Webinar: Importance of Flow in Organ-on-a-Chip, featuring the Gut-on-a-Chip Model
As OOC technologies continue to evolve, precise flow rate control has been shown to be essential for controlling shear stress in long-term experiments and accurate biophysical modeling. In this webinar, you’ll gain insights into the latest advancements in flow control for OOC perfusion and recirculating media systems. Learn about the state-of-the-art options available, their advantages, limitations, and their relative effects on experimental outcomes.
Our expert from Institute Pasteur Lille showcase the Gut-on-Chip (GoC) model, supported by the Omi automated platform, highlighting its applications and benefits.
In this conference, you will:
- Gain insights into the latest advancements in flow control technologies for OOC/MPS, and how they effect experimental outcomes.
- Discover best practices for implementing flow parameters in long-term studies, ensuring physiological relevance and reproducibility.
- Gold standards in Organ-On-Chip design: how to estimate shear stress and its significance in chip models?
- Explore real-world applications: A case study presentation from Institute Pasteur Lille
Featured Talk by Dr. Elise Delannoy
Dr. Delannoy will present her latest research on the Bioengineered Human Gut-on-Chip Model to Study Host-Microbiome Interactions, highlighting an innovative, low-cost, open-access, and 3D-printed Gut-on-Chip model (3DPµGut).
Discover Omi, Automated Organ-on-chip platform
Omi is an automated platform that helps reproduce the microphysiological behavior of organs inside microfluidic chips. It is compatible any type of chips to sustain different cell culture types or organ on chip models (Gut, Skin…)
Endothelial Cell Culture Under Shear Stress
Reproduce precise shear stress conditions of blood vessels with endothelial cells-on-chip using the Omi.
HUVEC after 7 days of culture media recirculation with Omi
Gut-on-chip Model Development
Achieve optimal flow control and sustained culture conditions, enhancing cell differentiation, nutrient delivery, and intestinal barrier function to accurately replicate the human intestine.
Caco2 cells after 7 days of culture medium recirculation with Omi