Literature DB >> 31132616

Muscle segmentation in axial computed tomography (CT) images at the lumbar (L3) and thoracic (T4) levels for body composition analysis.

Setareh Dabiri1, Karteek Popuri2, Elizabeth M Cespedes Feliciano3, Bette J Caan3, Vickie E Baracos4, Mirza Faisal Beg2.   

Abstract

In diseases such as cancer, patients suffer from degenerative loss of skeletal muscle (cachexia). Muscle wasting and loss of muscle function/performance (sarcopenia) can also occur during advanced aging. Assessing skeletal muscle mass in sarcopenia and cachexia is therefore of clinical interest for risk stratification. In comparison with fat, body fluids and bone, quantifying the skeletal muscle mass is more challenging. Computed tomography (CT) is one of the gold standard techniques for cancer diagnostics and analysis of progression, and therefore a valuable source of imaging for in vivo quantification of skeletal muscle mass. In this paper, we design a novel deep neural network-based algorithm for the automated segmentation of skeletal muscle in axial CT images at the third lumbar (L3) and the fourth thoracic (T4) levels. A two-branch network with two training steps is investigated. The network's performance is evaluated for three trained models on separate datasets. These datasets were generated by different CT devices and data acquisition settings. To ensure the model's robustness, each trained model was tested on all three available test sets. Errors and the effect of labeling protocol in these cases were analyzed and reported. The best performance of the proposed algorithm was achieved on 1327 L3 test samples with an overlap Jaccard score of 98% and sensitivity and specificity greater than 99%.
Copyright © 2019 Elsevier Ltd. All rights reserved.

Entities:  

Keywords:  Aging; CT imaging; Cancer; Convolutional neural network; Skeletal muscle segmentation

Year:  2019        PMID: 31132616      PMCID: PMC6620151          DOI: 10.1016/j.compmedimag.2019.04.007

Source DB:  PubMed          Journal:  Comput Med Imaging Graph        ISSN: 0895-6111            Impact factor:   4.790


  15 in total

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Authors:  N Kamiya; X Zhou; H Chen; C Muramatsu; T Hara; R Yokoyama; M Kanematsu; H Hoshi; H Fujita
Journal:  Conf Proc IEEE Eng Med Biol Soc       Date:  2011

2.  Automated recognition of the psoas major muscles on X-ray CT images.

Authors:  N Kamiya; X Zhou; H Chen; T Hara; H Hoshi; R Yokoyama; M Kanematsu; H Fujita
Journal:  Conf Proc IEEE Eng Med Biol Soc       Date:  2009

3.  Automated segmentation of psoas major muscle in X-ray CT images by use of a shape model: preliminary study.

Authors:  Naoki Kamiya; Xiangrong Zhou; Huayue Chen; Chisako Muramatsu; Takeshi Hara; Ryujiro Yokoyama; Masayuki Kanematsu; Hiroaki Hoshi; Hiroshi Fujita
Journal:  Radiol Phys Technol       Date:  2011-07-14

4.  Deep convolutional neural networks for multi-modality isointense infant brain image segmentation.

Authors:  Wenlu Zhang; Rongjian Li; Houtao Deng; Li Wang; Weili Lin; Shuiwang Ji; Dinggang Shen
Journal:  Neuroimage       Date:  2015-01-03       Impact factor: 6.556

5.  Deep feature learning for knee cartilage segmentation using a triplanar convolutional neural network.

Authors:  Adhish Prasoon; Kersten Petersen; Christian Igel; François Lauze; Erik Dam; Mads Nielsen
Journal:  Med Image Comput Comput Assist Interv       Date:  2013

6.  Automatic Segmentation of MR Brain Images With a Convolutional Neural Network.

Authors:  Pim Moeskops; Max A Viergever; Adrienne M Mendrik; Linda S de Vries; Manon J N L Benders; Ivana Isgum
Journal:  IEEE Trans Med Imaging       Date:  2016-03-30       Impact factor: 10.048

7.  Brain Tumor Segmentation Using Convolutional Neural Networks in MRI Images.

Authors:  Sergio Pereira; Adriano Pinto; Victor Alves; Carlos A Silva
Journal:  IEEE Trans Med Imaging       Date:  2016-03-04       Impact factor: 10.048

8.  Total body skeletal muscle and adipose tissue volumes: estimation from a single abdominal cross-sectional image.

Authors:  Wei Shen; Mark Punyanitya; ZiMian Wang; Dympna Gallagher; Marie-Pierre St-Onge; Jeanine Albu; Steven B Heymsfield; Stanley Heshka
Journal:  J Appl Physiol (1985)       Date:  2004-08-13

9.  Body Composition Assessment in Axial CT Images Using FEM-Based Automatic Segmentation of Skeletal Muscle.

Authors:  Karteek Popuri; Dana Cobzas; Nina Esfandiari; Vickie Baracos; Martin Jägersand
Journal:  IEEE Trans Med Imaging       Date:  2015-09-22       Impact factor: 10.048

10.  A practical and precise approach to quantification of body composition in cancer patients using computed tomography images acquired during routine care.

