Microfluidic Patterning of Protein Gradients on Biomimetic Hydrogel Substrates

This protocol describes a versatile microfluidic method to generate tethered protein gradients of virtually any user-defined shape on biomimetic hydrogel substrates. It can be applied to test, in a microenvironment of physiologically relevant stiffness, how cells respond to graded biomolecular signals, for example to elucidate how morphogen proteins affect stem cell fate. The method is based on the use of microfluidic flow focusing to rapidly capture in a step-wise manner tagged biomolecules via affinity binding on the gel surface. The entire patterning process can be performed in

Microfluidic Patterning of Protein Gradients on Biomimetic Hydrogel Substrates

p High-Throughput Single-Cell TCR-pMHC Dissociation Rate Measurements Performed by an Autonomous Microfluidic Cellular Processing Unit

An integrated microfluidic device for stem cell differentiation based on cell-imprinted substrate designed for cartilage regeneration in a rabbit model

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p High-Throughput Single-Cell TCR-pMHC Dissociation Rate Measurements Performed by an Autonomous Microfluidic Cellular Processing Unit

An integrated microfluidic device for stem cell differentiation based on cell-imprinted substrate designed for cartilage regeneration in a rabbit model

The role of OCT4 and SOX2 in regulating chromatin accessibility and cell fate across the cell cycle in embryonic stem cells