Skin deformation analysis for pre-operative planning of DIEAP flap reconstruction surgery

•Statistic analysis of the patient's position at the CTA scan and at the surgical table.•Deformation errors need to be controlled to achieve high fidelity 3D model anchorage.•3D surface data (manual and automatic) alignment revealed relevant deformation.•30% cases of deformation are above 3 mm...

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Bibliographic Details
Published in:Medical engineering & physics 2023-09, Vol.119, p.104025-104025, Article 104025
Main Authors: Timóteo, Rafaela, Pinto, David, Martinho, Marta, Gouveia, Pedro, Lopes, Daniel Simões, Mavioso, Carlos, Cardoso, Maria João
Format: Article
Language:English
Subjects:
3D surface scan
Augmented reality
Deep inferior epigastric artery flap
Mesh alignment
Skin deformation
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Summary:•Statistic analysis of the patient's position at the CTA scan and at the surgical table.•Deformation errors need to be controlled to achieve high fidelity 3D model anchorage.•3D surface data (manual and automatic) alignment revealed relevant deformation.•30% cases of deformation are above 3 mm and 15% are above 4 mm. Deep inferior epigastric artery perforator (DIEAP) flap reconstruction surgeries can potentially benefit from augmented reality (AR) in the context of surgery planning and outcomes improvement. Although three-dimensional (3D) models help visualize and map the perforators, the anchorage of the models to the patient's body during surgery does not consider eventual skin deformation from the moment of computed tomography angiography (CTA) data acquisition until the position of the patient while in surgery. In this work, we compared the 3D deformation registration from supine arms down (CTA position) to supine with arms at 90° degrees (surgical position), estimating the patient's skin deformation. We processed the data sets of 20 volunteers with a 3D rigid registration tool and performed a descriptive statistical analysis and statistical inference. With 2.45 mm of root mean square and 2.89 mm of standard deviation, results include 30% cases of deformation above 3 mm and 15% above 4 mm. Pose transformation deformation indicates that 3D surface data from the CTA scan position differs from data acquired in loco at the surgical table. Such results indicate that research should be conducted to construct accurate 3D models using CTA data to display on the patient, while considering projection errors when using AR technology.
ISSN:1350-4533
1873-4030
DOI:10.1016/j.medengphy.2023.104025