Predicting Rotator Cuff Tear Severity Using Radiographic Images and Machine Learning Techniques
Authors: 
Yusik Cho, Alena Jalics, Ding Lv, Marissa Gilbert, Kathy Dickson, Dawei Chen, Thomas Nguyen, Hannah Joines, Brandon Kakos, Chaoyang Chen, Stephen LemosAuthors Info & Claims
Pages 237 - 241
Abstract
Rotator cuff (RC) tears can cause acromion sclerosis associated with quantitative correlation between the severity of tear and severity of acromial sclerosis. The object of this study was to determine the effectiveness of X-ray image processing by machine learning (ML) techniques in the assessment of the severity of rotator cuff (RC) tear. The accuracy of ML diagnosis was compared with the accuracy of physician diagnosis. 145 patients including 72 patients with full-thickness rotator cuff tears, 50 patients with partial rotator cuff tears, and 23 patients with Bankart lesions, who underwent arthroscopic repair were recruited in this retrospective study. Before surgery, X-ray radiography was performed to diagnose the RC tear type. Image processing software Tensorflow and Keras (Image-Data-Generator) (Sequential) with convolutional neural network (CNN) structure were used to differentially diagnose partial tear and full-thickness rotator cuff tears. 80% of images were used for model training and 20% of images for model validation. The results demonstrated that the accuracy of physician diagnosis-based X-ray was 72.6% for full tears and 60.3% for partial tears, respectively. The accuracy of CNN diagnosis-based X-ray was 79.6% for full tear and 87.5% for partial tear, respectively. CNN discriminated partial tear from no-tear with a higher accuracy than human vision (Chi Square, Pearson test, p<0.001). This study presents a novel approach for the diagnosis of RCT using X-ray images and ML techniques that can assist the orthopaedic surgeon using plain X-rays to determine future treatment plans.
References
[1]
A. F. Depalma, "Surgical Anatomy of the Rotator Cuff and the Natural History of Degenerative Periarthritis," Surg Clin North Am, vol. 43, pp. 1507-20, Dec 1963.
[2]
H. V. Heikel, "Rupture of the rotator cuff of the shoulder. Experiences of surgical treatment," Acta Orthop Scand, vol. 39, no. 4, pp. 477-92, 1968.
[3]
A. W. t. Pearsall, S. Bonsell, R. J. Heitman, C. A. Helms, D. Osbahr, and K. P. Speer, "Radiographic findings associated with symptomatic rotator cuff tears," J Shoulder Elbow Surg, vol. 12, no. 2, pp. 122-7, Mar-Apr 2003.
[4]
H. R. Umans, H. Pavlov, M. Berkowitz, and R. F. Warren, "Correlation of radiographic and arthroscopic findings with rotator cuff tears and degenerative joint disease," J Shoulder Elbow Surg, vol. 10, no. 5, pp. 428-33, Sep-Oct 2001.
[5]
D. S. Weiner and I. Macnab, "Superior migration of the humeral head. A radiological aid in the diagnosis of tears of the rotator cuff," J Bone Joint Surg Br, vol. 52, no. 3, pp. 524-7, Aug 1970.
[6]
F. C. Golding, "The shoulder–the forgotten joint," Br J Radiol, vol. 35, pp. 149-58, Mar 1962.
[7]
M. Rezaee and M. Tavakoli, "Cancerous Masses Segmentation by Using Heuristic Ant Colony Algorithms in Medical Images," Journal of Image and Graphics, vol. 2, no. 2, 2014.
[8]
K. Thanammal, J. Jayasudha, R. Vijayalakshmi, and S. Arumugaperumal, "Effective Histogram Thresholding Techniques for Natural Images Using Segmentation," Journal of Image and Graphics, vol. 2, no. 2, pp. 113-116, 2014.
[9]
S. M. Anwar, M. Majid, A. Qayyum, M. Awais, M. Alnowami, and M. K. Khan, "Medical Image Analysis using Convolutional Neural Networks: A Review," J Med Syst, vol. 42, no. 11, p. 226, Oct 8 2018.
[10]
J. Gao, Q. Jiang, B. Zhou, and D. Chen, "Convolutional neural networks for computer-aided detection or diagnosis in medical image analysis: An overview," Math Biosci Eng, vol. 16, no. 6, pp. 6536-6561, Jul 15 2019.
[11]
J. C. Caicedo, "Nucleus segmentation across imaging experiments: the 2018 Data Science Bowl," Nat Methods, vol. 16, no. 12, pp. 1247-1253, Dec 2019.
[12]
J. Hung, "Keras R-CNN: library for cell detection in biological images using deep neural networks," BMC Bioinformatics, vol. 21, no. 1, p. 300, Jul 11 2020.
[13]
R. Pauwels, "Artificial intelligence for detection of periapical lesions on intraoral radiographs: Comparison between convolutional neural networks and human observers," Oral Surg Oral Med Oral Pathol Oral Radiol, vol. 131, no. 5, pp. 610-616, May 2021.
[14]
T. Kumaraguru, P. Abirami, K. M. Darshan, S. P. Angeline Kirubha, S. Latha, and P. Muthu, "Smart access development for classifying lung disease with chest x-ray images using deep learning," Mater Today Proc, Apr 16 2021.
[15]
L. Shamir, "Assessing the efficacy of low-level image content descriptors for computer-based fluorescence microscopy image analysis," J Microsc, vol. 243, no. 3, pp. 284-92, Sep 2011.
[16]
P. Lakhani and B. Sundaram, "Deep Learning at Chest Radiography: Automated Classification of Pulmonary Tuberculosis by Using Convolutional Neural Networks," Radiology, vol. 284, no. 2, pp. 574-582, Aug 2017.
[17]
A. T. Sahlol, P. Kollmannsberger, and A. A. Ewees, "Efficient Classification of White Blood Cell Leukemia with Improved Swarm Optimization of Deep Features," Sci Rep, vol. 10, no. 1, p. 2536, Feb 13 2020.
[18]
I. M. Baltruschat, H. Nickisch, M. Grass, T. Knopp, and A. Saalbach, "Comparison of Deep Learning Approaches for Multi-Label Chest X-Ray Classification," Sci Rep, vol. 9, no. 1, p. 6381, Apr 23 2019.
[19]
C. Chen, C. Chen, X. Mei, C. Chen, G. Ni, and S. Lemos, "Effects of Image Augmentation and Dual-layer Transfer Machine Learning Architecture on Tumor Classification," Proceedings of the 2019 8th International Conference on Computing and Pattern Recognition, pp. 282–287, 2019.
[20]
K. El Asnaoui and Y. Chawki, "Using X-ray images and deep learning for automated detection of coronavirus disease," J Biomol Struct Dyn, vol. 39, no. 10, pp. 3615-3626, Jul 2021.
[21]
S. Albahli, N. Ayub, and M. Shiraz, "Coronavirus disease (COVID-19) detection using X-ray images and enhanced DenseNet," Appl Soft Comput, vol. 110, p. 107645, Oct 2021.
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Published In
October 2021
393 pages
ISBN:9781450390439
DOI:10.1145/3497623
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Published: 04 February 2022
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ICCPR '21: 2021 10th International Conference on Computing and Pattern Recognition
October 15 - 17, 2021
Shanghai, China
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