Comparison of Manual Two-dimensional and Automated Three-dimensional Methods of Assessing Shoulder Joint Morphology through Computed Tomography Images

Rocha Motta Filho, Geraldo da; Amaral, Marcus Vinícius; Cohen, Márcio; Carvalho, Marcio Schiefer de Sá; Fonseca, Raphael Soares da; Oliveira, Ana Carolina Leal de

doi:10.1055/s-0044-1786821

Abstract

Objective

To evaluate the interobserver agreement in the measurement of anatomical parameters of the shoulder using manual methods of two-dimensional (2D) computed tomography (CT) unformatted in the plane of the scapula and to compare them with the automated measurement obtained through the Blueprint (Wright Medical, Memphis, TN, United States) software, which uses reconstructed three-dimensional (3D) images.

Methods

The present is a cross-sectional study in which 2D CT images of 38 patients with different diagnoses were used. The anatomical parameters were measured by the manual methods described by Friedman et al., the glenoid vault method, the Maurer et al. method, and shoulder subluxation according to Walch et al., by five independent qualified surgeons and compared with the parameters obtained through the Blueprint automated software.

Results

Significant differences were found between the manual measurement version obtained through the Friedman et al. method and the automated version. The mean values found for inclination did not show statistically significant differences among the methods. The mean value found for subluxation showed significant differences between the average observed in the analyses performed by the automated method and those performed by the surgeons.

Conclusion

The manual measurements of glenoid version and inclination performed by experienced surgeons are effective, and the vault method is superior to the Friedman et al. method in the analysis of severe glenoid deformities.

Keywords
artroplasty; shoulder replacement; tomography, X-ray computed

Resumo

Objetivo

Avaliar a concordância interobservador na medida dos parâmetros anatômicos do ombro utilizando métodos manuais de tomografia computadorizada (TC) bidimensional (2D) não formatada no plano da escápula e compará-los à medida automatizada obtida com o programa Blueprint (Wright Medical, Memphis, TN, Estados Unidos), que utiliza imagens tridimensionais (3D) reconstruídas.

Métodos

Este é um estudo transversal com a utilização de imagens de TC 2D de 38 pacientes com diferentes diagnósticos. Os parâmetros anatômicos foram medidos por métodos manuais - versão, método de Friedman et al., e método do vault; inclinação, por método de Maurer et al., e subluxação do ombro segundo Walch et al. As mensurações foram realizadas por cinco cirurgiões qualificados e independentes, e comparados aos parâmetros obtidos pelo programa automatizado Blueprint.

Resultados

Foram observadas diferenças significativas entre a versão de medida manual obtida pelo método de Friedman et al. e a versão automatizada. Os valores médios de inclinação não apresentaram diferenças estatisticamente significativas entre os métodos. A média observada de subluxação teve diferenças significativas entre as análises realizadas pelo método automatizado e pelos cirurgiões.

Conclusão

As medidas manuais de versão e inclinação da glenoide realizadas por cirurgiões experientes são eficazes, e o método da abóbada é superior ao de Friedman et al. na análise de deformidades glenoidais graves.

Palavras-chave
artroplastia; substituição do ombro; tomografia computadorizada por raios X

Introduction

Correction of joint deformities in the glenoid is essential to perform shoulder arthroplasty, and it can directly impact the functional result and survival of the implant.¹1 Walch G, Mesiha M, Boileau P, et al. Three-dimensional assessment of the dimensions of the osteoarthritic glenoid. Bone Joint J 2013;95-B(10):1377–1382 Therefore, preoperative planning is essential for the successful performance of total shoulder arthroplasty.¹1 Walch G, Mesiha M, Boileau P, et al. Three-dimensional assessment of the dimensions of the osteoarthritic glenoid. Bone Joint J 2013;95-B(10):1377–1382

2 Shapiro TA, McGarry MH, Gupta R, Lee YS, Lee TQ. Biomechanical effects of glenoid retroversion in total shoulder arthroplasty. J Shoulder Elbow Surg 2007;16(3, Suppl)S90–S95

3 Iannotti JP, Greeson C, Downing D, Sabesan V, Bryan JA. Effect of glenoid deformity on glenoid component placement in primary shoulder arthroplasty. J Shoulder Elbow Surg 2012;21(01):48–55-⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760

Traditionally, the assessment of glenoid morphology is performed using angular measurements on two-dimensional (2D) computed tomography (CT) images, which have demonstrated low accuracy and inter- and intraobserver agreements.⁵5 Ganapathi A, McCarron JA, Chen X, Iannotti JP. Predicting normal glenoid version from the pathologic scapula: a comparison of 4 methods in 2- and 3-dimensional models. J Shoulder Elbow Surg 2011;20(02):234–244 The use of three-dimensional (3D) CT images has shown limited improvements as the reconstruction of the scapula plane requires reformatting and processing of 2D images.⁶6 Hoenecke HR Jr, Hermida JC, Flores-Hernandez C, D'Lima DD. Accuracy of CT-based measurements of glenoid version for total shoulder arthroplasty. J Shoulder Elbow Surg 2010;19(02):166–171,⁷7 Scalise JJ, Bryan J, Polster J, Brems JJ, Iannotti JP. Quantitative analysis of glenoid bone loss in osteoarthritis using three-dimensional computed tomography scans. J Shoulder Elbow Surg 2008; 17(02):328–335

