In regenerative medicine, advanced therapeutic products derived from tissue engineering technologies and are critical for more accurate medical innovation. Tissue engineered scaffold-free 3D models, including organoids, exhibit functional hallmarks of human native tissues improving the search for biomarkers, drug testing/development and toxicology models, while supporting the development of alternative methods to animal use, as stated by the Directive (2010/63/ EU) established the European Centre for the validation of alternative methods (ECVAM).
To replace animal testing, it is important to develop microphysiological systems and ‘body-on-chip’ approaches at a reasonable cost. Yet, most current bioreactors in tissue engineering are expensive, designed for organ transplant and poorly designed for miniaturization and scale-up. Furthermore, organoid production faces critical challenges such as small-scale, high costs and reproducibility. Currently, the scientific literature has been arguing that the convergence of organoids and microfluidic technologies to overcome these limitations. Specifically, microfluidics technologies can work as bioreactors, reducing labor hours and cost by supporting automated systems and low volume of reagents.
The main objective of this study was to develop a microfluidic bioreactor for organoid mass production. To reached this, we accomplish the following specific objectives:
- a bioreactor design containing hundreds of individual chambers for organoids;
- 3D simulations to analyze the microfluidic flow and the nutrients reaching the organoids inside the individual chambers;
- microfabrication of the bioreactor prototype based on hot embossing technology (Sublym) using a biocompatible polymer (Flexdym). Sublym and Flexdym are registered technologies from Eden Tech.
- seeding of human adipose-tissue derived stem/stromal cells (ASCs) in the microchannels of the bioreactor to form individual organoids inside each individual chamber;
- viability and adipogenesis assays to attest the functionality of ASC organoids.