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Journal of Imaging Informatics in Medicine

Erschienen in:

06.08.2019

Assessing the Bone Age of Children in an Automatic Manner Newborn to 18 Years Range

verfasst von: Farzaneh Dehghani, Alireza Karimian, Mehri Sirous

Erschienen in: Journal of Imaging Informatics in Medicine | Ausgabe 2/2020

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Abstract

Bone age assessment (BAA) is a radiological process to identify the growth disorders in children. Although this is a frequent task for radiologists, it is cumbersome. The objective of this study is to assess the bone age of children from newborn to 18 years old in an automatic manner through computer vision methods including histogram of oriented gradients (HOG), local binary pattern (LBP), and scale invariant feature transform (SIFT). Here, 442 left-hand radiographs are applied from the University of Southern California (USC) hand atlas. In this experiment, for the first time, HOG–LBP–dense SIFT features with background subtraction are applied to assess the bone age of the subject group. For this purpose, features are extracted from the carpal and epiphyseal regions of interest (ROIs). The SVM and 5-fold cross-validation are used for classification. The accuracy of female radiographs is 73.88% and of the male is 68.63%. The mean absolute error is 0.5 years for both genders’ radiographs. The accuracy a within 1-year range is 95.32% for female and 96.51% for male radiographs. The accuracy within a 2-year range is 100% and 99.41% for female and male radiographs, respectively. The Cohen’s kappa statistical test reveals that this proposed approach, Cohen’s kappa coefficients are 0.71 for female and 0.66 for male radiographs, p value < 0.05, is in substantial agreement with the bone age assessed by experienced radiologists within the USC dataset. This approach is robust and easy to implement, thus, qualified for computer-aided diagnosis (CAD). The reduced processing time and number of ROIs facilitate BAA.

Nur mit Berechtigung zugänglich

Moradi M, Sirous M, and Morovatti P The reliability of skeletal age determination in an Iranian sample using Greulich and Pyle method. Forensic science international, vol. 223, pp. 372. e1–372. e4, 2012

Greulich WW, Pyle SI: Radiographic atlas of skeletal development of hand wrist. California: Stanford University Press, 1971

Tanner J, Healy M, Goldstein H, Cameron N: Assessment of Skeletal Maturity and Predication of Adult height (TW3 Method). WB Saunders, 2001

De Sanctis V, Soliman AT, Di Maio S, Bedair S: Are the new automated methods for bone age estimation advantageous over the manual approaches? Pediatric endocrinology reviews: PER 12:200–205, 2014PubMed

Satoh M: Bone age: assessment methods and clinical applications. Clinical Pediatric Endocrinology 24:143–152, 2015CrossRef

Pietka E, Gertych A, Pospiech S, Cao F, Huang H, Gilsanz V: Computer-assisted bone age assessment: Image preprocessing and epiphyseal/metaphyseal ROI extraction. IEEE transactions on medical imaging 20:715–729, 2001CrossRef

Fischer B, Welter P, Günther RW, Deserno TM: Web-based bone age assessment by content-based image retrieval for case-based reasoning. International journal of computer assisted radiology and surgery 7:389–399, 2012CrossRef

Kashif M, Deserno TM, Haak D, Jonas S: Feature description with SIFT, SURF, BRIEF, BRISK, or FREAK? A general question answered for bone age assessment. Computers in biology and medicine 68:67–75, 2016CrossRef

Lee H, Tajmir S, Lee J, Zissen M, Yeshiwas BA, Alkasab TK, Choy G, Do S: Fully automated deep learning system for bone age assessment. Journal of digital imaging 30:427–441, 2017CrossRef

10.

Larson DB, Chen MC, Lungren MP, Halabi SS, Stence NV, Langlotz CP: Performance of a deep-learning neural network model in assessing skeletal maturity on pediatric hand radiographs. Radiology 287:313–322, 2017CrossRef

11.

Halabi SS, Prevedello LM, Kalpathy-Cramer J, Mamonov AB, Bilbily A, Cicero M et al.: The RSNA Pediatric Bone Age Machine Learning Challenge. Radiology:180736, 2018

12.