Thus, the emergence of three-dimensional (3D) CT images associated with the development of automated computer software is intended to control the limitations and inaccuracies of manual methods and the reformatting of CT slices in the scapular plane.⁸8 Iannotti J, Baker J, Rodriguez E, et al. Three-dimensional preoperative planning software and a novel information transfer technology improve glenoid component positioning. J Bone Joint Surg Am 2014;96(09):e71

9 Boileau P, Cheval D, Gauci MO, Holzer N, Chaoui J, Walch G. Automated Three-Dimensional Measurement of Glenoid Version and Inclination in Arthritic Shoulders. J Bone Joint Surg Am 2018; 100(01):57–65

10 Gross DJ, Golijanin P, Dumont GD, et al. The effect of sagittal rotation of the glenoid on axial glenoid width and glenoid version in computed tomography scan imaging. J Shoulder Elbow Surg 2016;25(01):61–68-¹¹11 Lewis GS, Armstrong AD. Glenoid spherical orientation and version. J Shoulder Elbow Surg 2011;20(01):3–11

Therefore, the aim of the present study was to evaluate the interobserver agreement in the measurement of anatomical parameters of the shoulder using manual methods from 2D CT unformatted in the plane of the scapula and to compare them with automated measurement that uses reconstructed 3D images.

Materials and Methods

Selection of Cases

After approval by the institutional Ethics in Research Committee (under no. 35243920.4.0000.5273), a study was carried out to evaluate the CT images of the shoulder joint in patients of both sexes, older than 18 years of age, diagnosed with osteoarthritis.

In total, 38 CT scans were randomly selected from exams performed for patients at the institution from January 2015 to December 2019. All CT exams were performed using the same device (model Brilliance, Philips, Amsterdam, Netherlands), with 64 channels, with the patient in the supine position.

The inclusion criteria were CT scans that had triplanar, coronal, sagittal, and axial sections, with a minimum section thickness of 1 mm, in which the entire scapula was visualized and were processed by the automated surgical planning software selected for the experiment. Images of patients who had undergone previous surgery in the shoulder and who had artifacts on CT images were excluded, such as the presence of a metallic implant or other anatomical changes that could affect the segmental processing by the automated software.

Manual Measurement

The 2D CT images that were not formatted in the scapula plane were used for the manual measurement of the version, according to the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 (Fig. 1) and glenoid vault methods, described by Matsumara et al.¹³13 Matsumura N, Ogawa K, Ikegami H, Collin P, Walch G, Toyama Y. Computed tomography measurement of glenoid vault version as an alternative measuring method for glenoid version. J Orthop Surg Res 2014;9(01):17 (Fig. 2), and of the glenoid inclination using the Maurer et al.¹⁴14 Maurer A, Fucentese SF, Pfirrmann CW, et al. Assessment of glenoid inclination on routine clinical radiographs and computed tomography examinations of the shoulder. J Shoulder Elbow Surg 2012;21(08):1096–1103 (Fig. 3) method in addition to the measurement of the percentage of humeral head subluxation according to Walch et al.⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760 (Fig. 4).

Fig. 1
Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method to evaluate the glenoid version. We used the fourth cut distal to the last cut in which the tip of the coracoid process was visualized in the axial plane. The glenoid version was determined by the angle, as shown: (A) Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 line, (B) glenoid line, and (C) line perpendicular to the scapular axis. A positive value of the glenoid version angle was interpreted as anteversion, while a negative value was interpreted as retroversion.

Fig. 2
The vault method for the measurement of the version, which was defined in the axial section as a triangle composed of the anterior and posterior walls of the scapula neck and the glenoid articular surface. The angle is determined by the lines: (A) vault axis, (B) glenoid line, and (C) line perpendicular to the vault axis.

Fig. 3
Maurer et al.¹⁴14 Maurer A, Fucentese SF, Pfirrmann CW, et al. Assessment of glenoid inclination on routine clinical radiographs and computed tomography examinations of the shoulder. J Shoulder Elbow Surg 2012;21(08):1096–1103 method for the measurement of the glenoid inclination, which was performed in the oblique coronal plane of the computed tomography scan, and the slice that best captured the floor of the supraspinatus fossa was selected. (A) Line tangent to the anterior and posterior edges of the glenoid, (B) supraspinatus fossa line, and (C) line perpendicular to line B determining the glenoid inclination.

Fig. 4
Walch et al.⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760 method to determine humeral head subluxation. (A) Line tangent to the anterior and posterior edges of the glenoid, (B) line perpendicular to the face of the glenoid at its midpoint, (C) line parallel to line A, dividing the middle third of the humeral head, and (D) part of the humeral head posterior to the center of the glenoid. Subluxation index = D/C.

These measurements were performed independently by five orthopedists specialized in shoulder surgery using the RadiAnt DICOM Viewer software (Medixant, Poznan, Poland).¹⁵15 RadiAnt® DICOM Viewer, Poznan, Poland. Available from: www.radiantviewer.com/pt-br
www.radiantviewer.com/pt-br... The observers were uniformly instructed, as described below, to standardize the measurements. All observers were blinded to each other's results.

Automated Measurement

The automated measurement used the CT images in the Digital Imaging and Communications in Medicine (DICOM) format that were processed by the Blueprint⁹9 Boileau P, Cheval D, Gauci MO, Holzer N, Chaoui J, Walch G. Automated Three-Dimensional Measurement of Glenoid Version and Inclination in Arthritic Shoulders. J Bone Joint Surg Am 2018; 100(01):57–65 (Wright Medical, Memphis, TN, United States) software. The software performs an automatic segmentation process, determines the scapula and glenoid planes, and then performs measurements, providing the version and inclination values, in addition to the percentage of subluxation of the humeral head (Fig. 5).

