Elveflow provides cutting-edge instruments leading to significant discoveries in science.
But that is not all we do. We also share knowledge.
Our Research Summaries bring the latest findings in the vast universe of peer-reviewed microfluidics applications to you. From physics and engineering to chemistry and biomedical sciences, our content is developed by experts with free access to everyone.
Discover how BioTrojan attacks target PDMS microvalves in flow-based microfluidic biochips, compromising biomedical devices. Learn about innovative countermeasures, including design improvements and spectral authentication techniques, to safeguard critical diagnostic operations.
Discover the potential of pressure-driven flow control in liquid-phase electron microscopy (LP-EM) for precise sample characterization.
Discover how light-field flow cytometry (LFC) enhances imaging flow cytometry by delivering high-throughput, high-resolution, 3D single-cell analysis. Explore its applications in cell biology and translational research.
Learn how optical nanotweezers and microfluidics reveal ferritin molecules' dynamics, advancing our understanding of iron metabolism and innovative medical applications.
Establish the feasibility of utilizing dye-doped soap or smectic liquid crystal bubbles as optical cavities for whispering gallery mode lasing
This article investigates the behaviour of immiscible two-phase flow through porous media focusing on how pore-scale processes impact macroscopic fluid front behaviour.
Learn how protein adsorption and its roles in bubble formation and stabilization can be used for industrial-scale food foam production.
An optical measurement method of the lubrication film around flowing droplets in a rectangular microfluidic channel.
Highly efficient passive Tesla valves designed using high-precision pressure sensors for microfluidic applications.
An integrated MZI method that reliably labels and enables droplets characterisation using microfluidics in real-time.
The authors developed, tested and validated a method that applies a pressure-driven flow controller to fabricate biocompatible micron-scale silk fibers by microfluidic wet spinning.
Complex droplet networks using pressure-driven microfluidics
The short review article is based on the original article entitled “ASSEMBLY OF MULTICOMPONENT STRUCTURES FROM HUNDREDS OF MICRON-SCALE BUILDING BLOCKS USING OPTICAL TWEEZERS” by Jeffrey E. Melzer and EUAN MCLEOD published in Microsystems & Nanoengineering Journal (June 2021).
This note describes the relationship between water–surface friction & properties of confining atomically flat materials in nanofluidic devices.
This short review explores the particle migration and trapping of finite-sized microparticles using acoustically-driven microfluidics. The pressure controller's precision played a crucial role in carrying out this study successfully.
This short review explores the fabrication of a leak resistant microfluidic chip. Most importantly, the 4 channel PDMS-based microfluidic chip is also tested under pressurized fluid injection for multiple liquid leak resistance checks.
This short review explores a microfluidic approach to synthesize stimuli-responsive microcapsules with temperature-responsive core-gap-shell structures for versatile design. The pressure-driven flow controller enabled the authors to achieve precise control over the generation of core gap-shell microcapsules for this study.
This study outlines microfluidic flows of jammed suspensions of soft microgels that behave as yield-stress fluids. Wall-slip friction, i.e. the slip velocity V is plotted against the tangential stress at the wall.
In this work, the authors present a methodology for building an accurate virtual sensor, based on Computer-Aided Engineering (CAE) simulations.
Orientational order of nematic liquid crystals (NLCs), unlike isotropic liquids, enhances the influence of their rheological properties, and thus requires precise tuning of the flow parameters to control the orientational patterns.
Flow cytometry microfluidics employs the elastic property of viscoelastic fluids to induce lateral lift force to migrate the particles into a single streamline.
PEGDA (poly (ethylene glycol) diacrylate) microgels were generated and encapsulated within pico-droplets by combining droplet-based microfluidics and microscope projection photolithography. A continuous-flow photolithography was set up within a cross junction to generate and simultaneously to in-situ encapsulate fiber-like structures in pico-droplets.
Thus far, 3D laser-micro and nanoprinting offered a widespread alternative to prepare complex but single constituent 3D microfluidic structure. This work proposes a system based on a microfluidic chamber integrated into a state-of-the-art laser lithography apparatus that allows the use of several materials to 3D print complex structures in the most effective manner.
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