3D, Organoid & Microphysiological Systems

Unlock the power of three-dimensional (3D) cell culture, organoids, and microphysiological systems designed to replicate human tissue complexity and function with high fidelity. These innovative platforms elevate drug discovery, toxicology, and disease modeling by providing insights that traditional 2D cultures cannot.

Our expertly engineered tumor spheroids and organoids, derived from human induced pluripotent stem cells (iPSC) and adult stem cells, closely mimic native tissue microenvironments. They recapitulate key biological features such as cellular heterogeneity, gradients, and extracellular matrix interactions, delivering superior predictive power for therapeutic efficacy and resistance studies.

Using state-of-the-art 3D bioprinting, we craft complex multicellular constructs with spatial precision, enabling controlled tissue architecture and cell-cell interaction. Our multicellular co-culture systems foster physiological cell communication, critical for modeling complex tissues and improving translational relevance.

Our organ-on-chip devices integrate microfluidics with tissue models (gut–liver, kidney–lung, blood-brain barrier) to simulate organ-level functions and inter-organ communication under flow conditions. These platforms enable real-time assessment of pharmacokinetics, drug metabolism, toxicity, and cellular crosstalk in highly controllable environments.

We provide integrated multi-organ microfluidic systems incorporating multiple organ chips connected by perfused microchannels. This whole-body simulation facilitates systemic drug and toxicity profiling, offering unparalleled translational insights to accelerate decision-making and reduce costly clinical failures.