Fig. 5
Initial screen of the Blueprint software showing the values of the glenoid version and inclination, and humeral head subluxation.

Statistical Analysis

The interclass correlation coefficient (ICC) was calculated to determine the variability in the manual measurements among surgeons.

For the descriptive statistics, data were presented as mean, standard deviation, maximum, and minimum values. The comparison of the measurements obtained by the different methods of evaluating the version was performed using the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 test, followed by the Dunn posttest. The comparison between the measurements of inclination and subluxation by manual and automated methods was performed using the Wilcoxon test. The cases were categorized according to the severity of the version and inclination, using intervals of 0 to 10°, and > 10° when indicated. Those intervals were chosen based on studies that have shown that the normal glenoid version is close to 0°, sometimes with slight anteversion but more often slight retroversion with values typically lower than 10° in either direction,¹⁶16 van de Bunt F, Pearl ML, Lee EK, Peng L, Didomenico P. Glenoid version by CT scan: an analysis of clinical measurement error and introduction of a protocol to reduce variability. Skeletal Radiol 2015;44(11):1627–1635 and that the normal intrinsic glenoid inclination angle is generally between 0 and 10°.¹⁷17 Favard L, Berhouet J, Walch G, Chaoui J, Lévigne C. Superior glenoid inclination and glenoid bone loss : Definition, assessment, biomechanical consequences, and surgical options. Orthopade 2017;46(12):1015–1021 All analyses were performed using the IBM SPSS Statistics for Windows (IBM Corp., Armonk, NY, United States) software, version 21.0.

Results

The present study included 38 cases, 17 of which were diagnosed with cuff tear arthropathy, and 21, with osteoarthritis.

The ICC for the manual measurements is described in Table 1. The mean version values obtained by the Friedman et al.,¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 vault, and automated methods are presented in Table 2. The vault method was similar to the automated method (p > 0.99), while the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method tended to underestimate this measure, both in relation to the automated and vault methods (p = 0.003) (Table 2).

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Table 1
Interclass correlation coefficients for version, by the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 and vault methods, inclination, and subluxation

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Table 2
Version measurement

The differences between the version measurements made by Blueprint and the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method were lower than 5° in 23 cases (60.5%), between 5 and 10° in 14 cases (36.8%), and greater than 10° in 1 case (2.6%). Such proportions were similar to those found in the comparison between Blueprint and the vault method: 22 cases (57.8%), 13 cases (34.2%), and 3 cases (7.8%), respectively (p = 0.57) (Table 3).

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Table 3
Number of cases in which the mean obtained by measurements using manual methods differed from automated measurements, stratified by degrees of difference

Inclination showed no statistical difference between the automated and manual methods (11.85° ± 9.8° versus 11.24° ± 5.44°; p = 0.377) (Table 4). Subluxation measurements resulted in higher values in the automated method in comparison to the manual one (60.08° ± 14.72° versus 48.47° ± 7.67°; p < 0.0001) (Table 4).

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Table 4
Measurement of inclination and subluxation

Cases were categorized considering those presenting a glenoid inclination within the normal range (−10 to +10°) and those with anatomical variation of this parameter. For cases within the normal range, the vault method resulted in significantly higher values than the automated (p = 0.04) and the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 methods (p = 0.0004). Interestingly, for cases with a version higher than 10°, the mean version obtained with the automated method was significantly higher than that obtained with Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method (p = 0,001), but similar to that obtained with vault method (p = 0.13). The mean values for subluxation obtained with the automated method were significantly higher than those obtained with the manual method in both subgroups evaluated (Table 5).

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Table 5
Comparison regarding the mean version, inclination, and subluxation using the automated and manual methods, categorized by version measured by the automated method

The cases were then categorized considering inclination, measured by the automated method. For cases with inclination within the normal range, the mean version obtained with the vault method was significantly higher than that obtained with the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method (p = 0.1), with no differences between the automated and the manual methods. For cases with inclination higher than 10°, the mean version was significantly underestimated by the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 in comparison to the automated (p = 0.002) and the vault methods (p = 0.007).

In cases within the normal range of inclination, this parameter was overestimated by the manual method in comparison to the automated one (p = 0.001). Regarding subluxation, the mean values obtained with automated method were significantly higher than those obtained with the manual method in both subgroups evaluated (Table 6).

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Table 6
Comparison regarding the mean of the inclination using the automated and manual methods, categorized by the severity of the inclination measured by the automated method

Discussion

The success of shoulder arthroplasty depends on the proper positioning of the implant.¹1 Walch G, Mesiha M, Boileau P, et al. Three-dimensional assessment of the dimensions of the osteoarthritic glenoid. Bone Joint J 2013;95-B(10):1377–1382 The surgeon's ability to identify morphological changes in the glenoid, especially regarding the version and inclination, is extremely important, as it avoids misplacements that compromise the survival of the procedure.²2 Shapiro TA, McGarry MH, Gupta R, Lee YS, Lee TQ. Biomechanical effects of glenoid retroversion in total shoulder arthroplasty. J Shoulder Elbow Surg 2007;16(3, Suppl)S90–S95,⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760,⁷7 Scalise JJ, Bryan J, Polster J, Brems JJ, Iannotti JP. Quantitative analysis of glenoid bone loss in osteoarthritis using three-dimensional computed tomography scans. J Shoulder Elbow Surg 2008; 17(02):328–335

