Lightsheet Optical Tweezer (LOT) for Optical Manipulation of Microscopic Particles and Live Cells

Abstract

A light sheet based optical tweezer (LOT) is developed to trap microscopic dielectric particles and live HeLa cells. The technique requires the generation of a tightly focussed diffraction-limited light sheet which is realized by a combination of cylindrical lens and high NA objective lens. The field pattern generated at the geometrical focus is a tightly focussed line (along x-axis) perpendicular to the beam propagation direction (z-axis). Spherical beads undergoing Brownian motion in the solution are trapped by the gradient potential, and the time (to reach trap-center under the influence of gradient potential) is estimated from the fast CMOS camera (operating at 230frames/sec). High-speed imaging of beads at varying laser power shows a steady increase in the stiffness of LOT with a maximum of 0.00118 pN/nm at 52.5 mW. This is an order less than traditional optical point-traps. The trapped beads displayed free movement along the light-sheet axis (x-axis), exhibiting a single degree of freedom. Subsequently, LOT is used to optically trap and pattern dielectric beads and HeLa cells in a line. We could successfully pattern 8 dielectric beads and 3 HeLa cells in a straight line. We anticipate that LOT can be used to study the 1D-physics of microscopic particles and help understand the patterned growth of live cells.