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. 2020 Sep 18;10(1):15346.
doi: 10.1038/s41598-020-72143-y.

Combining deep learning with 3D stereophotogrammetry for craniosynostosis diagnosis

Guido de Jong  1 Elmar Bijlsma  2 Jene Meulstee  3   4 Myrte Wennen  2   5 Erik van Lindert  2 Thomas Maal  3   4 René Aquarius  2 Hans Delye  2
Affiliations

Combining deep learning with 3D stereophotogrammetry for craniosynostosis diagnosis

Guido de Jong et al. Sci Rep. .

Abstract

Craniosynostosis is a condition in which cranial sutures fuse prematurely, causing problems in normal brain and skull growth in infants. To limit the extent of cosmetic and functional problems, swift diagnosis is needed. The goal of this study is to investigate if a deep learning algorithm is capable of correctly classifying the head shape of infants as either healthy controls, or as one of the following three craniosynostosis subtypes; scaphocephaly, trigonocephaly or anterior plagiocephaly. In order to acquire cranial shape data, 3D stereophotographs were made during routine pre-operative appointments of scaphocephaly (n = 76), trigonocephaly (n = 40) and anterior plagiocephaly (n = 27) patients. 3D Stereophotographs of healthy infants (n = 53) were made between the age of 3-6 months. The cranial shape data was sampled and a deep learning network was used to classify the cranial shape data as either: healthy control, scaphocephaly patient, trigonocephaly patient or anterior plagiocephaly patient. For the training and testing of the deep learning network, a stratified tenfold cross validation was used. During testing 195 out of 196 3D stereophotographs (99.5%) were correctly classified. This study shows that trained deep learning algorithms, based on 3D stereophotographs, can discriminate between craniosynostosis subtypes and healthy controls with high accuracy.

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Conflict of interest statement

The authors declare no competing interests.

Figures

Figure 1
Figure 1
2D schematic representation of the head shape raycasting technique using a hemi-icosphere to determine the ray length from the sella turcica to the intersection of the outer surface of the 3D stereophotograph of the head.
Figure 2
Figure 2
A subject’s original 3D stereophotograph and its mirrored counterpart stay linked throughout training and testing of the deep learning network to prevent cross-over.
See this image and copyright information in PMC

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