Crecea Vasilica, Graf Benedikt W, Kim Taewoo, Popescu Gabriel, Boppart Stephen A
Department of Physics, University of Illinois at Urbana-Champaign, Urbana, IL 61801 USA (
University of Illinois at Urbana-Champaign, Urbana, IL 61801 USA. He is now with NinePoint Medical, Cambridge, MA 02139 USA (
IEEE J Sel Top Quantum Electron. 2014 Mar;20(2). doi: 10.1109/JSTQE.2013.2280501.
We present a real-time multimodal near-infrared imaging technology that tracks externally induced axial motion of magnetic microbeads in single cells in culture. The integrated multimodal imaging technique consists of phase-sensitive magnetomotive optical coherence microscopy (MM-OCM) and multiphoton microscopy (MPM).MPMis utilized for the visualization of multifunctional fluorescent and magnetic microbeads, while MM-OCM detects, with nanometer-scale sensitivity, periodic displacements of the microbeads induced by the modulation of an external magnetic field. Magnetomotive signals are measured from mouse macrophages, human breast primary ductal carcinoma cells, and human breast epithelial cells in culture, and validated with full-field phase-sensitive microscopy. This methodology demonstrates the capability for imaging controlled cell dynamics and has the potential for measuring cell biomechanical properties, which are important in assessing the health and pathological state of cells.
我们展示了一种实时多模态近红外成像技术,该技术可追踪培养的单细胞中磁性微珠的外部诱导轴向运动。集成的多模态成像技术由相敏磁动力光学相干显微镜(MM-OCM)和多光子显微镜(MPM)组成。MPM用于可视化多功能荧光和磁性微珠,而MM-OCM以纳米级灵敏度检测由外部磁场调制引起的微珠周期性位移。从培养的小鼠巨噬细胞、人乳腺原发性导管癌细胞和人乳腺上皮细胞中测量磁动力信号,并用全场相敏显微镜进行验证。这种方法证明了对受控细胞动力学进行成像的能力,并且具有测量细胞生物力学特性的潜力,这对于评估细胞的健康和病理状态很重要。