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1. The Pre-Polarization and Concentration of Cells near Micro-Electrodes Using AC Electric Fields Enhances the Electrical Cell Lysis in a Sessile Drop

   https://doi.org/10.3390/bios15010022  

   Kaphle, Kishor; Nawarathna, Dharmakeerthi (January 2025, Biosensors)

   Cell lysis is the starting step of many biomedical assays. Electric field-based cell lysis is widely used in many applications, including point-of-care (POC) applications, because it provides an easy one-step solution. Many electric field-based lysis methods utilize micro-electrodes to apply short electric pulses across cells. Unfortunately, these cell lysis devices produce relatively low cell lysis efficiency as electric fields do not reach a significant portion of cells in the sample. Additionally, the utility of syringe pumps for flow cells in and out of the microfluidics channel causes cell loss and low throughput cell lysis. To address these critical issues, we suspended the cells in a sessile drop and concentrated on the electrodes. We used low-frequency AC electric fields (1 Vpp, 0–100 kHz) to drive the cells effectively towards electrodes and lysed using a short pulse of 10 V. A post-lysis analysis was performed using a hemocytometer, UV-vis spectroscopy, and fluorescence imaging. The results show that the pre-electric polarization of cells, prior to applying short electrical pulses, enhances the cell lysis efficiency. Additionally, the application of AC electric fields to concentrate cells on the electrodes reduces the assay time to about 4 min. In this study, we demonstrated that low-frequency AC electric fields can be used to pre-polarize and concentrate cells near micro-electrodes and improve cell lysis efficiency. Due to the simplicity and rapid cell lysis, this method may be suitable for POC assay development. 

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2. Pulsed Electric Field Processing of Liquid Milk Protein Concentrate 85 ( MPC85 ) to Enhance Protein Functionality

   https://doi.org/10.1111/jfpe.70183  

   Raghunath, Sonali; Mallikarjunan, Kumar; Schoenfuss, Tonya C (August 2025, Journal of Food Process Engineering)

   ABSTRACT Milk protein concentrate 85 (MPC85) is a high‐protein dairy ingredient widely used in a variety of foods and prone to performance challenges with certain applications. To address the performance limitations, this study explored pulsed electric field (PEF) processing, a nonthermal method known to alter protein behavior and functional properties. The impact of PEF processing on liquid MPC85 was assessed for solubility, foaming capacity and stability, emulsion stability, gel strength, and water‐holding capacity. Key parameters examined were temperature (25°C–50°C), electric field strength (4–20 kV/cm), and frequency (30–300 Hz). Predicted individual optimized conditions were as follows: For foaming capacity, the minimum (92.35 mL/g; 29.4% lower than the control) was predicted at 25°C, 12.45 kV/cm, and 32.21 Hz and maximum (153.86 mL/g; 17% higher than the control) was predicted at 49.35°C, 19.58 kV/cm, and 119.06 Hz. Maximum emulsion stability (55.12 min; 70.2% higher than the control) was at 50°C, 5.9 kV/cm, and 30 Hz, and the maximum gel strength (4751.33 N; 131% greater than the control) was at 50°C, 4 kV/cm, and 300 Hz. All models showed a good fit to the experimental data. Results demonstrated that foaming stability, water‐holding capacity, and solubility did not show significant improvement under the tested conditions. In conclusion, PEF could be potentially used as a tool to modify the structure of the MPC85 to further promote the application of high‐protein ingredients in the dairy industry. 

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3. Dynamic scaling of stochastic thermodynamic observables for chemical reactions at and away from equilibrium

   https://doi.org/10.1063/5.0106714  

   Mondal, Shrabani; Greenberg, Jonah S.; Green, Jason R. (November 2022, The Journal of Chemical Physics)

   Physical kinetic roughening processes are well-known to exhibit universal scaling of observables that fluctuate in space and time. Are there analogous dynamic scaling laws that are unique to the chemical reaction mechanisms available synthetically and occurring naturally? Here, we formulate an approach to the dynamic scaling of stochastic fluctuations in thermodynamic observables at and away from equilibrium. Both analytical expressions and numerical simulations confirm our dynamic scaling ansatz with associated scaling exponents, function, and law. A survey of common chemical mechanisms reveals classes that organize according to the molecularity of the reactions involved, the nature of the reaction vessel and external reservoirs, (non)equilibrium conditions, and the extent of autocatalysis in the reaction network. Varying experimental parameters, such as temperature, can cause coupled reactions capable of chemical feedback to transition between these classes. While path observables, such as the dynamical activity, have scaling exponents that are time-independent, the variance in the entropy production and flow can have time-dependent scaling exponents and self-averaging properties as a result of temporal correlations that emerge during thermodynamically irreversible processes. Altogether, these results establish dynamic universality classes in the nonequilibrium fluctuations of thermodynamic observables for well-mixed chemical reactions. 

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4. Characterization of vacuum and deep ultraviolet pulses via two-photon autocorrelation signals

   https://doi.org/10.1364/OL.427200  

   Walker, S.; Reiff, R.; Jaron-Becker, A.; Becker, A. (June 2021, Optics Letters)

   Characterization of ultrashort vacuum and deep ultraviolet pulses is important in view of applications of those pulses for spectroscopic and dynamical imaging of atoms, molecules, and materials. We present an extension of the autocorrelation technique, applied for measurement of the pulse duration via a single Gaussian function. Analytic solutions for two-photon ionization of atoms by Gaussian pulses are used along with an expansion of the pulse to be characterized using multiple Gaussians at multi-color central frequencies. This approach allows one to use two-photon autocorrelation signals to characterize isolated ultrashort pulses and pulse trains, i.e., the time-dependent amplitude and phase variation of the electric field. The potential of the method is demonstrated using vacuum and deep ultraviolet pulses and pulse trains obtained from numerical simulations of macroscopic high harmonic spectra. 

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5. Temporal reflection and refraction of optical pulses inside a dispersive medium: an analytic approach

   https://doi.org/10.1364/JOSAB.416058  

   Zhang, Junchi; Donaldson, W_R; Agrawal, G_P (February 2021, Journal of the Optical Society of America B)

   We develop an analytic approach for reflection of light at a temporal boundary inside a dispersive medium and derive frequency-dependent expressions for the reflection and transmission coefficients. Using the analytic results, we study the temporal reflection of an optical pulse and show that our results agree fully with a numerical approach used earlier. Our approach provides approximate analytic expressions for the electric fields of the reflected and transmitted pulses. Whereas the width of the transmitted pulse is modified, the reflected pulse is a mirrored version of the incident pulse. When a part of the incident spectrum lies in the region of total internal reflection, both the reflected and transmitted pulses are distorted considerably. 

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