Shengli Mi,
Associate Professor, Biomanufacturing Engineering Laboratory,
Tsinghua University-Shenzhen
Shengli Mi received his PhD in Stem cell and Tissue Engineering from Northwest University of Agriculture and Forestry. Since 2012, he is an Associate Professor in Division of Advanced Manufacturing, Graduate school at Shenzhen, Tsinghua University. He is now the standing member of the 3D printing branch of biomedical materials of Chinese Biomaterials Society, the member of Society of Biofabrication and the editorial board of the International Journal of Ophthalmic Research. He is mainly engaged in research work in the field of biological manufacturing and tissue engineering, and his research interests include biofabrication, disease pathogeneses study, drug test and discovery, and cell/tissue/organ-on-a-chip devices.
A Minimized Valveless Electromagnetic Micropump for the Microfluidics Actuation On Organ-on-a-Chip
Wednesday, 9 October 2019 at 15:15
Add to Calendar ▼2019-10-09 15:15:002019-10-09 16:15:00Europe/LondonA Minimized Valveless Electromagnetic Micropump for the Microfluidics Actuation On Organ-on-a-ChipSELECTBIOenquiries@selectbiosciences.com
In recent years, organ chips have become an ideal alternative for physiologic, pathologic studies and drug screening. In order to simulate the physiological environment in vivo more realistically, micropumps are often needed as a power source to achieve dynamic culture in organ chips. In this study, we present a valveless electromagnetic micropump which can be used in organ chips. The fluid flow is actuated by the vibration of PDMS membrane through a varying magnetic field. This micropump uses a nozzle/diffuser structure instead of valves, which makes the structure quite simple. By reducing the volume of coil and magnet, the volume of the electromagnetic micropump is minimized so that it can be integrated on a microfluidic chip. The micropump and the chip can be portably packaged by using a small signal generation module and dry battery to supply the coil with square wave, reducing the dependence on external devices. In addition, multiple electromagnetic micropumps can be integrated on a single chip. These micropumps can be connected in series or in parallel, which can achieve complicated flow conditions and simulate the fluid flow in human body more realistically in different types of organ chips. The flow rate of the microfluidics was measured to characterize the actuating performance of the micropump. We established the dynamic co-culture of liver model and the breast cancer model on the chip, with medium actuated by the electromagnetic micropump. Cell viability, albumin and IL-6 were analyzed. Compared with the static control group, the results indicated that dynamic co-culture actuated by the electromagnetic micropump was beneficial for the growth and functions of cells.
Add to Calendar ▼2019-10-07 00:00:002019-10-09 00:00:00Europe/LondonLab-on-a-Chip and Microfluidics 2019: Emerging Themes, Technologies and Applications Track "A"SELECTBIOenquiries@selectbiosciences.com
Add to Calendar ▼2019-10-09 15:15:002019-10-09 16:15:00Europe/LondonA Minimized Valveless Electromagnetic Micropump for the Microfluidics Actuation On Organ-on-a-ChipSELECTBIOenquiries@selectbiosciences.com
