Automatic muscle and fat segmentation in the thigh from T1-Weighted MRI

Purpose To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous adipose tissue [SAT] and intermuscular adipose tissue [IMAT]) from T1‐weighted (T1‐W) magnetic resonance imaging (MRI) images of the thi...

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Published in	Journal of magnetic resonance imaging Vol. 43; no. 3; pp. 601 - 610
Main Authors	Orgiu, Sara, Lafortuna, Claudio L., Rastelli, Fabio, Cadioli, Marcello, Falini, Andrea, Rizzo, Giovanna
Format	Journal Article
Language	English
Published	United States Blackwell Publishing Ltd 01.03.2016 Wiley Subscription Services, Inc
Subjects	Adipose Tissue - diagnostic imaging Adiposity Adult Age Factors Aged Algorithms Automatic Data Processing Body Composition Fascia - diagnostic imaging Female Fuzzy Logic Humans IMAT Magnetic Resonance Imaging Middle Aged Models, Statistical MRI muscle Muscle, Skeletal - diagnostic imaging Obesity - diagnostic imaging Obesity - physiopathology Pattern Recognition, Automated Reproducibility of Results segmentation Snake thigh Thigh - diagnostic imaging Young Adult segmentation IMAT MRI Snake thigh muscle
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ISSN	1053-1807 1522-2586
DOI	10.1002/jmri.25031

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Abstract	Purpose To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous adipose tissue [SAT] and intermuscular adipose tissue [IMAT]) from T1‐weighted (T1‐W) magnetic resonance imaging (MRI) images of the thigh. Materials and Methods Eighteen subjects underwent an MRI examination on a 1.5T Philips Achieva scanner. Acquisition was performed using a T1‐W sequence (TR = 550 msec, TE = 15 msec), pixel size between 0.81–1.28 mm, slice thickness of 6 mm. Bone, AT, and SM were discriminated using a fuzzy c‐mean algorithm and morphologic operators. The muscle fascia that separates SAT from IMAT was detected by integrating a morphological‐based segmentation with an active contour Snake. The method was validated on five young normal weight, five older normal weight, and five older obese females, comparing automatic with manual segmentations. Results We reported good performance in the extraction of SM, AT, and bone in each subject typology (mean sensitivity above 96%, mean relative area difference of 1.8%, 2.7%, and 2.5%, respectively). A mean distance between contours pairs of 0.81 mm and a mean percentage of contour points with distance smaller than 2 pixels of 86.2% were obtained in the muscle fascia identification. Significant correlation was also found between manual and automatic IMAT and SAT cross‐sectional areas in all subject typologies (p < 0.001). Conclusion The proposed automatic segmentation approach provides adequate thigh tissue segmentation and may be helpful in studies of regional composition. J. MAGN. RESON. IMAGING 2016;43:601–610.
AbstractList	Purpose To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous adipose tissue [SAT] and intermuscular adipose tissue [IMAT]) from T1-weighted (T1-W) magnetic resonance imaging (MRI) images of the thigh. Materials and Methods Eighteen subjects underwent an MRI examination on a 1.5T Philips Achieva scanner. Acquisition was performed using a T1-W sequence (TR=550 msec, TE=15 msec), pixel size between 0.81-1.28mm, slice thickness of 6mm. Bone, AT, and SM were discriminated using a fuzzy c-mean algorithm and morphologic operators. The muscle fascia that separates SAT from IMAT was detected by integrating a morphological-based segmentation with an active contour Snake. The method was validated on five young normal weight, five older normal weight, and five older obese females, comparing automatic with manual segmentations. Results We reported good performance in the extraction of SM, AT, and bone in each subject typology (mean sensitivity above 96%, mean relative area difference of 1.8%, 2.7%, and 2.5%, respectively). A mean distance between contours pairs of 0.81mm and a mean percentage of contour points with distance smaller than 2 pixels of 86.2% were obtained in the muscle fascia identification. Significant correlation was also found between manual and automatic IMAT and SAT cross-sectional areas in all subject typologies (p < 0.001). Conclusion The proposed automatic segmentation approach provides adequate thigh tissue segmentation and may be helpful in studies of regional composition. J. MAGN. RESON. IMAGING 2016;43:601-610. To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous adipose tissue [SAT] and intermuscular adipose tissue [IMAT]) from T1-weighted (T1 -W) magnetic resonance imaging (MRI) images of the thigh. Eighteen subjects underwent an MRI examination on a 1.5T Philips Achieva scanner. Acquisition was performed using a T1 -W sequence (TR = 550 msec, TE = 15 msec), pixel size between 0.81-1.28 mm, slice thickness of 6 mm. Bone, AT, and SM were discriminated using a fuzzy c-mean algorithm and morphologic operators. The muscle fascia that separates SAT from IMAT was detected by integrating a morphological-based segmentation with an active