What if we could measure flavour or scent with a chip? Our experts developed a microfluidic technique called receptomics. This technique measures the response of many different receptor proteins to series of extracts or pure substances in a flow cell, and predicts responses in the human body, thus reducing the need for test panels or animal experiments. The receptomics technique may also be useful for the development of personalised food and medication.
How does receptomics work?
The receptor coding genes are printed in a grid layout of approximately one square centimetre onto a glass slide. A cell layer is seeded on top of the glass slide and the cells attach to the printed DNA. When the cells absorb the DNA via reverse transfection, a living cell array is formed where each spot of the array expresses an unique receptor.
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Using receptor signals
Receptors (GPCR’s and ion channels) have many different biological functions in the human body like the detection of taste or scent molecules and hormones. These molecules are captured on the outside of the cell and they subsequently trigger a biological response inside of the cell. Those intracellular signals can be diverse but often involve calcium ions.
Visualising taste or hormone differences
Our receptomics technique visualizes the changes in calcium ion concentration within the cells of the entire living cell array. We visualize the real-time calcium signals of all array spots in parallel to determine specific response patterns for each sample. In that way we are able to capture for example taste differences in food stuffs like tomato, coffee or beer or hormone differences in blood serum.
A crucial tool in our receptomics technique is the software that allows for the rapid analysis of the signals and statistical tools to report receptor specific differences between samples.
Sensing hormones from gut cells
We run receptomics projects focusing on tongue-on-a-chip, nose-on-a-chip and gut-on-a-chip applications. In the case of the gut-on-a-chip application the receptomics chip is placed downstream of gut cells to sense the hormones that are secreted from the gut cells upon stimulation.