Your search keyword '"Daniel E. Milkie"' showing total 3 results

1. High-density three-dimensional localization microscopy across large volumes

Author

Wesley R. Legant, Jonathan B. Grimm, Luke D. Lavis, Eric Betzig, Timothy A. Brown, Lin Shao, Brian B. Avants, and Daniel E. Milkie

Subjects

0301 basic medicine, Fluorescence-lifetime imaging microscopy, Materials science, High density, High resolution, Cell Biology, Biochemistry, Imaging modalities, Cell biology, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Membrane, Microscopy, Zebrafish embryo, Correlative imaging, Molecular Biology, 030217 neurology & neurosurgery, Biotechnology, Biomedical engineering

Abstract

Extending three-dimensional (3D) single-molecule localization microscopy away from the coverslip and into thicker specimens will greatly broaden its biological utility. However, because of the limitations of both conventional imaging modalities and conventional labeling techniques, it is a challenge to localize molecules in three dimensions with high precision in such samples while simultaneously achieving the labeling densities required for high resolution of densely crowded structures. Here we combined lattice light-sheet microscopy with newly developed, freely diffusing, cell-permeable chemical probes with targeted affinity for DNA, intracellular membranes or the plasma membrane. We used this combination to perform high-localization precision, ultrahigh-labeling density, multicolor localization microscopy in samples up to 20 μm thick, including dividing cells and the neuromast organ of a zebrafish embryo. We also demonstrate super-resolution correlative imaging with protein-specific photoactivable fluorophores, providing a mutually compatible, single-platform alternative to correlative light-electron microscopy over large volumes.

Published

2016

2. Adaptive optics via pupil segmentation for high-resolution imaging in biological tissues

Author

Eric Betzig, Na Ji, and Daniel E. Milkie

Subjects

genetic structures, Computer science, Sensitivity and Specificity, Biochemistry, Signal, law.invention, Biological specimen, Optics, law, Microscopy, Segmentation, Adaptive optics, Molecular Biology, Lighting, Lenses, business.industry, Resolution (electron density), Reproducibility of Results, Equipment Design, Cell Biology, Image Enhancement, Equipment Failure Analysis, Lens (optics), Microscopy, Fluorescence, Multiphoton, Computer-Aided Design, Artifacts, Focus (optics), business, Biotechnology

Abstract

Biological specimens are rife with optical inhomogeneities that seriously degrade imaging performance under all but the most ideal conditions. Measuring and then correcting for these inhomogeneities is the province of adaptive optics. Here we introduce an approach to adaptive optics in microscopy wherein the rear pupil of an objective lens is segmented into subregions, and light is directed individually to each subregion to measure, by image shift, the deflection faced by each group of rays as they emerge from the objective and travel through the specimen toward the focus. Applying our method to two-photon microscopy, we could recover near-diffraction-limited performance from a variety of biological and nonbiological samples exhibiting aberrations large or small and smoothly varying or abruptly changing. In particular, results from fixed mouse cortical slices illustrate our ability to improve signal and resolution to depths of 400 microm.

Published

2009

3. Multiplexed aberration measurement for deep tissue imaging in vivo

Author

Douglas S. Kim, Rui Liu, Zhongchao Tan, Daniel E. Milkie, Tsai Wen Chen, Chen Wang, Na Ji, Wenzhi Sun, and Aaron M. Kerlin

Subjects

Fluorescence-lifetime imaging microscopy, Optics and Photonics, Light, Phase (waves), Neuroimaging, Biochemistry, Article, Histones, Mice, Optics, Microscopy, Animals, Adaptive optics, Caenorhabditis elegans, Molecular Biology, Zebrafish, Fluorescent Dyes, Visual Cortex, Physics, Fourier Analysis, business.industry, Scattering, Resolution (electron density), Brain, Proteins, Pupil, Cell Biology, Ray, Functional imaging, Mice, Inbred C57BL, Microscopy, Fluorescence, business, Protein Processing, Post-Translational, Biotechnology

Abstract

We describe a multiplexed aberration measurement method that modulates the intensity or phase of light rays at multiple pupil segments in parallel to determine their phase gradients. Applicable to fluorescent-protein-labeled structures of arbitrary complexity, it allows us to obtain diffraction-limited resolution in various samples in vivo. For the strongly scattering mouse brain, a single aberration correction improves structural and functional imaging of fine neuronal processes over a large imaging volume.

Published

2014