English

Super-resolution using Sparse Representations over Learned Dictionaries: Reconstruction of Brain Structure using Electron Microscopy

Computer Vision and Pattern Recognition 2012-10-03 v1 Neurons and Cognition Machine Learning

Abstract

A central problem in neuroscience is reconstructing neuronal circuits on the synapse level. Due to a wide range of scales in brain architecture such reconstruction requires imaging that is both high-resolution and high-throughput. Existing electron microscopy (EM) techniques possess required resolution in the lateral plane and either high-throughput or high depth resolution but not both. Here, we exploit recent advances in unsupervised learning and signal processing to obtain high depth-resolution EM images computationally without sacrificing throughput. First, we show that the brain tissue can be represented as a sparse linear combination of localized basis functions that are learned using high-resolution datasets. We then develop compressive sensing-inspired techniques that can reconstruct the brain tissue from very few (typically 5) tomographic views of each section. This enables tracing of neuronal processes and, hence, high throughput reconstruction of neural circuits on the level of individual synapses.

Keywords

Cite

@article{arxiv.1210.0564,
  title  = {Super-resolution using Sparse Representations over Learned Dictionaries: Reconstruction of Brain Structure using Electron Microscopy},
  author = {Tao Hu and Juan Nunez-Iglesias and Shiv Vitaladevuni and Lou Scheffer and Shan Xu and Mehdi Bolorizadeh and Harald Hess and Richard Fetter and Dmitri Chklovskii},
  journal= {arXiv preprint arXiv:1210.0564},
  year   = {2012}
}

Comments

12 pages, 11 figures

R2 v1 2026-06-21T22:14:15.145Z