Abstract: A microscope directs light through an excitation objective to generate a lattice light sheet (LLS) within a sample. A detection objective collects signal light from the sample in response to the LLS and images the collected light onto a detector. Second and third light beams are imaged onto focal planes of the excitation objective and detection objective, respectively. One or more wavefront detectors determine wavefronts of light emitted from the sample and through the excitation objective in response to the imaged second light beam and emitted from the sample through the detection objective in response to the imaged third light beam. A wavefront of the first light beam is modified to reduce a sample-induced aberration of the LLS within the sample, and a wavefront of the signal light emitted from the sample is modified to reduce a sample-induced aberration of the signal light at the detector.

Abstract: A microscope directs light through an excitation objective to generate a lattice light sheet (LLS) within a sample. A detection objective collects signal light from the sample in response to the LLS and images the collected light onto a detector. Second and third light beams are imaged onto focal planes of the excitation objective and detection objective, respectively. One or more wavefront detectors determine wavefronts of light emitted from the sample and through the excitation objective in response to the imaged second light beam and emitted from the sample through the detection objective in response to the imaged third light beam. A wavefront of the first light beam is modified to reduce a sample-induced aberration of the LLS within the sample, and a wavefront of the signal light emitted from the sample is modified to reduce a sample-induced aberration of the signal light at the detector.

Abstract: A sample is bathed in a solution that includes labels having a binding affinity for a structure on the sample and that emit light in response to excitation light. A sheet of excitation light having a FWHM thickness is provided to the sample. Light emitted from labels in response to the excitation light is imaged onto a detector, where the light is imaged with a detection objective having a depth of focus comparable to or greater than the FWHM thickness. The bathing of the sample and the imaging of the light emitted from the bound labels is controlled, such that the imaged light from different individual labels bound to the structure is resolved on the detector. The providing, imaging, and controlling are repeated to image, at different times, light from labels bound to the structure at different locations on or within the sample.

Abstract: A microscope directs light through an excitation objective to generate a lattice light sheet (LLS) within a sample. A detection objective collects signal light from the sample in response to the LLS and images the collected light onto a detector. Second and third light beams are imaged onto focal planes of the excitation objective and detection objective, respectively. One or more wavefront detectors determine wavefronts of light emitted from the sample and through the excitation objective in response to the imaged second light beam and emitted from the sample through the detection objective in response to the imaged third light beam. A wavefront of the first light beam is modified to reduce a sample-induced aberration of the LLS within the sample, and a wavefront of the signal light emitted from the sample is modified to reduce a sample-induced aberration of the signal light at the detector.

Abstract: Techniques for generating microtissues, including a micro-fabricated platform including at least one micro-well including a plurality of micro-cantilevers coupled thereto and surrounded by a plurality of ridges, each micro-cantilever including a cap at a terminal end thereof. The platform can be immersed in a suspension of cells. The suspension of cells can be driven into at least one micro-well, and the ridges can be de-wetted to remove excess suspension and isolate the suspension of cells in each micro-well. The cells can be driven in the suspension of each micro-well toward a top surface of the suspension, which can be polymerized to form a matrix. The cells can be cultivated to spontaneously compact the matrix such that the micro-cantilevers anchor and constrain the contracting matrix to form a band of microtissue that spans across the micro-cantilevers.

Abstract: A sample is bathed in a solution that includes labels having a binding affinity for a structure on the sample and that emit light in response to excitation light. A sheet of excitation light having a FWHM thickness is provided to the sample. Light emitted from labels in response to the excitation light is imaged onto a detector, where the light is imaged with a detection objective having a depth of focus comparable to or greater than the FWHM thickness. The bathing of the sample and the imaging of the light emitted from the bound labels is controlled, such that the imaged light from different individual labels bound to the structure is resolved on the detector. The providing, imaging, and controlling are repeated to image, at different times, light from labels bound to the structure at different locations on or within the sample.

Abstract: Techniques for generating microtissues, including a micro-fabricated platform including at least one micro-well including a plurality of micro-cantilevers coupled thereto and surrounded by a plurality of ridges, each micro-cantilever including a cap at a terminal end thereof. The platform can be immersed in a suspension of cells. The suspension of cells can be driven into at least one micro-well, and the ridges can be de-wetted to remove excess suspension and isolate the suspension of cells in each micro-well. The cells can be driven in the suspension of each micro-well toward a top surface of the suspension, which can be polymerized to form a matrix. The cells can be cultivated to spontaneously compact the matrix such that the micro-cantilevers anchor and constrain the contracting matrix to form a band of microtissue that spans across the micro-cantilevers.