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Development of a microfluidic device to study synthetic cell division (BEP/MEP)

Description The physical process of cell division, or cytokinesis, is the mechanism by which a parent cell divides into two daughter cells.…

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Building a living cell from scratch using microfluidics (BEP/MEP)

Description Throughout the course of evolution life has developed a staggering complexity at the cellular level. To shed light on the…

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Establishing programmable liposome fusion to enable synthetic cell growth (BEP/MEP)

Short description: To accomplish sustained growth and division, synthetic cells must expand their membrane surface. Providing extra lipids…

/en/faculty-of-applied-sciences/about-faculty/departments/bionanoscience/research/research-labs/koenderink-lab/student-projects/establishing-programmable-liposome-fusion-to-enable-synthetic-cell-growth-bep-mep

Mechanobiology of in vitro cartilage tissues (BEP/MEP)

Short description: In connective tissues, cells are embedded in a support matrix composed of a complex 3D network of extracellular…

/en/faculty-of-applied-sciences/about-faculty/departments/bionanoscience/research/research-labs/koenderink-lab/student-projects/mechanobiology-of-in-vitro-cartilage-tissues-bep-mep