Quinto-Su Pedro A, Lai Hsuan-Hong, Yoon Helen H, Sims Christopher E, Allbritton Nancy L, Venugopalan Vasan
Department of Chemical Engineering & Materials Science, University of California, Irvine, CA 92697, USA.
Lab Chip. 2008 Mar;8(3):408-14. doi: 10.1039/b715708h. Epub 2008 Jan 30.
We use time-resolved imaging to examine the lysis dynamics of non-adherent BAF-3 cells within a microfluidic channel produced by the delivery of single highly-focused 540 ps duration laser pulses at lambda = 532 nm. Time-resolved bright-field images reveal that the delivery of the pulsed laser microbeam results in the formation of a laser-induced plasma followed by shock wave emission and cavitation bubble formation. The confinement offered by the microfluidic channel constrains substantially the cavitation bubble expansion and results in significant deformation of the PDMS channel walls. To examine the cell lysis and dispersal of the cellular contents, we acquire time-resolved fluorescence images of the process in which the cells were loaded with a fluorescent dye. These fluorescence images reveal cell lysis to occur on the nanosecond to microsecond time scale by the plasma formation and cavitation bubble dynamics. Moreover, the time-resolved fluorescence images show that while the cellular contents are dispersed by the expansion of the laser-induced cavitation bubble, the flow associated with the bubble collapse subsequently re-localizes the cellular contents to a small region. This capacity of pulsed laser microbeam irradiation to achieve rapid cell lysis in microfluidic channels with minimal dilution of the cellular contents has important implications for their use in lab-on-a-chip applications.
我们使用时间分辨成像技术来研究非贴壁BAF-3细胞在微流控通道中的裂解动力学,该微流控通道是通过在λ = 532 nm处施加单个高聚焦的540 ps持续时间的激光脉冲产生的。时间分辨明场图像显示,脉冲激光微束的施加会导致激光诱导等离子体的形成,随后是冲击波发射和空化气泡的形成。微流控通道提供的限制极大地限制了空化气泡的膨胀,并导致PDMS通道壁发生显著变形。为了研究细胞裂解和细胞内容物的扩散,我们获取了细胞加载荧光染料过程的时间分辨荧光图像。这些荧光图像显示,细胞裂解通过等离子体形成和空化气泡动力学在纳秒到微秒的时间尺度上发生。此外,时间分辨荧光图像显示,虽然细胞内容物通过激光诱导空化气泡的膨胀而分散,但与气泡坍塌相关的流动随后将细胞内容物重新定位到一个小区域。脉冲激光微束照射在微流控通道中实现快速细胞裂解且细胞内容物稀释最小的这种能力,对其在芯片实验室应用中的使用具有重要意义。