We made a bold choice to fit both our mission, which is to boost science using microfluidics, as well as our culture, which is to do things our way and to be part of the research community.
We decided to promote and sell our instruments, not through common, boring advertisement, but instead by providing you with:
And then we hope that while surfing our website, some of you will discover our microfluidic brand and fall in love with Elveflow.
Learn about water-in-oil emulsions and how Elveflow’s microfluidic solutions offer precision control for applications in food, cosmetics, and pharmaceuticals.
The profile of laminar flow through a small straight pipe may be approximated by small concentric cylinders towards the direction of the flow.
This review introduces the field of microfluidics and provides an overview of the advantages, disadvantages, and current applications of microfluidics in chemistry.
Explore the intricacies of air-liquid interfaces and optimized cell culture substrates in microfluidic lung-on-a-chip systems.
Explore the advanced microfluidic tumor-on-chip systems revolutionizing breast cancer research. How these systems offer precise drug testing.
Explore methods for droplet detection and measurement in microfluidic channels, including optical imaging and laser-initiated detection.
Discover how gut-on-a-chip technology is revolutionizing intestinal research & drug development by replicating the gut's complex environment.
Centrifugal microfluidics, or "Lab-on-a-CD," leverages centrifugal force to manipulate fluids on a microscale.
Nanocrystals (NCs) are tiny crystalline objects, with unique properties crucial for scientific and technological applications.
The integration of CRISPR-Cas9 with microfluidics has led to the development of innovative techniques for genetic editing and screening.
Pharmacogenomics is the study of how an individual’s genetic variants influence drug responses and treatment efficacy.
The Dynamics of Fungal Spore Dispersal: Insights from Microfluidic Models
Free-flow electrophoresis (FFE) is a technique that enables the continuous separation of analytes as they flow through a planar channel.
Specifically, we will explore a mechanical force known as shear stress and its role in modulating cellular responses through a process known as mechanosensing.
A lab-on-a-chip is a miniaturized device that integrates onto a single chip one or several analyses, which are usually done in a laboratory; analyses such as DNA sequencing or biochemical detection.
Multiple emulsions (monodisperse double emulsions for example) are promising materials for industrial fields like cosmetics, pharmaceutics or food. These emulsions in an emulsion can be used to encapsulate fragile compounds (drugs, vitamins, aromas…) inside droplets
Polydimethylsiloxane, called PDMS or dimethicone, is a polymer widely used for the fabrication and prototyping of microfluidic chips.
Finding the right technique for particle encapsulation using micro and nanoparticles is key for a successful particle encapsulation protocol.
This review demonstrates the development of microfluidic techniques and their capability in performing various types of chemical synthesis.
A guide to calculate the flow resistance of your microfluidic circuit.
One of the key criteria to choose your microfluidic device material is its chemical resistance. This review will help you choose one depending on your application.
Microfluidics: definitions. This short review aims to cover the main microfluidics definitions from the simple word by word science to the advantages & applications
Introduction to thermoelectric sensor | Microfluidics immunosensors offer multiple advantages over the conventional immunoassays that include improved reaction rate, reduced time for incubation of the reactants, and decreased reagents and sample consumption. Moreover, miniaturization and integration of the multiple assay components permit automation, precise flow control, increased reproducibility, and the possibility for high-throughput analysis.
PLGA nanoparticles are of great interest for biomedical applications. This review focus on microfluidic synthesis methods of these nanoparticles.
This review focuses on point of care (POC) diagnostic devices for pathogen detection
Acoustic techniques for sorting and separation of micron-sized particles in microfluidic devices
Microfluidics is the science that deals with the flow of liquid inside micrometer-size channels.
Air bubbles are among the most recurring issues in microfluidics. Because of the micrometric dimensions of the tubes and channels
Microrheology is a technique used to measure the rheological properties of a medium, such as viscosity and viscoelasticity. This short review is presenting the different techniques and applications.
Diagnosis is the first step in treating any disease, and paper microfluidic devices can facilitate this crucial step. Most of the time, this necessary task is
Electrochemical detection is particularly suitable for lab-on-a-chip integration and microfluidics due to the versatility of size, geometry and nature of electrodes that can be integrated within a microfluidic platform, and to the minimum instrumentation it requires.
Soft robotics is a growing field which relies on mimicking locomotion mechanisms of soft bodies existing in nature to achieve smooth and complex motion. This review presents the different techniques and applications of soft robotics.
Microfluidics is a term which appears more and more often in papers and scientific magazines; but, what exactly is microfluidics?
In this review, we will present the PCR, qPCR and other associated methods with their microfluidic applications.
This review presents the main applications of microfluidics for molecular analysis and its numerous techniques for DNA analysis.
Microfluidics, i.e. the science and engineering of fluid flows in microscale, can be the answer for a more effective and targeted drug administration.
Suitable detection techniques are required to be coupled to microfluidic technology in order to analyze experiment outcomes in a sensitive and scalable way.
Microfluidics involve different types of devices, and materials for microfluidic fabrication must be selected while bearing in mind all the requirements necessary for building a fine microfluidic device.
Nanoparticles are particles with a size smaller than 100 nm. They are made up of carbon, metal, metal oxides or organic matter.
PDMS pneumatic microvalves are based on the pressure-driven deformation of a soft material (generally PDMS) that clogs or releases liquid flows into microsystems.
Microfluidics is both the science which studies the behaviour of fluids through micro-channels and the technology of manufacturing microminiaturized devices containing chambers and tunnels through which fluids flow or are confined.
Magnetic manipulation of micro-fluids is an attractive concept. Due to the non-invasive nature of magnetic fields, magnetic particles or magnetic fluids can be manipulated inside a microfluidic channel by external magnets that are not in direct contact with the fluid.
Today, MICROFLUIDICS is a distinct and major technological field, but 20 years ago it was not like this and its boundaries were not so well defined. The history of microfluidics is strictly related to several other areas
Gas bubbles present in a liquid sample are a common problem encountered in numerous microfluidic experiments, and their removal in the sample of interest is quite often a major challenge for microfluidicists.
Microfluidic accessories, such as tubing, fittings and connectors are critical tools that strengthen experimental setups, making it possible to simplify and accelerate the discoveries of microfluidicists.
Several parameters have to be taken into consideration while choosing a microfluidic tubing. Depending on your application, the choice of the right tubing for
Polydimethylsiloxane, called PDMS or dimethicone, is a polymer widely used for the fabrication and prototyping of microfluidic chips. It is a mineral-organic polymer (a structure containing carbon and silicon)
Syringe pumps are widely used in microfluidics research since they are easy to use and enable fast setup of microfluidic experiments. The two main drawbacks of the syringe pump for MICROFLUIDICS are the slow response time when setting a new flow rate and the FLOW OSCILLATIONS DUE TO MOTOR STEPS. Here, we will focus on understanding why syringe pumps have low responsiveness in microfluidics and go through ways to address this concern.
It is no secret that in MICROFLUIDICS as in other fields, sometimes the smallest things can make the biggest difference. We all have better things to do than waste our precious time dealing with leakage
Because they make setups more reliable, microfluidic accessories such as tubing, fittings and connectors are of fundamental importance. By enabling microfluidicists to free up more time to develop and test microfluidic strategies,
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