We offer the widest product range of low-flow mass flow meters on the market. Numerous styles of both standard and bespoke instruments can be offered for applications in laboratory, machinery, industry and hazardous areas.
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Bronkhorst instruments are used for numerous applications in many different markets. In this section you will find an overview of the main markets for our equipment, illustrated with some typical examples of applications.
Are you looking for technical documentation, are you interested to learn more about the measuring principles of Bronkhorst products, or you do want to get in contact with a Bronkhorst Service Engineer? This section will guide you to the relevant service & support topics.
Bronkhorst High-Tech BV the leaders in Mass Flow Meter / Mass Flow Controller technology for gases and liquids, Pressure Controllers and Evaporation Systems.
In my role as Science Officer at Bronkhorst I am always looking for emerging fields of application for flow control systems. As part-time professor of Microfluidic Handling Systems at both the University of Twente and Delft University of Technology I am involved in the development of miniaturized flow meters and controllers for micro flow rates. In this blog I want to share my insights about the role of flow control in organ-on-a-chip applications, where both aspects come together.
Organ-on-a-chip technology can potentially play an important role in research for new biomedical treatment methods . The control of gas flow, liquid flow  and pressure are 3 important functionalities to consider when working with these kinds of applications, as I will further explain in this blog.
An organ-on-a-chip can be described as a small microfluidic device on which living tissue of a specific organ has been grown while mimicking real life conditions. The development of organ-on-a-chip systems is quite known in the field of biomedical research, it enables research towards new treatment methods.
There are many examples of organ-on-a-chip applications. In this blog I will focus on lung-on-a-chip devices as they have recently been used in COVID-19 research: minuscule models of the lungs were created, to understand how COVID-19 invades the human body and does its damage .
In 2010, the first lung-on-a-chip system was presented by D. Huh et al. . In 2013, the same group presented a follow-up paper . We reproduced some results from their 2013 follow-up paper  in figure 1. The lung cells on the chip are grown on flexible, stretchable membranes which are a realistic imitation of the alveoli.
By applying pressure differences to the side chambers, the artificial alveoli can be expanded, thus mimicking the breathing process. By means of flowing liquid through the lower channel, and gas through the upper channel, the blood and oxygen circulation can be simulated, respectively.
A microfluidic chip suitable for growing lung-on-a-chip cell cultures, with an upper channel used for air flow, a lower channel used for liquid flow, and side chambers to apply different pressures;
Below; A mechanical stretching of the lung cells when a vacuum is applied in the side chambers.
The control of gas flow, liquid flow and pressure are 3 important functionalities to consider when working with lung-on-a-chip applications:
In my role as Science Officer at Bronkhorst, I am also involved in the iMicrofluidics project  together with the NERI initiative of Delft University of Technology. Our goal is to support and speed up the development and optimization of organ-on-a-chip systems by providing researchers with an integrated, compact and modular microfluidic sensor and actuator platform to which they can effortlessly connect their different types of organs on-a-chip, and real-time monitor and control the quality of the output of their process.
Picture 3: Preliminary version of the flow control platform, with two Bronkhorst ML120 mini CORI-FLOWs for fluid control in the upper and lower channel and an IQ+PRESS instrument for pressure control to stretch the membrane.
A preliminary version of the platform was recently fabricated , comprising among others two Bronkhorst ML120 Coriolis mass flow controllers – to control the liquid and gas flow – and an IQ+FLOW pressure controller – to regulate the vacuum. Of course, it would also be possible to control the gas flow with a thermal gas mass flow controller from the EL-FLOW Select or EL-FLOW Prestige series and the liquid flow with a liquid flow controller for ultra-low flow rates from the µ-FLOW series.
Initial measurement results show a good performance of the platform. Future research will involve improvement and optimisation of the platform, and application of the platform in organ-on-a-chip research. Among others, scientists of Erasmus Medical Centre in Rotterdam have expressed their interest in using the platform for their research on lung-on-a-chip .
MEMS-based Coriolis instruments are currently the lowest low measuring Coriolis mass flow sensor in the world.
Two important statistics for flow measurement are Accuracy and Repeatability. But is accuracy always important? Check the blog.
One of the most frequent challenges that we come across, and one that people are always surprised we can solve, is the ability to control and meter flow and pressure in-line.