Dalal N, Triggs B: Histograms of oriented gradients for human detection In Computer Vision and Pattern Recognition, 2005. CVPR 2005. IEEE Computer Society Conference on, 2005, pp. 886–893.

13.

Houam L, Hafiane A, Boukrouche A, Lespessailles E, Jennane R: One dimensional local binary pattern for bone texture characterization. Pattern Analysis and Applications 17:179–193, 2014CrossRef

14.

Lowe DG: Distinctive image features from scale-invariant keypoints. International journal of computer vision 60:91–110, 2004CrossRef

15.

Gertych A, Zhang A, Sayre J, Pospiech-Kurkowska S, Huang H: Bone age assessment of children using a digital hand atlas. Computerized Medical Imaging and Graphics 31:322–331, 2007CrossRef

16.

Perona P, Malik J: Scale-space and edge detection using anisotropic diffusion. IEEE Transactions on pattern analysis and machine intelligence 12:629–639, 1990CrossRef

17.

Güraksin GE, Uğuz H, Baykan ÖK: Bone age determination in young children (newborn to 6 years old) using support vector machines. Turkish Journal of Electrical Engineering & Computer Sciences 24:1693–1708, 2016CrossRef

18.

Wang Q, Yang J: Eye location and eye state detection in facial images with unconstrained background. Journal of Information and Computing Science 1:284–289, 2006

19.

Wang X, Han TX, Yan S: An HOG-LBP human detector with partial occlusion handling. In Computer Vision, 2009 IEEE 12th International conference on, 2009, pp. 32–39.

20.

Ojala T, Pietikäinen M, Mäenpää T: Gray scale and rotation invariant texture classification with local binary patterns. European Conference on Computer Vision:404–420, 2000

21.

Ojala T, Pietikainen M, Maenpaa T: Multiresolution gray-scale and rotation invariant texture classification with local binary patterns. IEEE Transactions on pattern analysis and machine intelligence 24:971–987, 2002CrossRef

22.

Lingras P, Butz C: Rough set based 1-v-1 and 1-vr approaches to support vector machine multi-classification. Information Sciences 177:3782–3798, 2007CrossRef

23.

Hsu C-W, Lin C-J: A comparison of methods for multiclass support vector machines. IEEE transactions on Neural Networks 13:415–425, 2002CrossRef

24.

Bishop CM: Pattern recognition and machine learning (information science and statistics). New York: Springer, 2006

25.

Sokolova M, Lapalme G: A systematic analysis of performance measures for classification tasks. Information Processing & Management 45:427–437, 2009CrossRef

26.

Zhang A, Gertych A, Liu BJ: Automatic bone age assessment for young children from newborn to 7-year-old using carpal bones. Computerized Medical Imaging and Graphics 31:299–310, 2007CrossRef

27.

Somkantha K, Theera-Umpon N, Auephanwiriyakul S: Bone age assessment in young children using automatic carpal bone feature extraction and support vector regression. Journal of digital imaging 24:1044–1058, 2011CrossRef

28.

Güraksın GE, Haklı H, Uğuz H: Support vector machines classification based on particle swarm optimization for bone age determination. Applied Soft Computing 24:597–602, 2014CrossRef

29.

Thodberg HH, Kreiborg S, Juul A, Pedersen KD: The BoneXpert method for automated determination of skeletal maturity. IEEE transactions on medical imaging 28:52–66, 2009CrossRef

Titel: Assessing the Bone Age of Children in an Automatic Manner Newborn to 18 Years Range
verfasst von: Farzaneh Dehghani
Alireza Karimian
Mehri Sirous
Publikationsdatum: 06.08.2019
Verlag: Springer International Publishing
Erschienen in: Journal of Imaging Informatics in Medicine / Ausgabe 2/2020
Print ISSN: 2948-2925
Elektronische ISSN: 2948-2933
DOI: https://doi.org/10.1007/s10278-019-00209-z

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