However, manual 2D methods to define glenoid morphology present limitations and inaccuracies because of the difficulty in segmenting CT images in the anatomical plane of the scapula. The discrepancies motivated the development of automated programs for preoperative planning, whose use has become increasingly frequent in an effort to improve the understanding of the anatomy and the subsequent positioning and fixation of the prosthetic components.⁸8 Iannotti J, Baker J, Rodriguez E, et al. Three-dimensional preoperative planning software and a novel information transfer technology improve glenoid component positioning. J Bone Joint Surg Am 2014;96(09):e71,⁹9 Boileau P, Cheval D, Gauci MO, Holzer N, Chaoui J, Walch G. Automated Three-Dimensional Measurement of Glenoid Version and Inclination in Arthritic Shoulders. J Bone Joint Surg Am 2018; 100(01):57–65 However, its routine use still does not occur in the practice of most surgeons who perform shoulder arthroplasties.⁸8 Iannotti J, Baker J, Rodriguez E, et al. Three-dimensional preoperative planning software and a novel information transfer technology improve glenoid component positioning. J Bone Joint Surg Am 2014;96(09):e71,¹⁸18 Werner BS, Hudek R, Burkhart KJ, Gohlke F. The influence of three-dimensional planning on decision-making in total shoulder arthroplasty. J Shoulder Elbow Surg 2017;26(08):1477–1483

19 Rosenthal Y, Rettig SA, Virk MS, Zuckerman JD. Impact of preoperative 3-dimensional planning and intraoperative navigation of shoulder arthroplasty on implant selection and operative time: a single surgeon's experience. J Shoulder Elbow Surg 2020;29(12): 2564–2570-²⁰20 Hartzler RU, Denard PJ, Griffin JW, Werner BC, Romeo AA. Surgeon acceptance of an initial 3D glenoid preoperative plan: rates and risk factors. J Shoulder Elbow Surg 2021;30(04):787–794 Moreover, there are controversies regarding the accuracy of these methods and the ideal placement of the implants.²¹21 Iannotti JP, Walker K, Rodriguez E, Patterson TE, Jun BJ, Ricchetti ET. Accuracy of 3-Dimensional Planning, Implant Templating, and Patient-Specific Instrumentation in Anatomic Total Shoulder Arthroplasty. J Bone Joint Surg Am 2019;101(05):446–457

22 Berhouet J, Jacquot A, Walch G, Deransart P, Favard L, Gauci MO. Preoperative planning of baseplate position in reverse shoulder arthroplasty: Still no consensus on lateralization, version and inclination. Orthop Traumatol Surg Res 2022;108(03):103115

23 Shukla DR, McLaughlin RJ, Lee J, Nguyen NTV, Sanchez-Sotelo J. Automated three-dimensional measurements of version, inclination, and subluxation. Shoulder Elbow 2020;12(01):31–37

24 Raiss P, Walch G, Wittmann T, Athwal GS. Is preoperative planning effective for intraoperative glenoid implant size and type selection during anatomic and reverse shoulder arthroplasty? J Shoulder Elbow Surg 2020;29(10):2123–2127-²⁵25 Denard PJ, Provencher MT, Lädermann A, Romeo AA, Parsons BO, Dines JS. Version and inclination obtained with 3-dimensional planning in total shoulder arthroplasty: do different programs produce the same results? JSES Open Access 2018;2(04):200–204

In the clinical practice at low- and middle-income countries, 2D CT images unformatted in the plane of the scapula are broadly used, which, despite representing a limitation, is a reality. In the present study, manual measurements of the version, by both the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 and vault methods, as well as inclination and subluxation, showed a good ICC. Interestingly, other studies⁵5 Ganapathi A, McCarron JA, Chen X, Iannotti JP. Predicting normal glenoid version from the pathologic scapula: a comparison of 4 methods in 2- and 3-dimensional models. J Shoulder Elbow Surg 2011;20(02):234–244,⁶6 Hoenecke HR Jr, Hermida JC, Flores-Hernandez C, D'Lima DD. Accuracy of CT-based measurements of glenoid version for total shoulder arthroplasty. J Shoulder Elbow Surg 2010;19(02):166–171,⁹9 Boileau P, Cheval D, Gauci MO, Holzer N, Chaoui J, Walch G. Automated Three-Dimensional Measurement of Glenoid Version and Inclination in Arthritic Shoulders. J Bone Joint Surg Am 2018; 100(01):57–65,¹⁰10 Gross DJ, Golijanin P, Dumont GD, et al. The effect of sagittal rotation of the glenoid on axial glenoid width and glenoid version in computed tomography scan imaging. J Shoulder Elbow Surg 2016;25(01):61–68 have shown that the version of the glenoid measured on 2D CT images presents significant interobserver variability due to the variation in the coronal and sagittal rotation of the scapula in relation to the patient's position on the examination table. However, in the present study, we obtained a good ICC, which we attribute to the fact that all evaluators are shoulder surgeons with more than five years of training and with experience in performing shoulder arthroplasties.