contour Snake. The method was validated on five young normal weight, five older normal weight, and five older obese females, comparing automatic with manual segmentations. We reported good performance in the extraction of SM, AT, and bone in each subject typology (mean sensitivity above 96%, mean relative area difference of 1.8%, 2.7%, and 2.5%, respectively). A mean distance between contours pairs of 0.81 mm and a mean percentage of contour points with distance smaller than 2 pixels of 86.2% were obtained in the muscle fascia identification. Significant correlation was also found between manual and automatic IMAT and SAT cross-sectional areas in all subject typologies (p < 0.001). The proposed automatic segmentation approach provides adequate thigh tissue segmentation and may be helpful in studies of regional composition. PURPOSETo introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous adipose tissue [SAT] and intermuscular adipose tissue [IMAT]) from T1-weighted (T1 -W) magnetic resonance imaging (MRI) images of the thigh.MATERIALS AND METHODSEighteen subjects underwent an MRI examination on a 1.5T Philips Achieva scanner. Acquisition was performed using a T1 -W sequence (TR = 550 msec, TE = 15 msec), pixel size between 0.81-1.28 mm, slice thickness of 6 mm. Bone, AT, and SM were discriminated using a fuzzy c-mean algorithm and morphologic operators. The muscle fascia that separates SAT from IMAT was detected by integrating a morphological-based segmentation with an active contour Snake. The method was validated on five young normal weight, five older normal weight, and five older obese females, comparing automatic with manual segmentations.RESULTSWe reported good performance in the extraction of SM, AT, and bone in each subject typology (mean sensitivity above 96%, mean relative area difference of 1.8%, 2.7%, and 2.5%, respectively). A mean distance between contours pairs of 0.81 mm and a mean percentage of contour points with distance smaller than 2 pixels of 86.2% were obtained in the muscle fascia identification. Significant correlation was also found between manual and automatic IMAT and SAT cross-sectional areas in all subject typologies (p < 0.001).CONCLUSIONThe proposed automatic segmentation approach provides adequate thigh tissue segmentation and may be helpful in studies of regional composition. Purpose To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous adipose tissue [SAT] and intermuscular adipose tissue [IMAT]) from T1‐weighted (T1‐W) magnetic resonance imaging (MRI) images of the thigh. Materials and Methods Eighteen subjects underwent an MRI examination on a 1.5T Philips Achieva scanner. Acquisition was performed using a T1‐W sequence (TR = 550 msec, TE = 15 msec), pixel size between 0.81–1.28 mm, slice thickness of 6 mm. Bone, AT, and SM were discriminated using a fuzzy c‐mean algorithm and morphologic operators. The muscle fascia that separates SAT from IMAT was detected by integrating a morphological‐based segmentation with an active contour Snake. The method was validated on five young normal weight, five older normal weight, and five older obese females, comparing automatic with manual segmentations. Results We reported good performance in the extraction of SM, AT, and bone in each subject typology (mean sensitivity above 96%, mean relative area difference of 1.8%, 2.7%, and 2.5%, respectively). A mean distance between contours pairs of 0.81 mm and a mean percentage of contour points with distance smaller than 2 pixels of 86.2% were obtained in the muscle fascia identification. Significant correlation was also found between manual and automatic IMAT and SAT cross‐sectional areas in all subject typologies (p < 0.001). Conclusion The proposed automatic segmentation approach provides adequate thigh tissue segmentation and may be helpful in studies of regional composition. J. MAGN. RESON. IMAGING 2016;43:601–610.
Author	Cadioli, Marcello Falini, Andrea Orgiu, Sara Rizzo, Giovanna Lafortuna, Claudio L. Rastelli, Fabio
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References_xml	– reference: Stenholm S, Harris TB, Rantanen T, Visser M, Kritchevsky SB, Ferrucci L. Sarcopenic obesity: definition, cause and consequences. Curr Opin Clin Nutr Metab Care 2008:11:693-700. – reference: Brunner G, Nambi V, Yang E, et al. Automatic quantification of muscle volumes in magnetic resonance imaging scans of the lower extremities. Magn Reson Imaging 2011:29:1065-1075. – reference: Boettcher M, Machann J, Stefan N, et al. Intermuscular adipose tissue (IMAT): association with other adipose tissue compartments and insulin sensitivity. J Magn Reson Imaging 2009:29:1340-1345. – reference: Positano V, Christiansen T, Santarelli MF, et al. Accurate segmentation of subcutaneous and intermuscular adipose tissue from MR images of the thigh. J Magn Reson Imaging 2009:29:677-684. – reference: Shen W, Wang Z, Punyanita M, et al. Adipose tissue quantification by imaging methods: a proposed classification. Obes Res 2003:11:5-16. – reference: Salvado O, Hillenbrand C, Zhang S, Wilson DL. Method to correct