Microfluidics

It is a multidisciplinary field that involves engineering, physics, chemistry, biochemistry, nanotechnology, and biotechnology. This technology has been developed for printing (e.g., ink-jet printers), analytical chemistry, synthetic chemistry, and biotechnology. They also have growing uses in environmental analysis and food and agriculture research.

Our chemists and engineers work together to help your team overcome design challenges by creating products with optical clarity, tight tolerances, tailorable fill times and contact angles, non-migratory acrylic adhesives and films that. To compare, a human hair is about 1microns thick.

This field has emerged in recent years as a new area of research, with applications in medicine, biology, chemistry, and physical sciences.

An acrobatic and patience exercise. Discover how to handle fluids for your microfluidic experiments. In this application note we describe how to do cell perfusion for dynamic cell culture and a way to enable uni-directional recirculation of medium. Check out our brand new comapny website, with information on all our products and services to help boost your research.

In the simplest of terms, microfluidics is the ability to handle fluids (like fluid collected with a nasal swab or a patient’s cells) at a micro level and with great precision, thus shrinking multiple lab functions down into a small, portable format. We are a research group in Biophysics and Medical Technology at the Department of Physics using micro- and nanofluidic systems to study biological interactions and automate complex processes for biomedical applications.

We have two areas of focus in our microfluidics effort. Your e-commerce platform for microfluidics.

Best products, knowledge sharing and customer care are our major principles. We dive deep into microfluidics to find the best solutions for your research! Circulating tumor cells (CTCs) have been widely considered as promising novel biomarkers for molecular research and clinical diagnosis of cancer.

However, the sorting of CTCs is very challenging due to the rarity of CTCs in blood and the morphological similarity to blood cells. Polymers are the most widely used materials for manufacturing devices but semiconductor materials like silicon are increasingly used. When time matters in hospitals, automated system can detect an early biomarker for the potentially life-threatening condition.

With its ability to replicate little slivers of reservoir rocks, microfluidics is giving the oil and gas industry a new way to capture. This site describes our work on open space microfluidics and concepts related to bioanalytical techologies towards personalized medicine.

Behavior of liquids in the micro domain differs greatly from macroscopic fluids. Microfluidics device helps diagnose sepsis in minutes. As stated in the first part of this review, using microfluidics for particle synthesis is far from its full potential. This section tries to foresee the future paths of microfluidics as a tool to synthesise catalyst NPs and other catalytic structures such as zeolites or catalyst supports.

In engineering and the physical sciences microfluidic systems are employed in applications such as control systems, heat management, and energy generation. Parameters such as flow rates, droplet size, temperatures, mixing parameters, surface properties and order of additions can be quickly varied. The study of microfluids.

Wide range of fluids and droplet types. Product development and manufacturing of microfluidic and lab-on-chip devices for science and industry.

Since blood is a moving biological fluid in vivo, it is important to study thrombosis formation in vitrounder physiological flow conditions.

To achieve this objective, we seek to develop methods that meet the following criteria in an attempt to mimic in vivofluid dynamics, molecular transport, and biochemistry: 1) flow channels. Technicolor’s latest leading role is as the breakout supplier of micro- and nano- based microfluidics consumables to the life sciences industries. Technicolor provides high quality quick-turn prototyping and rapid scalability for high volume manufacturing to speed development and product launch.

Further, the integration of microfluidics (MF) with advanced biosensor technologies is likely to result in improved POC diagnostics. This paper presents the overview of the different materials (glass, silicon, polymer, paper) and techniques for the fabrication of MF based POC devices along with their wide range of biosensor applications.

Our microfluidics technology is different, as it allows visual access to the porous system: we see the complex fluid-fluid interactions, oil mobilisation and displacement mechanisms happening. This in-depth information and knowledge gained allows us to better understand the many mechanisms of oil recovery and to support our customers in their decision-making process.

Our mission at microfluidic ChipShop is to shrink your biological and chemical lab and to bring lab-on-a-chip systems into daily laboratory life. Operating at this scale offers several advantages that can be leverage in medical devices and research. A microfluidic device can also be called a lab-on-a-chip as it can contain many necessary lab functions in a single device.

Due to these small dimensions, mass transport is dominated by capillary forces. Thus the physics and chemistry encountered is more ideal and easily predicted.

Metering of various components can also be precisely controlled.