In this review, we explain why microfluidics is the best alternative to enhance organoid viability, promote tissue maturation, and support vascularization.
Bimodal microscopy measures red blood cell mechanosensitive channel activation and mechanical properties during micropipette aspiration using Flow EZ.
Explore microgel crosslinking methods, key biomaterials, and their advanced applications in tissue engineering, drug delivery, and cell encapsulation.
Perform calcium signaling assays on cardiac organ-on-a-chip using Aria. Learn how calcium transients and electrophysiology in hiPSC-derived microtissues is analyzed.
Discover microfluidic interfaced capillary electrophoresis for automated, precise analysis and monitoring of biomolecular interactions and drug delivery.
Explore best practices in microfluidic perfusion for organ-on-a-chip, live-cell imaging, drug testing, and advanced flow control systems
The microfluidic receptomics-based tongue-on-a-chip platform assesses how taste receptor live cells respond to different sweeteners.
Explore how microfluidics revolutionizes drug delivery with precise nanoparticle synthesis, microneedles, and organ-on-chip technologies.
Microfluidic 3D printing combines flow control and laser lithography to create high-resolution multimaterial structures, enabling advanced cell culture and bioprinting.
Dr. Agarwal’s Physiomimetic Microsystems Laboratory (PML) developed the microfluidic pancreas-on-chip platform that can provide controlled oxygen and perfusion environments for viability and real-time imaging.
Droplet microfluidics enables precise liquid control for drug discovery, diagnostics, and materials. Follow these 10 tips to master stability, flow, and encapsulation.
