Dypha | Dypha: adding the dimension of time to cell culture

Summary
The current preclinical drug development pipeline is highly inefficient with 9 out of 10 drugs failing when first tested in humans. Of those failures, between 69% and 81% is due to a lack of efficacy (52-57%) or safety (17-24%), indicating that the predictivity of currently used cell culture and animal models is not high enough. While promising human cell culture models have arisen in the last decades (e.g. pluripotent stem cell models, spheroids, organoids), the environment of these models is too simplistic to reach their full potential and to translate certain responses to humans.

One of the important aspects missing in current cell culture is kinetics: many processes in the human body have response times with resolutions of seconds, minutes or hours. In standard cell culture however, such temporal resolution is absent because cell culture medium remains unchanged for typically 1-3 days. So for kinetics, scientists turn to animal models with relatively low translational success and high costs.

As an alternative, complex microfluidic setups have been used to enable perfusion in vitro and demonstrated a significant amount of evidence that kinetics can improve the relevance of cell culture models. Despite the evidence, typical cell culture biologists are not taking kinetics into account because the tools to control kinetics in cell culture are too complex.

We solve this problem by starting from what cell culture biologists currently use: a standard well plate. We developed a µFluidic Adaptor that can be clamped on any 96 well plate and completely replaces the fluid in the well homogenously without disturbing the cell culture. Our goal is to develop a plug-and-play peripheral system that integrates automated fluidics and microscopic readout in a fully controlled environment: the δypha System. The system uses µFluidic Adaptors that can be designed for different applications or well plate formats.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101158943
Start date: 01-04-2024
End date: 31-03-2027
Total budget - Public funding: 2 499 625,00 Euro - 2 499 625,00 Euro
Cordis data

Original description

The current preclinical drug development pipeline is highly inefficient with 9 out of 10 drugs failing when first tested in humans. Of those failures, between 69% and 81% is due to a lack of efficacy (52-57%) or safety (17-24%), indicating that the predictivity of currently used cell culture and animal models is not high enough. While promising human cell culture models have arisen in the last decades (e.g. pluripotent stem cell models, spheroids, organoids), the environment of these models is too simplistic to reach their full potential and to translate certain responses to humans.

One of the important aspects missing in current cell culture is kinetics: many processes in the human body have response times with resolutions of seconds, minutes or hours. In standard cell culture however, such temporal resolution is absent because cell culture medium remains unchanged for typically 1-3 days. So for kinetics, scientists turn to animal models with relatively low translational success and high costs.

As an alternative, complex microfluidic setups have been used to enable perfusion in vitro and demonstrated a significant amount of evidence that kinetics can improve the relevance of cell culture models. Despite the evidence, typical cell culture biologists are not taking kinetics into account because the tools to control kinetics in cell culture are too complex.

We solve this problem by starting from what cell culture biologists currently use: a standard well plate. We developed a µFluidic Adaptor that can be clamped on any 96 well plate and completely replaces the fluid in the well homogenously without disturbing the cell culture. Our goal is to develop a plug-and-play peripheral system that integrates automated fluidics and microscopic readout in a fully controlled environment: the δypha System. The system uses µFluidic Adaptors that can be designed for different applications or well plate formats.

Status

SIGNED

Call topic

HORIZON-EIC-2023-TRANSITIONCHALLENGES-01

Update Date

06-11-2024
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Horizon Europe
HORIZON.3 Innovative Europe
HORIZON.3.1 The European Innovation Council (EIC)
HORIZON.3.1.0 Cross-cutting call topics
HORIZON-EIC-2023-TRANSITION-01
HORIZON-EIC-2023-TRANSITIONCHALLENGES-01 EIC Transition Challenge: Full scale Micro-Nano-Bio devices for medical and medical research applications