In the present study, the mean glenoid version measured through the automated method was similar to that obtained through the vault method. However, the version measured by the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method was lower than that obtained by the automated and vault methods. Still, based on the comparisons of the versions, only 1 case showed a difference greater than 10° when comparing the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method with the automated method. Therefore, it was shown that the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method is less accurate than the vault method when the automated method was used as a standard. In 2014, Matsumara et al.¹³13 Matsumura N, Ogawa K, Ikegami H, Collin P, Walch G, Toyama Y. Computed tomography measurement of glenoid vault version as an alternative measuring method for glenoid version. J Orthop Surg Res 2014;9(01):17 compared the measurement of the version by the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 and vault methods and, similarly, stated that both methods present good interobserver agreement, but that the vault method enables an easier measurement, since it does not depend on the anatomical variations of the body of the scapula or its inclusion in the exam.¹¹11 Lewis GS, Armstrong AD. Glenoid spherical orientation and version. J Shoulder Elbow Surg 2011;20(01):3–11,¹³13 Matsumura N, Ogawa K, Ikegami H, Collin P, Walch G, Toyama Y. Computed tomography measurement of glenoid vault version as an alternative measuring method for glenoid version. J Orthop Surg Res 2014;9(01):17,¹⁵15 RadiAnt® DICOM Viewer, Poznan, Poland. Available from: www.radiantviewer.com/pt-br
www.radiantviewer.com/pt-br... ,²³23 Shukla DR, McLaughlin RJ, Lee J, Nguyen NTV, Sanchez-Sotelo J. Automated three-dimensional measurements of version, inclination, and subluxation. Shoulder Elbow 2020;12(01):31–37

Remarkably, using the automated method as a standard, in cases in which the version was within the normal range, we did not observe significative differences between the automated and Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 methods; however, in cases in which the version was out of the normal range (> 10°), the mean version obtained by the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method was significantly lower than that obtained by the automated method. Altogether, these results enable us to conclude that the use of version measurement by the automated method is more important in cases in which deformities on the glenoid surface are more severe, possibly influencing the clinical practice, both in the correction of the version and in the correct positioning of the implant. This finding is compatible with that found in the literature, in which Chalmers et al.²⁶26 Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264 demonstrated that, in deformities classified as B2 using the morphological classification proposed by Walch et al.,⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760 the measurement of the version by CT images is superior.²⁶26 Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264,²⁷27 Bercik MJ, Kruse K II, Yalizis M, Gauci MO, Chaoui J, Walch G. A modification to the Walch classification of the glenoid in primary glenohumeral osteoarthritis using three-dimensional imaging. J Shoulder Elbow Surg 2016;25(10):1601–1606

In a recent study, Reid et al.²⁸28 Reid JJ, Kunkle BF, Greene AT, Eichinger JK, Friedman RJ. Variability and reliability of 2-dimensional vs. 3-dimensional glenoid version measurements with 3-dimensional preoperative planning software. J Shoulder Elbow Surg 2022;31(02):302–309 found results similar to ours, showing that the measurement of the version in 2D CT scans, using the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method, presents both high intra- and interclass correlation rates. On the other hand, this study²⁸28 Reid JJ, Kunkle BF, Greene AT, Eichinger JK, Friedman RJ. Variability and reliability of 2-dimensional vs. 3-dimensional glenoid version measurements with 3-dimensional preoperative planning software. J Shoulder Elbow Surg 2022;31(02):302–309 also found significant differences between measurements using manual and automated methods. However, when the cases were categorized according to version severity, the authors²⁸28 Reid JJ, Kunkle BF, Greene AT, Eichinger JK, Friedman RJ. Variability and reliability of 2-dimensional vs. 3-dimensional glenoid version measurements with 3-dimensional preoperative planning software. J Shoulder Elbow Surg 2022;31(02):302–309 did not find differences between the methods in the different subgroups evaluated, suggesting that the version magnitude does not influence the differences between the methods. This result contrasts with the findings of the present study, as we found that the manual method underestimated glenoid inclination, in comparison to automated method, in cases with a version greater than 10°. The different version ranges used to stratify the cases and the different diagnosis included in our series may explain these differences.

Glenoid inclination presented similar values when assessed by the manual or automated methods. Iannotti et al.,²¹21 Iannotti JP, Walker K, Rodriguez E, Patterson TE, Jun BJ, Ricchetti ET. Accuracy of 3-Dimensional Planning, Implant Templating, and Patient-Specific Instrumentation in Anatomic Total Shoulder Arthroplasty. J Bone Joint Surg Am 2019;101(05):446–457 regarding inclination measurements on formatted CT scans, observed that there were no differences from those obtained with the automated method. In relation to unformatted images, an expressive difference was found. In 94% of the cases, the difference in inclination between the unformatted and the formatted images was greater than 5°, again a value with significance in the clinical practice.²¹21 Iannotti JP, Walker K, Rodriguez E, Patterson TE, Jun BJ, Ricchetti ET. Accuracy of 3-Dimensional Planning, Implant Templating, and Patient-Specific Instrumentation in Anatomic Total Shoulder Arthroplasty. J Bone Joint Surg Am 2019;101(05):446–457 In our series, when the cases were categorized according to severity of the inclination, differences were found in the measurement of mild cases (0–10° of inclination), in which the manual method resulted in a mean that was significantly higher than that obtained by the automated method (p = 0.001). In a study published in 2020, Choi et al.²⁹29 Choi CH, Kim HC, Kang D, Kim JY. Comparative study of glenoid version and inclination using two-dimensional images from computed tomography and three-dimensional reconstructed bone models. Clin Shoulder Elbow 2020;23(03):119–124 compared inclination measured by automated and 2D methods and found that the 3D method resulted in measurements that were significatively lower than those obtained with the 2D method. Although the authors²⁹29 Choi CH, Kim HC, Kang D, Kim JY. Comparative study of glenoid version and inclination using two-dimensional images from computed tomography and three-dimensional reconstructed bone models. Clin Shoulder Elbow 2020;23(03):119–124 did not perform a subgroup analysis, the data evaluated presented mean values for version and inclination compatible with the cases included in the subgroup of mild cases of the present study.

