Setup : Pressure sensor + Sensor Reader + OB1 flow controller
In microfluidic experiments, precise control over variables is crucial for reliable results. Pressure in microfluidic systems, in particular, plays a vital role, significantly affecting fluid behavior at the microscale. Maintaining optimal pressure levels is essential for preserving the integrity of pressure-sensitive components and ensuring accurate experimental outcomes
Capillary Pressure Sensor
Maintaining precise control over pressure at every juncture within your microfluidic setup is paramount for safeguarding the integrity of pressure-sensitive components and samples. Yet, accurately gauging pressure throughout the entire microfluidic device poses challenges due to pressure drops within the system (such as connectors, tubing, microfluidic resistors, chips, etc.). These challenges can be addressed by employing a pressure sensor capable of measuring and regulating pressure through a feedback loop at specific points within your setup. Implementing a pressure sensor feedback loop allows you to fine-tune pressure control effectively.
Most microfluidic devices and chips will be affected by pressure drops : the setup presented here can monitor via two pressure sensors and a sensor reader the effective drop occurring on a microfluidic chip
To address these challenges effectively, it is highly advisable to integrate a pressure sensor into your microfluidic system.
A pressure sensor fulfills two crucial functions:
OB1 flow controller
Sample Reservoirs
Microfluidic Pressure Sensor
Microfluidic Sensor Reader
Used with pressure controller
Used with syringe pump
Functionality: While pressure sensors and sensor readers can be utilized, syringe pumps lack feedback loop benefits. However, monitoring pressure in syringe pump setups remains crucial, especially for pressure-sensitive samples or incompatible connectors.
Elveflow’s ESI software offers precise and secure control and logging of pressure-sensitive applications.
Key features include:
How can we help you?
Name*
Email*
Message
Newsletter subscription
We will answer within 24 hours
By filling in your info you accept that we use your data.
Do you want tips on how to best set up your microfluidic experiment? Do you need inspiration or a different angle to take on your specific problem? Well, we probably have an application note just for you, feel free to check them out!
Microfluidics is the science of handling small amounts of liquids, inside micrometer scale channels. Discover how to handle fluids for your microfluidic experiments.
This application note demonstrates a smart use ouf Elveflow's Pressure sensor and sensor reader for Direct-Ink-Writing flow control.
Learn how to set up your development environment for Elveflow products with this comprehensive tutorial.
This user guide will show you how to run microfluidic colocalization studies of single molecule spectroscopy.
This application note explores the basic principle of pneumatic pumps and a flow controller based on the basic principle of pneumatic pumps, known as pressure driven flow control. It also demonstrates the applications of pressure driven flow control in a range of industrial & research fields.
Flow regulation is a compulsory operation in most of the microfluidics operations. In some applications such as 2D or 3D cell culture, flow regulation is essential since accurate micro-environmental parameters control is required. Elveflow do it’s best to make this operation as easy as possible to help you to focus on what really matter in your setup.
Study the impact of molecular transport on cell cultures with a cross flow membrane chip and microfluidic instruments.
Precise liquid injection system for manipulation of small volumes of fluids using the MUX distribution and the MUX recirculation valve.
This application note explains how to set up a robust and reproducible microfluidic platform for liposomes assembly with improved encapsulation efficiency and reduced polydispersity in size.
Single-wall carbon nanotubes (SWCNTs) are considered as quasi 1-dimensional (1D) carbon nanostructures, which are known for their outstanding anisotropic electronic, mechanical, thermal and optical properties.
This application note describes how to combine and synchronise liquid perfusion and imaging using an Olympus spinning disc confocal microscope together with an Elveflow pressure-driven flow controlled microfluidic system.
Mixing is a crucial step for several microfluidic applications like chemical synthesis, clinical diagnostics, sequencing and synthesis of nucleic acids
This application note describes how microfluidic can be employed as a nanoparticle generator based on the example of PLGA bead generation.
Learn how to perform PLGA nanoparticle preparation with Elveflow instruments and a microfluidic chip
Get a quote
Collaborations
Need customer support?
Serial Number of your product
Support Type AdviceHardware SupportSoftware Support
Subject*
I hereby agree that Elveflow uses my personal data Newsletter subscription
Message I hereby agree that Elveflow uses my personal data Newsletter subscription