Tarn Mark D, Hirota Noriyuki, Iles Alexander, Pamme Nicole
Department of Chemistry, The University of Hull, Cottingham Road, Hull HU6 7RX, UK.
Nano Ceramics Center, National Institute for Materials Science, Tsukuba 305-0047, Japan.
Sci Technol Adv Mater. 2009 May 22;10(1):014611. doi: 10.1088/1468-6996/10/1/014611. eCollection 2009 Feb.
We explore the potential of a microfluidic continuous flow particle separation system based on the repulsion of diamagnetic materials from a high magnetic field. Diamagnetic polystyrene particles in paramagnetic manganese (II) chloride solution were pumped into a microfluidic chamber and their deflection behaviour in a high magnetic field applied by a superconducting magnet was investigated. Two particle sizes (5 and 10 μm) were examined in two concentrations of MnCl (6 and 10%). The larger particles were repelled to a greater extent than the smaller ones, and the effect was greatly enhanced when the particles were suspended in a higher concentration of MnCl. These findings indicate that the system could be viable for the separation of materials of differing size and/or diamagnetic susceptibility, and as such could be suitable for the separation and sorting of small biological species for subsequent studies.
我们探索了一种基于抗磁性材料在强磁场中排斥作用的微流控连续流颗粒分离系统的潜力。将顺磁性氯化锰(II)溶液中的抗磁性聚苯乙烯颗粒泵入微流控腔室,并研究它们在超导磁体施加的强磁场中的偏转行为。在两种浓度的氯化锰(6%和10%)中检测了两种粒径(5和10μm)的颗粒。较大的颗粒比较小的颗粒受到更大程度的排斥,并且当颗粒悬浮在更高浓度的氯化锰中时,这种效果会大大增强。这些发现表明,该系统对于分离不同尺寸和/或抗磁磁化率的材料可能是可行的,因此可能适用于分离和分选小型生物物种以供后续研究。