In relation to subluxation, significant differences were found between the manual and automated methods. Other studies³⁰30 Jacxsens M, Van Tongel A, Willemot LB, Mueller AM, Valderrabano V, De Wilde L. Accuracy of the glenohumeral subluxation index in nonpathologic shoulders. J Shoulder Elbow Surg 2015;24(04): 541–546 have already reported an error intrinsic to the measurement of subluxation using the Walch et al.⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760 method. The subluxation index, described by Walch et al.,⁴4 Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760 is measured on a CT transverse cut. The scapular body has an inclination compared to the body of the patient in whom the CT cross-sections are aligned, which leads to errors in the 2D CT measurements.⁵5 Ganapathi A, McCarron JA, Chen X, Iannotti JP. Predicting normal glenoid version from the pathologic scapula: a comparison of 4 methods in 2- and 3-dimensional models. J Shoulder Elbow Surg 2011;20(02):234–244,¹⁰10 Gross DJ, Golijanin P, Dumont GD, et al. The effect of sagittal rotation of the glenoid on axial glenoid width and glenoid version in computed tomography scan imaging. J Shoulder Elbow Surg 2016;25(01):61–68,¹¹11 Lewis GS, Armstrong AD. Glenoid spherical orientation and version. J Shoulder Elbow Surg 2011;20(01):3–11,²⁶26 Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264,²⁷27 Bercik MJ, Kruse K II, Yalizis M, Gauci MO, Chaoui J, Walch G. A modification to the Walch classification of the glenoid in primary glenohumeral osteoarthritis using three-dimensional imaging. J Shoulder Elbow Surg 2016;25(10):1601–1606,³⁰30 Jacxsens M, Van Tongel A, Willemot LB, Mueller AM, Valderrabano V, De Wilde L. Accuracy of the glenohumeral subluxation index in nonpathologic shoulders. J Shoulder Elbow Surg 2015;24(04): 541–546 Jacxsens et al.³⁰30 Jacxsens M, Van Tongel A, Willemot LB, Mueller AM, Valderrabano V, De Wilde L. Accuracy of the glenohumeral subluxation index in nonpathologic shoulders. J Shoulder Elbow Surg 2015;24(04): 541–546 concluded that measurements based on shoulders reconstructed in 3D seem to be more appropriate, as they reconstruct the bone anatomy regardless of the patient's orientation at the time of the exam, and could be, therefore, another more reliable measurement than the 2D one, which is underestimated.

An interesting finding of the present study was that the differences between the subluxation measurements obtained by the automated and manual methods tended to increase with the severity of the version, suggesting that the greater the version angle, the more the manual method underestimates the measurement of the subluxation, when the automated method is used as the default. Further studies are needed to assess the clinical impact of such a finding, once it can directly impact on surgical planning.

Chalmers et al.²⁶26 Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264 evaluated the glenoid version and inclination and humeral head subluxation values using corrected and uncorrected CT scans, and compared these measurements with the values provided by the Blueprint software. They²⁶26 Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264 concluded that the orientation of the slices of CT scans formatted in the plane of the scapula presented a decrease in retroversion measurements compared to unformatted CT scans. On the other hand, the authors²⁶26 Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264 verified that there are no differences between unformatted CT scans and the values of automated programs. In 48% of the cases, the difference between the uncorrected and corrected versions was greater than 5°, which is considered significant in the clinical practice.²¹21 Iannotti JP, Walker K, Rodriguez E, Patterson TE, Jun BJ, Ricchetti ET. Accuracy of 3-Dimensional Planning, Implant Templating, and Patient-Specific Instrumentation in Anatomic Total Shoulder Arthroplasty. J Bone Joint Surg Am 2019;101(05):446–457 These findings are similar to the results obtained in our series.

Shukla et al.²³23 Shukla DR, McLaughlin RJ, Lee J, Nguyen NTV, Sanchez-Sotelo J. Automated three-dimensional measurements of version, inclination, and subluxation. Shoulder Elbow 2020;12(01):31–37 used the same automated program used in the present study and found similar results between the manual and automated methods for the measurements of version and inclination, but with an important difference in the percentage measurements of subluxation of the humeral head. Thus, like these authors,²³23 Shukla DR, McLaughlin RJ, Lee J, Nguyen NTV, Sanchez-Sotelo J. Automated three-dimensional measurements of version, inclination, and subluxation. Shoulder Elbow 2020;12(01):31–37 we believe that measuring the percentage of subluxation is essential in the preoperative planning of shoulder arthroplasty, and that such variability in the values of this parameter between the manual and automated methods should be taken into consideration, since the percentage of posterior head subluxation is a radiographic criterion that influences the surgical technique to be used and the selection of implants and manual measurements of this parameter are underestimated by the manual method.

As a limitation of the present study, we used a single automated preoperative planning program. We understand that these programs present a variability of measurements among them, since they use different anatomical parameters to format the images.

Conclusion

The manual method is effective in measuring the glenoid version and inclination when performed by experienced surgeons, and the vault method is more accurate than the Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method in patients with glenoids with greater deformities. However, the measurement of the percentage of posterior subluxation of the humeral head presents a great discrepancy between the manual and automated methods. Such differences underscore the need for further studies that aim to assess the impact of such differences on the outcome of procedures, since several uncertainties exist regarding the accuracy of manual and automated methods and the selection and correct positioning of the implants.

