Abstract

Standard structural brain imaging protocols result in images that cannot resolve structures smaller than 1- 2mm in size. Achieving significantly higher resolution would be of fundamental clinical and neuroscientific value, as it would allow the in-vivo detection and analysis of cytoarchitectural features of the cortex, as well as substructures of brain regions such as the hippocampus, thalamus and amygdala. Unfortunately, such resolution is extremely difficult to obtain in-vivo, as the signal-to-noise ratio goes down with the third power of the linear dimension of each voxel. While some recent studies have pushed this limit to under 1A mm, this is at the cost of extremely long scan sessions and specialized imaging hardware, and even this is still a coarse resolution relative to what is required to visualize correlates of the cytoarchitecture with MRI. Here we take a different approach, and propose to image ex-vivo tissue samples, both blocks of tissue and whole hemispheres, in which exceedingly high-resolution is obtainable, on the order of lOOujns. In these images, many MR signatures of cytoarchitectural features are apparent, and hence they can be used for the construction of models including these cytoarchitectonically defined boundaries. For those features that are not distinguishable from the MR, we propose to perform histological analysis of the tissue, and use cross modal registration techniques to transfer the information from the histology back to the models. High dimensional mapping procedures are then proposed to map these models, obtained from ultra high-resolution imaging and histology, back to the more standard resolution in-vivo data to predict the probability of a given cytoarchitectural boundary occurring at each location in the in-vivo data. We focus on cortical areas in the medial temporal lobe as they are of great clinical relevance, as they are thought to be one of the earliest loci of Alzheimer's disease, and are critical to normal memory function. The ability to more accurately localize these cortical regions would be a critical step in the early diagnosis of AD, and in the assessment of the efficacy of potential clinical interventions.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
3R01EB006758-03S1
Application #
7848763
Study Section
Biomedical Imaging Technology Study Section (BMIT)
Program Officer
Cohen, Zohara
Project Start
2007-08-13
Project End
2009-10-31
Budget Start
2009-06-05
Budget End
2009-10-31
Support Year
3
Fiscal Year
2009
Total Cost
$36,608
Indirect Cost

  Institution

Name
Massachusetts General Hospital
Department
Type
DUNS #
073130411
City
Boston
State
MA
Country
United States
Zip Code
02199

  Publications

Greve, Douglas N; Fischl, Bruce (2018) False positive rates in surface-based anatomical analysis. Neuroimage 171:6-14
Bianciardi, Marta; Strong, Christian; Toschi, Nicola et al. (2018) A probabilistic template of human mesopontine tegmental nuclei from in vivo 7T MRI. Neuroimage 170:222-230
Aganj, Iman; Harisinghani, Mukesh G; Weissleder, Ralph et al. (2018) Unsupervised Medical Image Segmentation Based on the Local Center of Mass. Sci Rep 8:13012
Wu, Jianxiao; Ngo, Gia H; Greve, Douglas et al. (2018) Accurate nonlinear mapping between MNI volumetric and FreeSurfer surface coordinate systems. Hum Brain Mapp :
Fischl, Bruce; Sereno, Martin I (2018) Microstructural parcellation of the human brain. Neuroimage 182:219-231
Rosas, H D; Wilkens, P; Salat, D H et al. (2018) Complex spatial and temporally defined myelin and axonal degeneration in Huntington disease. Neuroimage Clin 20:236-242
Magnain, Caroline; Augustinack, Jean C; Tirrell, Lee et al. (2018) Colocalization of neurons in optical coherence microscopy and Nissl-stained histology in Brodmann's area 32 and area 21. Brain Struct Funct :
Li, Yi; Barkovich, Matthew J; Karch, Celeste M et al. (2018) Regionally specific TSC1 and TSC2 gene expression in tuberous sclerosis complex. Sci Rep 8:13373
Siless, Viviana; Chang, Ken; Fischl, Bruce et al. (2018) AnatomiCuts: Hierarchical clustering of tractography streamlines based on anatomical similarity. Neuroimage 166:32-45
Polimeni, Jonathan R; Renvall, Ville; Zaretskaya, Natalia et al. (2018) Analysis strategies for high-resolution UHF-fMRI data. Neuroimage 168:296-320

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