Your search keyword '"Duncan LH"' showing total 2 results

1. Multiview confocal super-resolution microscopy.

Author

Wu Y, Han X, Su Y, Glidewell M, Daniels JS, Liu J, Sengupta T, Rey-Suarez I, Fischer R, Patel A, Combs C, Sun J, Wu X, Christensen R, Smith C, Bao L, Sun Y, Duncan LH, Chen J, Pommier Y, Shi YB, Murphy E, Roy S, Upadhyaya A, Colón-Ramos D, La Riviere P, and Shroff H

Subjects

Animals, Caenorhabditis elegans cytology, Caenorhabditis elegans embryology, Caenorhabditis elegans growth & development, Cell Line, Tumor, Drosophila melanogaster cytology, Drosophila melanogaster growth & development, Humans, Imaginal Discs cytology, Mice, Myoblasts cytology, Organ Specificity, Single-Cell Analysis, Tissue Fixation, Deep Learning, Microscopy, Confocal methods, Microscopy, Confocal standards

Abstract

Confocal microscopy 1 remains a major workhorse in biomedical optical microscopy owing to its reliability and flexibility in imaging various samples, but suffers from substantial point spread function anisotropy, diffraction-limited resolution, depth-dependent degradation in scattering samples and volumetric bleaching 2 . Here we address these problems, enhancing confocal microscopy performance from the sub-micrometre to millimetre spatial scale and the millisecond to hour temporal scale, improving both lateral and axial resolution more than twofold while simultaneously reducing phototoxicity. We achieve these gains using an integrated, four-pronged approach: (1) developing compact line scanners that enable sensitive, rapid, diffraction-limited imaging over large areas; (2) combining line-scanning with multiview imaging, developing reconstruction algorithms that improve resolution isotropy and recover signal otherwise lost to scattering; (3) adapting techniques from structured illumination microscopy, achieving super-resolution imaging in densely labelled, thick samples; (4) synergizing deep learning with these advances, further improving imaging speed, resolution and duration. We demonstrate these capabilities on more than 20 distinct fixed and live samples, including protein distributions in single cells; nuclei and developing neurons in Caenorhabditis elegans embryos, larvae and adults; myoblasts in imaginal disks of Drosophila wings; and mouse renal, oesophageal, cardiac and brain tissues., (© 2021. This is a U.S. government work and not under copyright protection in the U.S.; foreign copyright protection may apply.)

Published

2021

2. Structural and developmental principles of neuropil assembly in C. elegans.

Author

Moyle MW, Barnes KM, Kuchroo M, Gonopolskiy A, Duncan LH, Sengupta T, Shao L, Guo M, Santella A, Christensen R, Kumar A, Wu Y, Moon KR, Wolf G, Krishnaswamy S, Bao Z, Shroff H, Mohler WA, and Colón-Ramos DA

Subjects

Algorithms, Animals, Brain cytology, Brain embryology, Caenorhabditis elegans chemistry, Caenorhabditis elegans cytology, Cell Movement, Diffusion, Interneurons metabolism, Motor Neurons metabolism, Neurites metabolism, Neuropil cytology, Sensory Receptor Cells metabolism, Caenorhabditis elegans embryology, Caenorhabditis elegans metabolism, Neuropil chemistry, Neuropil metabolism

Abstract

Neuropil is a fundamental form of tissue organization within the brain 1 , in which densely packed neurons synaptically interconnect into precise circuit architecture 2,3 . However, the structural and developmental principles that govern this nanoscale precision remain largely unknown 4,5 . Here we use an iterative data coarse-graining algorithm termed 'diffusion condensation' 6 to identify nested circuit structures within the Caenorhabditis elegans neuropil, which is known as the nerve ring. We show that the nerve ring neuropil is largely organized into four strata that are composed of related behavioural circuits. The stratified architecture of the neuropil is a geometrical representation of the functional segregation of sensory information and motor outputs, with specific sensory organs and muscle quadrants mapping onto particular neuropil strata. We identify groups of neurons with unique morphologies that integrate information across strata and that create neural structures that cage the strata within the nerve ring. We use high resolution light-sheet microscopy 7,8 coupled with lineage-tracing and cell-tracking algorithms 9,10 to resolve the developmental sequence and reveal principles of cell position, migration and outgrowth that guide stratified neuropil organization. Our results uncover conserved structural design principles that underlie the architecture and function of the nerve ring neuropil, and reveal a temporal progression of outgrowth-based on pioneer neurons-that guides the hierarchical development of the layered neuropil. Our findings provide a systematic blueprint for using structural and developmental approaches to understand neuropil organization within the brain.

Published

2021