Optical trapping by a single focused laser beam is used as a tool to manipulate individual microparticles and living cells, while nanoparticles are trapped as a single small assembly in solution. However, the picture is completely different at interface.¹⁾ The nano- and micro-particles are gathered along the interface, giving a single extremely large disk-like assembly. Its size reaches a few ten micrometers, which is interpreted in terms of scattering and propagation of the trapping laser along the interface. Recently we reported that a similar behavior is induced for protein lysozyme solution and its assembly size is a sub-millimeter in diameter and a few ten micrometers in depth.²⁾
Here we apply simultaneous transmission and fluorescence imaging and elucidate no-linear assembling nature with respect to trapping laser power and protein concentration. Upon irradiation a “white ring” appears from the focus in the transmission image and expands to the outside over a few ten micrometers. The fluorescence imaging of a dye-bonded lysozyme directly reveals the assembling behavior, while it is visualized by monitoring the movement of added polystyrene microparticles. Based on these results, we propose a two-stage mechanism; 1) formation and widening of a shallow lysozyme layer and 2) the later trapping of lysozyme clusters expelling the lysozyme layer from the focus.
1. H. Masuhara, K. Yuyama, Annu. Rev. Phys. Chem., 2021, 72, 565-589
2. P.-W. Yi et al., J. Phys. Chem. C, 2021, 125, 18988-18999