinder array gap. Diamond-oriented arrays exhibited enhanced trapping under moderate dielectrophoretic velocity-to-fluid velocity ratios (up to 39% greater), while square arrays performed better under low-field and large-cylinder conditions (up to 40% greater). 

   more » « less
2. Recent advances in dielectrophoresis toward biomarker detection: A summary of studies published between 2014 and 2021

   https://doi.org/10.1002/elps.202100194  

   Velmanickam, Logeeshan; Jayasooriya, Vidura; Vemuri, Madhava_Sarma; Tida, Umamaheswara_Rao; Nawarathna, Dharmakeerthi (September 2021, ELECTROPHORESIS)

   Abstract Dielectrophoresis is a well‐understood phenomenon that has been widely utilized in biomedical applications. Recent advancements in miniaturization have contributed to the development of dielectrophoretic‐based devices for a wide variety of biomedical applications. In particular, the integration of dielectrophoresis with microfluidics, fluorescence, and electrical impedance has produced devices and techniques that are attractive for screening and diagnosing diseases. This review article summarizes the recent utility of dielectrophoresis in assays of biomarker detection. Common screening and diagnostic biomarkers, such as cellular, protein, and nucleic acid, are discussed. Finally, the potential use of recent developments in machine learning approaches toward improving biomarker detection performance is discussed. This review article will be useful for researchers interested in the recent utility of dielectrophoresis in the detection of biomarkers and for those developing new devices to address current gaps in dielectrophoretic biomarker detection. 

   more » « less
3. Proof of Concept for Flow Through Nanoparticle Trapping Using a Dielectrophoretic Metal‐Coated Nanofiber Mat

   https://doi.org/10.1002/elps.70019  

   Mondal, Tonoy_K; Baryla, Christian; Stanley, Hannah; Williams, Stuart_J (August 2025, ELECTROPHORESIS)

   ABSTRACT While traditional dielectrophoretic methods for nanoparticle enrichment and filtration are versatile and selective, they struggle to handle higher throughput applications. To address this challenge and enhance the practical application of dielectrophoresis, we propose an innovative design for porous sandwiched nanofiber electrodes. The electrode is fabricated through a simple process involving the electrospinning of nanofibers with a diameter of 216 ± 28 nm and mat thickness of around 70 µm, followed by the deposition of a thin chromium/gold layer (approximately 140 nm thick) on both sides. This process ensures no electrical short circuit occurs between the electrodes, and it maintains a sheet resistance of 7.19 Ω/□. The resulting significant electric field gradients are capable of trapping nanoparticles with diameters of 100 nm and 40 nm. The structure's sub‐micrometer features and large active surface area allow for trapping of nanoparticles at a flow rate of 3.6 mL/h. To evaluate the effects of applied voltage and volumetric flow rate, we conducted experiments with constant voltage while varying the flow rate and constant flow rate while varying the voltage. Our findings indicate that trapping performance improves with higher AC voltage but decreases at higher flow rates. These insights are crucial for optimizing parameters for large‐scale nanoparticle enrichment and filtration. This proof‐of‐concept study for flow through dielectrophoresis of nanoparticles paves the way for a device suitable for large‐scale sample processing and higher throughput/separation efficiency in practical settings. 

   more » « less
4. Statistics of protein electrostatics

   https://doi.org/10.1063/5.0229619  

   Colburn, Taylor; Sarhangi, Setare Mostajabi; Matyushov, Dmitry V (November 2024, The Journal of Chemical Physics)

   Molecular dynamics simulations of a small redox-active protein plastocyanin address two questions. (i) Do protein electrostatics equilibrate to the Gibbsian ensemble? (ii) Do the electrostatic potential and electric field inside proteins follow the Gaussian distribution? The statistics of electrostatic potential and electric field are probed by applying small charge and dipole perturbations to different sites within the protein. Nonergodic (non-Gibbsian) sampling is detectable through violations of exact statistical rules constraining the first and second statistical moments (fluctuation–dissipation relations) and the linear relation between free-energy surfaces of the collective coordinate representing the Hamiltonian electrostatic perturbation. We find weakly nonergodic statistics of the electrostatic potential (simulation time of 0.4–1.0 μs) and non-Gibbsian and non-Gaussian statistics of the electric field. A small dipolar perturbation of the protein results in structural instabilities of the protein–water interface and multi-modal distributions of the Hamiltonian energy gap. The variance of the electrostatic potential passes through a crossover at the glass transition temperature Ttr ≃ 170 K. The dipolar susceptibility, reflecting the variance of the electric field inside the protein, strongly increases, with lowering temperature, followed by a sharp drop at Ttr. The linear relation between free-energy surfaces can be directly tested by combining absorption and emission spectra of optical dyes. It was found that the statistics of the electrostatic potential perturbation are nearly Gibbsian/Gaussian, with little deviations from the prescribed statistical rules. On the contrary, the (nonergodic) statistics of dipolar perturbations are strongly non-Gibbsian/non-Gaussian due to structural instabilities of the protein hydration shell. 

   more » « less
5. Three‐dimensional lab‐on‐a‐foil device for dielectrophoretic separation of cancer cells

   https://doi.org/10.1002/elps.202200287  

   Wu, Mengren; Gao, Yuan; Luan, Qiyue; Papautsky, Ian; Chen, Xiaolin; Xu, Jie (April 2023, ELECTROPHORESIS)

   Abstract A simple, low‐cost, three‐dimensional (3D) lab‐on‐a‐foil microfluidic device for dielectrophoretic separation of circulating tumor cells (CTCs) is designed and constructed. Disposable thin films are cut by xurography and microelectrode array are made with rapid inkjet printing. The multilayer device design allows the studying of spatial movements of CTCs and red blood cells (RBCs) under dielectrophoresis (DEP). A numerical simulation was performed to find the optimum driving frequency of RBCs and the crossover frequency for CTCs. At the optimum frequency, RBCs were lifted 120 µm inz‐axis direction by DEP force, and CTCs were not affected due to negligible DEP force. By utilizing the displacement difference, the separation of CTCs (modeled with A549 lung carcinoma cells) from RBCs inz‐axis direction was achieved. With the nonuniform electric field at optimized driving frequency, the RBCs were trapped in the cavities above the microchannel, whereas the A549 cells were separated with a high capture rate of 86.3% ± 0.2%. The device opens not only the possibility for 3D high‐throughput cell separation but also for future developments in 3D cell manipulation through rapid and low‐cost fabrication. 

   more » « less