Your search keyword '"Adam W Hantman"' showing total 2 results

1. Neuropixels 2.0: A miniaturized high-density probe for stable, long-term brain recordings

Author

John O'Callaghan, Maxime Beau, Fabian Kloosterman, Abraham Z. Vollan, Anna Lebedeva, Michael Häusser, Susu Chen, Joshua T. Dudman, John O'Keefe, Cagatay Aydin, Timothy D. Harris, Albert K. Lee, Nicholas A. Steinmetz, Jan Putzeys, Kenneth D. Harris, Rik van Daal, Carolina Mora-Lopez, Matteo Carandini, Zhiwen Ye, Marius Pachitariu, Karel Svoboda, Marius Bauza, Jennifer Colonell, Dimitar Kostadinov, Claudia Böhm, Martijn Broux, Edvard I. Moser, Michael S. Okun, B. Dutta, Alfonso Renart, Adam W. Hantman, Richard J. Gardner, Shiwei Wang, Sebastian Haesler, Bill Karsh, Britton Sauerbrei, Jai Bhagat, Junchol Park, and Marleen Welkenhuysen

Subjects

Male, Neurons, Miniaturization, Multidisciplinary, Post hoc, Computer science, Extramural, Action Potentials, Brain, High density, Article, Electrodes, Implanted, Rats, Term (time), Electrophysiology, Mice, Inbred C57BL, Mice, Neural processing, Animals, Microelectrodes, Algorithms, Biomedical engineering

Abstract

Recording many neurons for a long time The ultimate aim of chronic recordings is to sample from the same neuron over days and weeks. However, this goal has been difficult to achieve for large populations of neurons. Steinmetz et al. describe the development and testing of Neuropixels 2.0. This new electrophysiological recording tool is a miniaturized, high-density probe for both acute and long-term experiments combined with sophisticated software algorithms for fully automatic post hoc computational stabilization. The technique also provides a strategy for extending the number of recorded sites beyond the number of available recording channels. In freely moving animals, extremely large numbers of individual neurons could thus be followed and tracked with the same probe for weeks and occasionally months. Science , this issue p. eabf4588

Published

2021

2. Cortical column and whole-brain imaging with molecular contrast and nanoscale resolution

Author

Eric Betzig, Igor Pisarev, Srigokul Upadhyayula, Shu-Hsien Sheu, Yongxin Zhao, Austin R. Graves, Christopher T. Zugates, Sean G. Megason, John A. Bogovic, Harald F. Hess, Adam W. Hantman, Song Pang, C. Shan Xu, Susan Tappan, Kishore R. Mosaliganti, Yoshinori Aso, Ved P. Singh, Shoh Asano, Jennifer Lippincott-Schwartz, Carolyn Ott, Gerald M. Rubin, H. Amalia Pasolli, Jennifer Colonell, Edward S. Boyden, Daniel E. Milkie, Grace H. Huynh, Tom Kirchhausen, Stephan Saalfeld, Alfredo Rodriguez, Tsung-Li Liu, and Ruixuan Gao

Subjects

Male, 0301 basic medicine, Dendritic spine, Materials science, Dendritic Spines, Confocal, Mice, Transgenic, Neuroimaging, Kidney, Imaging phantom, Mice, 03 medical and health sciences, Imaging, Three-Dimensional, 0302 clinical medicine, Microscopy, Image Processing, Computer-Assisted, Fluorescence microscope, medicine, Biological neural network, Animals, Humans, Nanotechnology, Multidisciplinary, Phantoms, Imaging, Optical Imaging, Brain, Somatosensory Cortex, Photobleaching, Axons, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, Microscopy, Fluorescence, Synapses, Biophysics, Drosophila, Female, Cortical column, 030217 neurology & neurosurgery

Abstract

INTRODUCTION Neural circuits across the brain are composed of structures spanning seven orders of magnitude in size that are assembled from thousands of distinct protein types. Electron microscopy has imaged densely labeled brain tissue at nanometer-level resolution over near-millimeter-level dimensions but lacks the contrast to distinguish specific proteins and the speed to readily image multiple specimens. Conversely, confocal fluorescence microscopy offers molecular contrast but has insufficient resolution for dense neural tracing or the precise localization of specific molecular players within submicrometer-sized structures. Last, superresolution fluorescence microscopy bleaches fluorophores too quickly for large-volume imaging and also lacks the speed for effective brain-wide or cortex-wide imaging of multiple specimens. RATIONALE We combined two imaging technologies to address these issues. Expansion microscopy (ExM) creates an expanded, optically clear phantom of a fluorescent specimen that retains its original relative distribution of fluorescent tags. Lattice light-sheet microscopy (LLSM) then images this phantom in three dimensions with minimal photobleaching at speeds sufficient to image the entire Drosophila brain or across the width of the mouse cortex in ∼2 to 3 days, with multiple markers at an effective resolution of ∼60 by 60 by 90 nm for 4× expansion. RESULTS We applied expansion/LLSM (ExLLSM) to study a variety of subcellular structures in the brain. In the mouse cortex, we quantified the volume of organelles, measured morphological parameters of ~1500 dendritic spines, determined the variation of distances between pre- and postsynaptic proteins, observed large differences in postsynaptic expression at adjacent pyramidal neurons, and studied both the azimuthal asymmetry and layer-specific longitudinal variation of axonal myelination. In Drosophila , we traced the axonal branches of olfactory projection neurons across one hemisphere and studied the stereotypy of their boutons at the calyx and lateral horn across five animals. We also imaged all dopaminergic neurons (DANs) across the brain of another specimen, visualized DAN morphologies in all major brain regions, and traced a cluster of eight DANs to their termini to determine their respective cell types. In the same specimen, we also determined the number of presynaptic active zones (AZs) across the brain and the local density of all AZs and DAN-associated AZs in each brain region. CONCLUSION With its high speed, nanometric resolution, and ability to leverage genetically targeted, cell type–specific, and protein-specific fluorescence labeling, ExLLSM fills a valuable niche between the high throughput of conventional optical pipelines of neural anatomy and the ultrahigh resolution of corresponding EM pipelines. Assuming the development of fully validated, brain-wide isotropic expansion at 10× or beyond and sufficiently dense labeling, ExLLSM may enable brainwide comparisons of even densely innervated neural circuits across multiple specimens with protein-specific contrast at 25-nm resolution or better.

Published

2019