Financial Support

The authors declare that they have received no financial support from agencies in the public, private, or non-profit sectors to conduct the present study.
Work carried out at the Shoulder and Elbow Surgery Center, Instituto Nacional de Traumatologia e Ortopedia, Rio de Janeiro, RJ, Brazil.

References

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Walch G, Mesiha M, Boileau P, et al. Three-dimensional assessment of the dimensions of the osteoarthritic glenoid. Bone Joint J 2013;95-B(10):1377–1382
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Shapiro TA, McGarry MH, Gupta R, Lee YS, Lee TQ. Biomechanical effects of glenoid retroversion in total shoulder arthroplasty. J Shoulder Elbow Surg 2007;16(3, Suppl)S90–S95
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Iannotti JP, Greeson C, Downing D, Sabesan V, Bryan JA. Effect of glenoid deformity on glenoid component placement in primary shoulder arthroplasty. J Shoulder Elbow Surg 2012;21(01):48–55
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Walch G, Badet R, Boulahia A, Khoury A. Morphologic study of the glenoid in primary glenohumeral osteoarthritis. J Arthroplasty 1999;14(06):756–760
⁵
Ganapathi A, McCarron JA, Chen X, Iannotti JP. Predicting normal glenoid version from the pathologic scapula: a comparison of 4 methods in 2- and 3-dimensional models. J Shoulder Elbow Surg 2011;20(02):234–244
⁶
Hoenecke HR Jr, Hermida JC, Flores-Hernandez C, D'Lima DD. Accuracy of CT-based measurements of glenoid version for total shoulder arthroplasty. J Shoulder Elbow Surg 2010;19(02):166–171
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Scalise JJ, Bryan J, Polster J, Brems JJ, Iannotti JP. Quantitative analysis of glenoid bone loss in osteoarthritis using three-dimensional computed tomography scans. J Shoulder Elbow Surg 2008; 17(02):328–335
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Iannotti J, Baker J, Rodriguez E, et al. Three-dimensional preoperative planning software and a novel information transfer technology improve glenoid component positioning. J Bone Joint Surg Am 2014;96(09):e71
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Boileau P, Cheval D, Gauci MO, Holzer N, Chaoui J, Walch G. Automated Three-Dimensional Measurement of Glenoid Version and Inclination in Arthritic Shoulders. J Bone Joint Surg Am 2018; 100(01):57–65
¹⁰
Gross DJ, Golijanin P, Dumont GD, et al. The effect of sagittal rotation of the glenoid on axial glenoid width and glenoid version in computed tomography scan imaging. J Shoulder Elbow Surg 2016;25(01):61–68
¹¹
Lewis GS, Armstrong AD. Glenoid spherical orientation and version. J Shoulder Elbow Surg 2011;20(01):3–11
¹²
Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037
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Matsumura N, Ogawa K, Ikegami H, Collin P, Walch G, Toyama Y. Computed tomography measurement of glenoid vault version as an alternative measuring method for glenoid version. J Orthop Surg Res 2014;9(01):17
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Maurer A, Fucentese SF, Pfirrmann CW, et al. Assessment of glenoid inclination on routine clinical radiographs and computed tomography examinations of the shoulder. J Shoulder Elbow Surg 2012;21(08):1096–1103
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RadiAnt® DICOM Viewer, Poznan, Poland. Available from: www.radiantviewer.com/pt-br
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van de Bunt F, Pearl ML, Lee EK, Peng L, Didomenico P. Glenoid version by CT scan: an analysis of clinical measurement error and introduction of a protocol to reduce variability. Skeletal Radiol 2015;44(11):1627–1635
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Favard L, Berhouet J, Walch G, Chaoui J, Lévigne C. Superior glenoid inclination and glenoid bone loss : Definition, assessment, biomechanical consequences, and surgical options. Orthopade 2017;46(12):1015–1021
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Hartzler RU, Denard PJ, Griffin JW, Werner BC, Romeo AA. Surgeon acceptance of an initial 3D glenoid preoperative plan: rates and risk factors. J Shoulder Elbow Surg 2021;30(04):787–794
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Shukla DR, McLaughlin RJ, Lee J, Nguyen NTV, Sanchez-Sotelo J. Automated three-dimensional measurements of version, inclination, and subluxation. Shoulder Elbow 2020;12(01):31–37
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Chalmers PN, Salazar D, Chamberlain A, Keener JD. Radiographic characterization of the B2 glenoid: the effect of computed tomographic axis orientation. J Shoulder Elbow Surg 2017;26(02):258–264
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Bercik MJ, Kruse K II, Yalizis M, Gauci MO, Chaoui J, Walch G. A modification to the Walch classification of the glenoid in primary glenohumeral osteoarthritis using three-dimensional imaging. J Shoulder Elbow Surg 2016;25(10):1601–1606
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Reid JJ, Kunkle BF, Greene AT, Eichinger JK, Friedman RJ. Variability and reliability of 2-dimensional vs. 3-dimensional glenoid version measurements with 3-dimensional preoperative planning software. J Shoulder Elbow Surg 2022;31(02):302–309
²⁹
Choi CH, Kim HC, Kang D, Kim JY. Comparative study of glenoid version and inclination using two-dimensional images from computed tomography and three-dimensional reconstructed bone models. Clin Shoulder Elbow 2020;23(03):119–124
³⁰
Jacxsens M, Van Tongel A, Willemot LB, Mueller AM, Valderrabano V, De Wilde L. Accuracy of the glenohumeral subluxation index in nonpathologic shoulders. J Shoulder Elbow Surg 2015;24(04): 541–546

Publication Dates

Publication in this collection
23 Sept 2024
Date of issue
2024

History

Received
22 Sept 2023
Accepted
05 Apr 2024
Published
08 July 2024

This is an open access article published by Thieme under the terms of the Creative Commons Attribution 4.0 International License, permitting copying and reproduction so long as the original work is given appropriate credit

[1] Financial Support

The authors declare that they have received no financial support from agencies in the public, private, or non-profit sectors to conduct the present study.

