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Associate Professor Xiaoyun Ding and his team in the Biomedical Microfluidics Laboratory (BMMLab) stumbled across an interesting anomaly during a cell sensing project that used different forms of acoustic waves to measure cell mechanics. The group discovered a new wave mode never seen before that can unlock a new level of cell manipulation capabilities.

The collaborative work could boost health and drug advancements by giving researchers a better understanding of primary and secondary radiation forces in multiphase colloidal systems – such as emulsions, foams, membranes and gels.

Professor Xiaoyun Ding recently earned a $1.8 million grant to help improve cancer-fighting tools and cut patient costs, exploring ways to streamline delivery of lifesaving treatments into immune cells.

Diseases of the blood, like sickle cell disease, have traditionally taken a full day, tedious lab work and expensive equipment to diagnose, but researchers across disciplines have developed a way to diagnose these conditions with greater precision in only one minute.

Researchers found a new way of understanding the vaporization behavior of mixtures. The work is described in “Vaporizable Endoskeletal Droplets via Tunable Interfacial Melting Transitions,” a paper published in Science Advances this April.