Automation analysis X-ray of the spine to objectify the assessment of the severity of scoliotic deformity in idiopathic scoliosis: a preliminary report

BACKGROUND: Scoliosis is one of the most common spinal deformations that is usually diagnosed on frontal radiographs using Cobb’s method. The use of automatic measurement methods based on artificial intelligence can overcome many drawbacks of the usual method and can significantly save the time of the radiologist. AIM: to analyze the accuracy, advantages and disadvantages of a newly developed AI program for automatic diagnosis of scoliosis and measurement of Cobb’s angle on frontal radiographs. Methods: 112 digital radiographs were used to test the agreement of Cobb’s angle measurements between the new automatic method and the radiologist using Blant-Altman method on Microsoft Excel. A limited clinical accuracy test was also conducted using 120 radiographs. The accuracy of the system in defining the grade of scoliosis was evaluated by calculating sensitivity; specificity; accuracy; and area under the ROC curve (ROC AUC). RESULTS: The agreement of Cobb’s angle measurement between the system and the radiologist was found mostly in scoliosis with grades 1 and 2. Only 2.8% of the results were found to be unsatisfying with an angle variability of more than 5°. Diagnostic accuracy metrics of the limited clinical trial in Mariinsky city hospital had also proved the reliability of the system, with sensitivity = 0.97; specificity = 0.88; accuracy (general validity) = 0.93; area under the ROC curve (ROC AUC) = 0.93. CONCLUSION: Overall, the AI program can automatically and accurately define the grade of scoliosis and measure the angles of spinal curvatures on frontal radiographs.

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Efficiency of the decision support system for determining the severity of scoliotic spinal deformity by the analysis of radiographs

Lein,

Nechaeva,

Demchenko

et al. 2024

Pediatr Traum Orthop Reconstr Surg

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BACKGROUND: In 2020, a decision support system was developed at expense of grant from Innovation Promotion Fund and integrated into medical base of prosthetic and orthopedic center “Sсoliologic.ru.” It is the first computer program for determining severity of scoliotic spinal deformity in analysis of radiographs. AIM: To evaluate performance of a computer program for determining Cobb angle by comparing obtained automated data with manual measurement data by various specialists. MATERIALS AND METHODS: From medical base of prosthetic and orthopedic center “Sсoliologic.ru,” 411 digital radiographs of spine of children and adolescents were selected, which were drawn by a radiologist (BP-etalon), an orthopedic traumatologist with 5 years of experience and experience in vertebrology (OO), and an orthopedic traumatologist with less than 1 year of experience and no experience in vertebrology (OB) and computer program (KP). The number and proportion of exact matches and mean absolute percentage error (MAPE) of results of measuring the Cobb angle of reference data were compared with indicators obtained by OO, OB, and KP in, for various types of scoliosis according to the classification of Rigо, as well as in determining the main arc. Bland–Altman graphs were used. The mean absolute deviation (MAD) and MAPE for the main arc with magnitude ranging from 20° to 50° were calculated. RESULTS: The exact matches of KP with standard were 21%. Hence, every fifth measurement of the Cobb angle on X-ray, calculated automatically, was identical to standard. The highest proportion of matches with standard was noted in OO (33%), and the lowest in OB (16%). The highest accuracy of KP was found at types E1 and E2, and the arc of 3 was 30% and 24%, respectively. The proportion of KP matches with standard increased to 61%, with an error of 3°, and to 75%, with an error of 5°; with an error of 7°, the proportion of matches reached 84%. Moreover, the proportion of coincidences of a non-experienced researcher increased from 34% to 58%. When determining magnitude of the main arc of scoliosis, OO increased his/her accuracy by almost 2,6 times, KP by 2,1 times, and OB by 1,5 times. The MAD of KP for all major arcs was 3.8°. Good reliability of the obtained KP indicators compared to the reference (ICC = 0.9) was noted. CONCLUSIONS: The use of a computer program may be recommended for automated determination of Cobb angle, because current algorithm of computer program has been found to be accurate compared to reference measurement. Its accuracy was significantly higher than that of novice orthopedic traumatologists with no experience in vertebrology.

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Automation analysis X-ray of the spine to objectify the assessment of the severity of scoliotic deformity in idiopathic scoliosis: a preliminary report

Cited by 4 publications

References 11 publications

Development of Methods and Models for Assessing Spine Curvature Based on Antilatency Motion Capture System

Development of Methods and Models for Assessing Spine Curvature Based on Antilatency Motion Capture System

A new artificial intelligence program for the automatic evaluation of scoliosis on frontal spinal radiographs: Accuracy, advantages and limitations

Efficiency of the decision support system for determining the severity of scoliotic spinal deformity by the analysis of radiographs

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