intensity inhomogeneity in MR images for atherosclerosis characterization. IEEE Trans Med Imaging 2006:25:539-552. – reference: Marcus RL, Addison O, Dibble LE, Foreman KB, Morrell G, LaStayo P. Intramuscular adipose tissue, sarcopenia, and mobility function in older individuals. J Aging Res 2012:2012. – reference: Heimann T, Van Ginneken B, Styner MA, et al. Comparison and evaluation of methods for liver segmentation from CT datasets. IEEE Trans Med Imaging 2009:28:1251-1265. – reference: Lafortuna CL, Tresoldi D, Rizzo G. Influence of body adiposity on structural characteristics of skeletal muscle in men and women. Clin Physiol Funct Imaging 2014:34:47-55. – reference: Bezdek JC, Ehrlich R, Full W. FCM: The fuzzy c-means clustering algorithm. Comput Geosci 1984:10:191-203. – reference: Elliott M, Walter G, Gulish H, et al. Volumetric measurement of human calf muscle from magnetic resonance imaging. Magn Reson Mater Phys 1997:5:93-98. – reference: Gray DS, Bray GA, Gemayel N, Kaplan K. Effect of obesity on bioelectrical impedance. Am J Clin Nutr 1989:50:255-260. – reference: Makrogiannis S, Serai S, Fishbein KW, Schreiber C, Ferrucci L, Spencer RG. Automated quantification of muscle and fat in the thigh from water-, fat-, and nonsuppressed MR images. J Magn Reson Imaging 2012:35:1152-1161. – reference: Ross R, Goodpaster B, Kelley D, Boada F. Magnetic resonance imaging in human body composition research: from quantitative to qualitative tissue measurement. Ann N Y Acad Sci 2000:904:12-17. – reference: Radegran G, Blomstrand E, Saltin B. Peak muscle perfusion and oxygen uptake in humans: importance of precise estimates of muscle mass. J Appl Physiol (1985) 1999:87:2375-2380. – reference: Broderick BJ, Dessus S, Grace PA, Ó'Laighin G. Technique for the computation of lower leg muscle bulk from magnetic resonance images. Med Eng Phys 2010:32:926-933. – reference: Müller M, Geisler C, Pourhassan M, Glüer C, Bosy-Westphal A. Assessment and definition of lean body mass deficiency in the elderly. Eur J Clin Nutr 2014;68:1220-1227. – reference: Mitsiopoulos N, Baumgartner RN, Heymsfield SB, Lyons W, Gallagher D, Ross R. Cadaver validation of skeletal muscle measurement by magnetic resonance imaging and computerized tomography. J Appl Physiol (1985) 1998:85:115-122. – reference: Urricelqui L, Malanda A, Villanueva A. Automatic segmentation of thigh magnetic resonance images. World Acad Sci Eng Technol 2009:34. – reference: Barra V, Boire J. Segmentation of fat and muscle from MR images of the thigh by a possibilistic clustering algorithm. Comput Methods Programs Biomed 2002:68:185-193. – reference: Valentinitsch A, Karampinos D, Alizai H, et al. Automated unsupervised multi-parametric classification of adipose tissue depots in skeletal muscle. J Magn Reson Imaging 2013:37:917-927. – reference: Janssen I, Heymsfield SB, Wang ZM, Ross R. Skeletal muscle mass and distribution in 468 men and women aged 18-88 yr. J Appl Physiol (1985) 2000:89:81-88. – reference: Heymsfield S. Development of imaging methods to assess adiposity and metabolism. Int J Obes 2008:32:S76-S82. – reference: Goodpaster BH, Thaete FL, Kelley DE. Thigh adipose tissue distribution is associated with insulin resistance in obesity and in type 2 diabetes mellitus. Am J Clin Nutr 2000:71:885-892. – reference: Kass M, Witkin A, Terzopoulos D. Snakes: active contour models. Int J Comput Vision 1988:1:321-331. – reference: Segal KR, Van Loan M, Fitzgerald PI, Hodgdon JA, Van Itallie TB. Lean body mass estimation by bioelectrical impedance analysis: a four-site cross-validation study. Am J Clin Nutr 1988:47:7-14. – reference: Yim JE, Heshka S, Albu JB, Heymsfield S, Gallagher D. Femoral-gluteal subcutaneous and intermuscular adipose tissues have independent and opposing relationships with CVD risk. J Appl Physiol (1985) 2008:104:700-707. – reference: Rybak J, Kuss A, Lamecker H, et al. The digital bee brain: integrating and managing neurons in a common 3D reference system. 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Snippet	Purpose To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components... To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components (subcutaneous... Purpose To introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components... PURPOSETo introduce and validate an automatic segmentation method for the discrimination of skeletal muscle (SM), and adipose tissue (AT) components...
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SubjectTerms	Adipose Tissue - diagnostic imaging Adiposity Adult Age Factors Aged Algorithms Automatic Data Processing Body Composition Fascia - diagnostic imaging Female Fuzzy Logic Humans IMAT Magnetic Resonance Imaging Middle Aged Models, Statistical MRI muscle Muscle, Skeletal - diagnostic imaging Obesity - diagnostic imaging Obesity - physiopathology Pattern Recognition, Automated Reproducibility of Results segmentation Snake thigh Thigh - diagnostic imaging Young Adult
Title	Automatic muscle and fat segmentation in the thigh from T1-Weighted MRI
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