Authors:  Marina Mourtzakis; Carla M M Prado; Jessica R Lieffers; Tony Reiman; Linda J McCargar; Vickie E Baracos
Journal:  Appl Physiol Nutr Metab       Date:  2008-10       Impact factor: 2.665
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  10 in total

1.  Automated body composition analysis of clinically acquired computed tomography scans using neural networks.

Authors:  Michael T Paris; Puneeta Tandon; Daren K Heyland; Helena Furberg; Tahira Premji; Gavin Low; Marina Mourtzakis
Journal:  Clin Nutr       Date:  2020-01-22       Impact factor: 7.324

Review 2.  Nutrition challenges of cancer cachexia.

Authors:  Omnia U Gaafer; Teresa A Zimmers
Journal:  JPEN J Parenter Enteral Nutr       Date:  2021-11       Impact factor: 4.016

Review 3.  Assessment of Cancer-Associated Cachexia - How to Approach Physical Function Evaluation.

Authors:  Julia Fram; Caroline Vail; Ishan Roy
Journal:  Curr Oncol Rep       Date:  2022-03-19       Impact factor: 5.075

4.  Deep learning method for localization and segmentation of abdominal CT.

Authors:  Setareh Dabiri; Karteek Popuri; Cydney Ma; Vincent Chow; Elizabeth M Cespedes Feliciano; Bette J Caan; Vickie E Baracos; Mirza Faisal Beg
Journal:  Comput Med Imaging Graph       Date:  2020-08-14       Impact factor: 4.790

5.  Sarcopenia in cancer: Risking more than muscle loss.

Authors:  Milan Anjanappa; Michael Corden; Andrew Green; Darren Roberts; Peter Hoskin; Alan McWilliam; Ananya Choudhury
Journal:  Tech Innov Patient Support Radiat Oncol       Date:  2020-11-09

6.  A Deep Learning Model to Automate Skeletal Muscle Area Measurement on Computed Tomography Images.

Authors:  Kaushalya C Amarasinghe; Jamie Lopes; Julian Beraldo; Nicole Kiss; Nicholas Bucknell; Sarah Everitt; Price Jackson; Cassandra Litchfield; Linda Denehy; Benjamin J Blyth; Shankar Siva; Michael MacManus; David Ball; Jason Li; Nicholas Hardcastle
Journal:  Front Oncol       Date:  2021-05-07       Impact factor: 6.244

Review 7.  The Value of Artificial Intelligence-Assisted Imaging in Identifying Diagnostic Markers of Sarcopenia in Patients with Cancer.

Authors:  Ying-Tzu Huang; Yi-Shan Tsai; Peng-Chan Lin; Yu-Min Yeh; Ya-Ting Hsu; Pei-Ying Wu; Meng-Ru Shen
Journal:  Dis Markers       Date:  2022-03-29       Impact factor: 3.434

8.  Identifying sarcopenia in advanced non-small cell lung cancer patients using skeletal muscle CT radiomics and machine learning.

Authors:  Xing Dong; Xu Dan; Ao Yawen; Xu Haibo; Li Huan; Tu Mengqi; Chen Linglong; Ruan Zhao
Journal:  Thorac Cancer       Date:  2020-08-06       Impact factor: 3.500

9.  Artificial intelligence-aided CT segmentation for body composition analysis: a validation study.

Authors:  Pablo Borrelli; Reza Kaboteh; Olof Enqvist; Johannes Ulén; Elin Trägårdh; Henrik Kjölhede; Lars Edenbrandt
Journal:  Eur Radiol Exp       Date:  2021-03-11

10.  Percentile-based averaging and skeletal muscle gauge improve body composition analysis: validation at multiple vertebral levels.

Authors:  J Peter Marquardt; Eric J Roeland; Emily E Van Seventer; Till D Best; Nora K Horick; Ryan D Nipp; Florian J Fintelmann
Journal:  J Cachexia Sarcopenia Muscle       Date:  2021-11-02       Impact factor: 12.910
  10 in total

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