Your search keyword '"Brattain LJ"' showing total 2 results

1. Axon Tracing and Centerline Detection using Topologically-Aware 3D U-Nets.

Author

Pollack D, Gjesteby LA, Snyder M, Chavez D, Kamentsky L, Chung K, and Brattain LJ

Subjects

Animals, Axons, Brain diagnostic imaging, Humans, Mice, Neural Networks, Computer, Algorithms, Imaging, Three-Dimensional methods

Abstract

As advances in microscopy imaging provide an ever clearer window into the human brain, accurate reconstruction of neural connectivity can yield valuable insight into the relationship between brain structure and function. However, human manual tracing is a slow and laborious task, and requires domain expertise. Automated methods are thus needed to enable rapid and accurate analysis at scale. In this paper, we explored deep neural networks for dense axon tracing and incorporated axon topological information into the loss function with a goal to improve the performance on both voxel-based segmentation and axon centerline detection. We evaluated three approaches using a modified 3D U-Net architecture trained on a mouse brain dataset imaged with light sheet microscopy and achieved a 10% increase in axon tracing accuracy over previous methods. Furthermore, the addition of centerline awareness in the loss function outperformed the baseline approach across all metrics, including a boost in Rand Index by 8%.

Published

2022

2. Real-time 4D ultrasound mosaicing and visualization.

Author

Brattain LJ and Howe RD

Subjects

Animals, Cardiac Surgical Procedures methods, Computer Graphics, Electromagnetic Phenomena, Image Processing, Computer-Assisted, Phantoms, Imaging, Software, Swine, Time Factors, Ultrasonics, User-Computer Interface, Electrocardiography methods, Heart physiology, Imaging, Three-Dimensional methods, Ultrasonography methods

Abstract

Intra-cardiac 3D ultrasound imaging has enabled new minimally invasive procedures. Its narrow field of view, however, limits its efficacy in guiding beating heart procedures where geometrically complex and spatially extended moving anatomic structures are often involved. In this paper, we present a system that performs electrocardiograph gated 4D mosaicing and visualization of 3DUS volumes. Real-time operation is enabled by GPU implementation. The method is validated on phantom and porcine heart data.

Published

2011