Amirali Ebadi scite author profile

Artificial cavitation as a prerequisite of sonoporation, plays an important role on the ultrasound (US) assisted drug delivery systems. In this study, we have proposed a new method of microbubble (MB) generation by local electrolysis of the medium. An integrated interdigital array of three-electrode system was designed and patterned on a nickel-coated quartz substrate and then, a short DC electrical pulse was applied that consequently resulted in distributed generation of microbubbles at the periphery of the electrodes. Growth of the carbon nanotube (CNT) nanostructures on the surface of the electrodes approximately increased the number of generated microbubbles up to 7-fold and decreased their average size from ∼20 µm for bare to ∼7 µm for CNT electrodes. After optimizing the three-electrode system, biocompatibility assays of the CNT electrodes stimulated by DC electrical micropulses were conducted. Finally, the effect of the proposed method on the sonoporation efficiency and drug uptake of breast cells were assessed using cell cycle and Annexin V/PI flow cytometry analysis. These results show the potential of electrochemical generation of MBs by CNT electrodes as an easy, available and promising technique for artificial cavitation and ultrasound assisted drug delivery.

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PDMS-based porous membrane for medical applications: Design, development, and fabrication

Keshtiban¹,

Zand²,

Ebadi³

et al. 2023

Biomed. Mater.

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Organ-on-a-Chip (OoC) is one of the most popular microfluidic chips and possesses various industrial, biomedical, and pharmaceutical applications. So far, many types of OoCs with different applications have been fabricated, most of which contain porous membranes, being useful for cell culture substrates. One of the challenging parts of OoC’s chips is porous membrane fabrication, making it a complex and sensitive process, which is an issue in microfluidic design. These membranes are made of various materials, same as biocompatible polymer polydimethylsiloxane (PDMS). Besides OoC, these PDMS membranes can be applied in diagnosis, cell separating, trapping, and sorting. In the present study, a new approach has been presented to design and fabricate an efficient porous membrane in terms of time and cost. The fabrication method has fewer steps than previous techniques and employs more controversial approaches. The presented method for membrane fabrication is functional and a new method to continue generating this product using one mold and peeling off the membrane on each try. Merely one sacrificial layer (PVA) and an O2 plasma surface treatment have been used for fabrication. Surface modification and sacrificial layer on the mold ease the peeling of the PDMS membrane. Transferring process of the membrane to the OoC device is explained, and a filtration test is presented to show the functionality of the PDMS membranes. Cell viability is investigated by MTT assay to ensure the PDMS porous membranes are suitable for microfluidic devices. Also, cell adhesion, cell count, and confluency are analyzed, showing almost the same results for the PDMS membranes and the control samples.

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Efficient paradigm to enhance particle separation in deterministic lateral displacement arrays

et al. 2019

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Microfluidics based particle sorting and separation methods are gaining momentum to be applied for various applications. Deterministic lateral displacement (DLD) methods are prominent for high resolution in separation and there has been extensive studies to develop more efficient devices based on the DLD. However, it is still challenging to fully eliminate negative effects of the boundaries that degrade particle separation efficiency by perturbing the fluid flow in the channel. In this article, we present two equations to optimize channels' geometry near the boundaries. Implementing the equations, the fluid behavior is improved around the pillars and thereby, separation efficiency is increased. The Boundary Correction Paradigm (BCP) enhances the microchannel's functionality as much as 2-3 times and can be highly beneficial in microchannels. Also, an equation is proposed in order to recalibrate the BCP in microchannels with desired pillar diameters. The calibration equation assures high accuracy and resolution of the DLD devices corrected with the BCP.

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A novel numerical modeling paradigm for bio particle tracing in non-inertial microfluidics devices

et al. 2019

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Amirali Ebadi

Dielectrophoresis-based microfluidic platform to sort micro-particles in continuous flow

Electrochemical generation of microbubbles by carbon nanotube interdigital electrodes to increase the permeability and material uptakes of cancer cells

PDMS-based porous membrane for medical applications: Design, development, and fabrication

Efficient paradigm to enhance particle separation in deterministic lateral displacement arrays

A novel numerical modeling paradigm for bio particle tracing in non-inertial microfluidics devices

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