Sulcus Extraction Based on MRI Images
Author: 
Ruyun XuAuthors Info & Claims
Abstract
The cortical folding of the brain refers to the highly convoluted folds formed during the developmental process of the brain cortex. These folds consist of depressed regions known as sulci and elevated regions called gyri. These sulci and gyri exhibit substantial individual variability while displaying a predominantly symmetric distribution across the left and right hemispheres, providing a certain regularity to the overall brain structure. Therefore, the accurate extraction of sulci becomes a crucial step in the study of the cortical surface of the brain. The sulcal pits, being the locally deepest and earliest-formed regions of the sulci, maintain their characteristics throughout development, demonstrating stability. In this study, we introduce a sulci extraction algorithm that utilizes the watershed algorithm combined with the adaptive thresholding method for extracting sulcal pits on the white matter mesh of the left and right hemispheres of the brain. Through merging operations to eliminate noisy sulcal pits, the algorithm achieves the extraction of shallower sulci in regions such as the inferior frontal sulcus, central sulcus, intraparietal sulcus, superior temporal sulcus, inferior temporal sulcus, lateral occipital sulcus, cingulate sulcus, subparietal sulcus and so on. The more precise extraction results of sulci contribute to an enhanced understanding of the brain's structure and function, providing more accurate and detailed information for neuroscience, medical research, and clinical applications, thereby propelling advancements in related fields.
References
[1]
SERGENT J. Brain-imaging studies of cognitive functions [J]. Trends in neurosciences, 1994, 17(6): 221-7.
[2]
HERMESSI H, MOURALI O, ZAGROUBA E. Multimodal medical image fusion review: Theoretical background and recent advances [J]. Signal Processing, 2021, 183: 108036.
[3]
ANDRADE N, FARIA F A, CAPPABIANCO F A M. A practical review on medical image registration: From rigid to deep learning based approaches; proceedings of the 2018 31st SIBGRAPI Conference on Graphics, Patterns and Images (SIBGRAPI), F, 2018 [C]. IEEE.
[4]
ARNOLD T C, FREEMAN C W, LITT B, Low‐field MRI: Clinical promise and challenges [J]. Journal of Magnetic Resonance Imaging, 2023, 57(1): 25-44.
[5]
ZILLES K, PALOMERO-GALLAGHER N, AMUNTS K. Development of cortical folding during evolution and ontogeny [J]. Trends in neurosciences, 2013, 36(5): 275-84.
[6]
VAN DER MEER D, KAUFMANN T, SHADRIN A A, The genetic architecture of human cortical folding [J]. Science advances, 2021, 7(51): eabj9446.
[7]
DE VAREILLES H, RIVIèRE D, MANGIN J, Development of cortical folds in the human brain: an attempt to review biological hypotheses, early neuroimaging investigations and functional correlates [J]. Developmental Cognitive Neuroscience, 2023: 101249.
[8]
DEMIRCI N, HOLLAND M A. Cortical thickness systematically varies with curvature and depth in healthy human brains [J]. Human Brain Mapping, 2022, 43(6): 2064-84.
[9]
JIANG X, ZHANG T, ZHANG S, Fundamental functional differences between gyri and sulci: implications for brain function, cognition, and behavior [J]. Psychoradiology, 2021, 1(1): 23-41.
[10]
RIBAS E C, RIBAS G C. Surgical Anatomy of the Sulci and Gyrus of the Brain Check for updates [J]. Brain Anatomy and Neurosurgical Approaches: A Practical, Illustrated, Easy-to-Use Guide, 2023: 89.
[11]
RIBAS G C. The cerebral sulci and gyri [J]. Neurosurgical focus, 2010, 28(2): E2.
[12]
RéGIS J, MANGIN J-F, FROUIN V, Generic model for the localization of the cerebral cortex and preoperative multimodal integration in epilepsy surgery [J]. Stereotactic and Functional Neurosurgery, 1995, 65(1-4): 72-80.
[13]
RéGIS J, MANGIN J-F, OCHIAI T, “Sulcal root” generic model: a hypothesis to overcome the variability of the human cortex folding patterns [J]. Neurologia medico-chirurgica, 2005, 45(1): 1-17.
[14]
CACHIA A, MANGIN J-F, RIVIERE D, A primal sketch of the cortex mean curvature: a morphogenesis based approach to study the variability of the folding patterns [J]. IEEE transactions on medical imaging, 2003, 22(6): 754-65.
[15]
LOHMANN G, VON CRAMON D Y, COLCHESTER A C. Deep sulcal landmarks provide an organizing framework for human cortical folding [J]. Cerebral Cortex, 2008, 18(6): 1415-20.
[16]
HASNAIN M K, FOX P T, WOLDORFF M G. Structure–function spatial covariance in the human visual cortex [J]. Cerebral cortex, 2001, 11(8): 702-16.
[17]
IM K, JO H J, MANGIN J-F, Spatial distribution of deep sulcal landmarks and hemispherical asymmetry on the cortical surface [J]. Cerebral cortex, 2010, 20(3): 602-11.
[18]
KAO C-Y, HOFER M, SAPIRO G, A geometric method for automatic extraction of sulcal fundi [J]. IEEE transactions on medical imaging, 2007, 26(4): 530-40.
[19]
YUN H J, IM K, YANG J-J, Automated sulcal depth measurement on cortical surface reflecting geometrical properties of sulci [J]. PloS one, 2013, 8(2): e55977.
[20]
BOUCHER M, WHITESIDES S, EVANS A. Depth potential function for folding pattern representation, registration and analysis [J]. Medical image analysis, 2009, 13(2): 203-14.
[21]
LE GUEN Y, AUZIAS G, LEROY F, Genetic influence on the sulcal pits: on the origin of the first cortical folds [J]. Cerebral Cortex, 2018, 28(6): 1922-33.
[22]
AUZIAS G, BRUN L, DERUELLE C, Deep sulcal landmarks: algorithmic and conceptual improvements in the definition and extraction of sulcal pits [J]. Neuroimage, 2015, 111: 12-25.
[23]
KALTENMARK I, DERUELLE C, BRUN L, Group-level cortical surface parcellation with sulcal pits labeling [J]. Medical image analysis, 2020, 66: 101749.
[24]
KLEIN A, ANDERSSON J, ARDEKANI B A, Evaluation of 14 nonlinear deformation algorithms applied to human brain MRI registration [J]. Neuroimage, 2009, 46(3): 786-802.
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Published In
May 2024
324 pages
ISBN:9798400716386
DOI:10.1145/3674558
Copyright © 2024 ACM.
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Published: 26 August 2024
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ICCTA 2024
ICCTA 2024: 2024 10th International Conference on Computer Technology Applications
May 15 - 17, 2024
Vienna, Austria
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