PURPOSE: To introduce a framework that automatically identifies regions of anatomical abnormality within anatomical MR images and uses those regions in hypothesis-driven selection of seed points for fiber tracking with diffusion tensor (DT) imaging (DTI). MATERIALS AND METHODS: Regions of interest (ROIs) are first extracted from MR images using an automated algorithm for volume-preserved warping (VPW) that identifies localized volumetric differences across groups. ROIs then serve as seed points for fiber tracking in coregistered DT images. Another algorithm automatically clusters and compares morphologies of detected fiber bundles. We tested our framework using datasets from a group of patients with Tourette's syndrome (TS) and normal controls. RESULTS: Our framework automatically identified regions of localized volumetric differences across groups and then used those regions as seed points for fiber tracking. In our applied example, a comparison of fiber tracts in the two diagnostic groups showed that most fiber tracts failed to correspond across groups, suggesting that anatomical connectivity was severely disrupted in fiber bundles leading from regions of known anatomical abnormality. CONCLUSION: Our framework automatically detects volumetric abnormalities in anatomical MRIs to aid in generating a priori hypotheses concerning anatomical connectivity that then can be tested using DTI. Additionally, automation enhances the reliability of ROIs, fiber tracking, and fiber clustering.
PURPOSE: To introduce a framework that automatically identifies regions of anatomical abnormality within anatomical MR images and uses those regions in hypothesis-driven selection of seed points for fiber tracking with diffusion tensor (DT) imaging (DTI). MATERIALS AND METHODS: Regions of interest (ROIs) are first extracted from MR images using an automated algorithm for volume-preserved warping (VPW) that identifies localized volumetric differences across groups. ROIs then serve as seed points for fiber tracking in coregistered DT images. Another algorithm automatically clusters and compares morphologies of detected fiber bundles. We tested our framework using datasets from a group of patients with Tourette's syndrome (TS) and normal controls. RESULTS: Our framework automatically identified regions of localized volumetric differences across groups and then used those regions as seed points for fiber tracking. In our applied example, a comparison of fiber tracts in the two diagnostic groups showed that most fiber tracts failed to correspond across groups, suggesting that anatomical connectivity was severely disrupted in fiber bundles leading from regions of known anatomical abnormality. CONCLUSION: Our framework automatically detects volumetric abnormalities in anatomical MRIs to aid in generating a priori hypotheses concerning anatomical connectivity that then can be tested using DTI. Additionally, automation enhances the reliability of ROIs, fiber tracking, and fiber clustering.
Authors: B Stieltjes; W E Kaufmann; P C van Zijl; K Fredericksen; G D Pearlson; M Solaiyappan; S Mori Journal: Neuroimage Date: 2001-09 Impact factor: 6.556
Authors: Wiepke Cahn; Hilleke E Hulshoff Pol; Elleke B T E Lems; Neeltje E M van Haren; Hugo G Schnack; Jeroen A van der Linden; Patricia F Schothorst; Herman van Engeland; René S Kahn Journal: Arch Gen Psychiatry Date: 2002-11
Authors: Yong-Wook Shin; Dae Jin Kim; Tae Hyon Ha; Hae-Jeong Park; Won-Jin Moon; Eun Chul Chung; Jong Min Lee; In Young Kim; Sun I Kim; Jun Soo Kwon Journal: Neuroreport Date: 2005-05-31 Impact factor: 1.837
Authors: Kerstin J Plessen; Tore Wentzel-Larsen; Kenneth Hugdahl; Patricia Feineigle; Joel Klein; Lawrence H Staib; James F Leckman; Ravi Bansal; Bradley S Peterson Journal: Am J Psychiatry Date: 2004-11 Impact factor: 18.112
Authors: Bradley S Peterson; Prakash Thomas; Michael J Kane; Lawrence Scahill; Heping Zhang; Richard Bronen; Robert A King; James F Leckman; Lawrence Staib Journal: Arch Gen Psychiatry Date: 2003-04
Authors: Russell H Tobe; Ravi Bansal; Dongrong Xu; Xuejun Hao; Jun Liu; Juan Sanchez; Bradley S Peterson Journal: Ann Neurol Date: 2010-04 Impact factor: 10.422
Authors: Iliyan Ivanov; James W Murrough; Ravi Bansal; Xuejun Hao; Bradley S Peterson Journal: Neuropsychopharmacology Date: 2013-09-27 Impact factor: 7.853
Authors: Marc J Dubin; Marc Dubin; Myrna M Weissman; Myrna Weissman; Dongrong Xu; Ravi Bansal; Xuejun Hao; Jun Liu; Virginia Warner; Bradley S Peterson; Bradley Peterson Journal: Psychiatry Res Date: 2012-04-18 Impact factor: 3.222
Authors: Hilmar P Sigurdsson; Sophia E Pépés; Georgina M Jackson; Amelia Draper; Paul S Morgan; Stephen R Jackson Journal: Cortex Date: 2018-04-12 Impact factor: 4.027