TY - JOUR
T1 - SHARM: Segmented Head Anatomical Reference Models
AU - Rashed, Essam A.
AU - Al-Shatouri, Mohammad
AU - Laakso, Ilkka
AU - Kodera, Sachiko
AU - Hirata, Akimasa
N1 - Publisher Copyright:
© 2025 Elsevier Ltd
PY - 2025/6
Y1 - 2025/6
N2 - Reliable segmentation of anatomical tissues in the human head is a crucial step in various clinical applications, including brain mapping, surgery planning, and computational simulation studies. Segmentation involves identifying different anatomical structures by labeling various tissues using different medical imaging modalities. While the segmentation of brain structures has seen significant progress, non-brain tissues receive less attention due to anatomical complexity and difficulties in observation using standard medical imaging protocols. The lack of comprehensive head segmentation methods and large segmented datasets limits variability studies, particularly in computational evaluations of electrical brain stimulation (neuromodulation), protection from electromagnetic fields, and electroencephalography, where non-brain tissues are essential. To address this gap, this study introduces the open-access Segmented Head Anatomical Reference Models (SHARM), comprising 196 subjects. These models are segmented into 15 different tissues: skin, fat, muscle, skull cancellous bone, skull cortical bone, brain white matter, brain gray matter, cerebellum white matter, cerebellum gray matter, cerebrospinal fluid, dura, vitreous humor, lens, mucous tissue, and blood vessels. The segmented head models are generated using the open-access IXI MRI dataset and a convolutional neural network structure named ForkNet+. Results indicate high consistency in the statistical characteristics of different tissue distributions across ages compared to real measurements. Electromagnetic exposure studies demonstrate variability in specific absorption rate (SAR) values among subjects. SHARM is expected to be a valuable benchmark for electromagnetic dosimetry studies and various human head segmentation applications.
AB - Reliable segmentation of anatomical tissues in the human head is a crucial step in various clinical applications, including brain mapping, surgery planning, and computational simulation studies. Segmentation involves identifying different anatomical structures by labeling various tissues using different medical imaging modalities. While the segmentation of brain structures has seen significant progress, non-brain tissues receive less attention due to anatomical complexity and difficulties in observation using standard medical imaging protocols. The lack of comprehensive head segmentation methods and large segmented datasets limits variability studies, particularly in computational evaluations of electrical brain stimulation (neuromodulation), protection from electromagnetic fields, and electroencephalography, where non-brain tissues are essential. To address this gap, this study introduces the open-access Segmented Head Anatomical Reference Models (SHARM), comprising 196 subjects. These models are segmented into 15 different tissues: skin, fat, muscle, skull cancellous bone, skull cortical bone, brain white matter, brain gray matter, cerebellum white matter, cerebellum gray matter, cerebrospinal fluid, dura, vitreous humor, lens, mucous tissue, and blood vessels. The segmented head models are generated using the open-access IXI MRI dataset and a convolutional neural network structure named ForkNet+. Results indicate high consistency in the statistical characteristics of different tissue distributions across ages compared to real measurements. Electromagnetic exposure studies demonstrate variability in specific absorption rate (SAR) values among subjects. SHARM is expected to be a valuable benchmark for electromagnetic dosimetry studies and various human head segmentation applications.
KW - Brain segmentation
KW - Convolutional neural networks
KW - Human head models
KW - MRI
UR - http://www.scopus.com/inward/record.url?scp=85214285092&partnerID=8YFLogxK
U2 - 10.1016/j.bspc.2024.107481
DO - 10.1016/j.bspc.2024.107481
M3 - Article
AN - SCOPUS:85214285092
SN - 1746-8094
VL - 104
JO - Biomedical Signal Processing and Control
JF - Biomedical Signal Processing and Control
M1 - 107481
ER -