Abstract
To be able to trap and image in a live cell / organism on the go is an incredible feat and paves the way for immobilization-free interrogation. This is a step towards the interrogation of cells / live species in their natural environment. To facilitate, aTRIMingtechnique primarily based on an adaptive lightsheet optical tweezer (aLOT) system is proposed. The TRIMing technique combines the benefits of touch-free optical tweezing and high-resolution imaging. The entire system is built on a single platform for rapid interrogation of freely moving live biological specimens. The trapping system combines an electrical-tunable lens (ETL), cylindrical lens, and an objective lens to generate adaptive PSF. The ETL (in the beam-expander) adaptively changes the beam cross-section (to either a parallel beam or converging point-beam) entering the back-aperture of cylindrical lens, resulting in a point or a line spot at the focus. An objective lens placed at the focus of a cylindrical lens converts the spot to a tightly focused diffraction-limited lightsheet or point PSF. Depending on the object type (spherical or elongated), the system can flip between point and sheet PSF at a rate of 200Hz. The system is integrated to a separate fluorescence arm to enable the imaging of trapped objects (cells or organisms). TheTRIMingsystem operates in a brightfield mode to optically trap using point / sheet PSF and subsequently switched to fluorescence mode for imaging. The potential of the system is demonstrated by trapping live specimens (HeLa cells and C. elegans labelled with Bodipy dye) and imaging them in a freely moving environment. Characterization shows a point and sheet PSF size of, 43.42μm2and 70.5×4.9μm2with a trap stiffness of 1.15×10−3pN/nmand 0.46×10−3pN/nm, respectively. Fluorescently-labelled live specimens were investigated that showed the random distribution of organelles (lipid droplets) both in cells and C. elegans. TheTRIMingsystem demonstrated a resolution of<0.7μm, a contrast of ≈ 0.84, a SNR of ≈ 11dB. This allows a good combination of rapid trapping and high-quality imaging. In addition, the system allows near real-time determination of critical biophysical parameters, such as organelle size of 1.01μm(in cells) and 1.29μm(in C. elegans) with a density of 0.021#/μm2and 0.039#/μm2, respectively. The number of lipid droplets are found to be nearly double for C. elegans as compared to HeLa cells. These parameters are directly linked to the physiological state of live biological species. Overall, the developedTRIMingsystem allows high-quality imaging of live specimens in a free living environment.Statement of SignificanceThe ability to image live specimens in a free-living environment is phenomenal. The existing techniques often constrain/fix/anesthetize these organisms to image their physiological state. This comes with a lot of conditioning and directly affects the physiological state or developmental process in biological species, especially the brain undergoing neuronal activity. The proposedTRIMingtechnique elevates this requirement by optically trapping the moving object and simultaneously imaging the internal organelles with high resolution in a free environment. The technique is expected to have widespread applications in diverse disciplines ranging from fundamental cell biology to optical physics.
Publisher
Cold Spring Harbor Laboratory