[2] Work carried out at the Shoulder and Elbow Surgery Center, Instituto Nacional de Traumatologia e Ortopedia, Rio de Janeiro, RJ, Brazil.

Variables	ICC	Inferior confidence interval	Superior confidence interval
Version according to the Friedman et al. ¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037 method	0.847	0.751	0.913
Version according to the vault method	0.845	0.744	0.931
Inclination	0.890	0.821	0.938
Subluxation	0.840	0.712	0.917

	Blueprint	Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037	Vault
Version (mean ± standard deviation)	10.45° ± 7.1°^a a p = 0.0059 Friedman et al.12 test, Dunn posttest;	8.07° ± 6.1°^a a p = 0.0059 Friedman et al.12 test, Dunn posttest; , ^b b p = 0.0005, Friedman et al.12 test, Dunn posttest.	10.42° ± 6.2°^b b p = 0.0005, Friedman et al.12 test, Dunn posttest.
Average difference(95% confidence interval)	–	2.37° (0.79–3.9°)	0.023° (−1.8–1.9°)
Maximum difference		11°	13.64°

	Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037	Vault
Difference < 5° in relation to the Blueprint software: n (%)	23 (60.5%)	21 (57.8%)
Difference of 5–10° in relation to the Blueprint software: n (%)	14 (36.8%)	13 (34.2%)
Difference > 10° in relation to the Blueprint software: n (%)	1 (2.6%)	3 (7.8%)

Version (°)		Parameter		p-value
Version (°): mean ± standard deviation
	Blueprint	Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037	Vault
0–10 (n = 21)	5.6 ± 2.8^a a p = 0.04;	5.4 ± 4.0^b b p = 0.0004;	7.7 ± 3.9^a a p = 0.04; , ^b b p = 0.0004;	0.01^* * One-way analysis of variance (ANOVA);
> 10 (n = 17)	16.3 ± 6.5^c c p = 0.001; Tukey multiple comparisons test;	11.3 ± 6.9^c c p = 0.001; Tukey multiple comparisons test;	13.7 ± 7.0	0.0061^* * One-way analysis of variance (ANOVA);
Inclination (°): mean ± standard deviation
	Blueprint	Manual
0–10 (n = 21)	11.5 ± 11.5	10.9 ± 6.0		0.7^# # t-test.
> 10 (n = 17)	10.8 ± 5.0	11.4 ± 4.8		0.5^# # t-test.
Subluxation (°): mean ± standard deviation
	Blueprint	Manual
0–10 (n = 21)	51.3 ± 10.4	45.7 ± 7.2		0.005^# # t-test.
> 10 (n = 17)	69.8 ± 12.5	52.0 ± 7.1		< 0.0001^# # t-test.

Inclination (°)		Parameter		p-value
Version (°): mean ± standard deviation
	Blueprint	Friedman et al.¹²12 Friedman RJ, Hawthorne KB, Genez BM. The use of computerized tomography in the measurement of glenoid version. J Bone Joint Surg Am 1992;74(07):1032–1037	Vault
0–10 (n = 21)	8.9 ± 6.4	8.3 ± 6.2^a a p = 0.01;	10.9 ± 7.3^a a p = 0.01;	0.03^* * One-way analysis of variance (ANOVA);
> 10 (n = 17)	12.3 ± 7.8^b b p = 0.002;	7.7 ± 6.3^b b p = 0.002; ,^c c p = 0.007; Tukey multiple comparisons test;	9.7 ± 4.8^c c p = 0.007; Tukey multiple comparisons test;	0.003^* * One-way analysis of variance (ANOVA);
Inclination (°): mean ± standard deviation
	Blueprint		Manual
0–10 (n = 21)	5.9 ± 2.9		8.7 ± 3.8	0.001^# # t-test.
> 10 (n = 17)	17.6 ± 9.9		14.0 ± 5.8	0.1^# # t-test.
Subluxation (°): mean ± standard deviation
	Blueprint		Manual
0–10 (n = 21)	60.33 ± 15.0		49.9 ± 6.8	0.0001^# # t-test.
>10 (n = 17)	58.7 ± 14.5		46.8 ± 8.6	0.000 ^# # t-test.

Brasil

Brasil

Comparison of Manual Two-dimensional and Automated Three-dimensional Methods of Assessing Shoulder Joint Morphology through Computed Tomography Images

Abstract

Objective

Methods

Results

Conclusion

Resumo

Objetivo

Métodos

Resultados

Conclusão

Introduction

Materials and Methods

Selection of Cases

Manual Measurement

Automated Measurement

Statistical Analysis

Results

Discussion

Conclusion

Financial Support

References

Publication Dates

History

	Blueprint	Manual	p
Inclination (mean ± standard deviation)	11.85° ± 9.8°	11.24° ± 5.44°	0.377
Subluxation (mean ± standard deviation)	60.08° ± 14.72°	48.47° ± 7.67°	< 0.0001