The Role of Cone Beam Computed Tomography in Periodontology: From 3D Models of Periodontal Defects to 3D-Printed Scaffolds.
Styliani VerykokouCharalabos IoannidisSofia SoileChristos AngelopoulosKonstantinos TheodoridisAthanasios S ArampatzisAndreana N AssimopoulouDimitrios ChristofilosAfroditi KapouraniIoannis PantazosPanagiotis BarmpalexisArgyro-Maria BoutsiChryssy PotsiouPublished in: Journal of personalized medicine (2024)
The treatment of osseous defects around teeth is a fundamental concern within the field of periodontology. Over the years, the method of grafting has been employed to treat bone defects, underscoring the necessity for custom-designed scaffolds that precisely match the anatomical intricacies of the bone cavity to be filled, preventing the formation of gaps that could allow the regeneration of soft tissues. In order to create such a patient-specific scaffold (bone graft), it is imperative to have a highly detailed 3D representation of the bone defect, so that the resulting scaffold aligns with the ideal anatomical characteristics of the bone defect. In this context, this article implements a workflow for designing 3D models out of patient-specific tissue defects, fabricated as scaffolds with 3D-printing technology and bioabsorbable materials, for the personalized treatment of periodontitis. The workflow is based on 3D modeling of the hard tissues around the periodontal defect (alveolar bone and teeth), scanned from patients with periodontitis. Specifically, cone beam computed tomography (CBCT) data were acquired from patients and were used for the reconstruction of the 3D model of the periodontal defect. The final step encompasses the 3D printing of these scaffolds, employing Fused Deposition Modeling (FDM) technology and 3D-bioprinting, with the aim of verifying the design accuracy of the developed methodοlogy. Unlike most existing 3D-printed scaffolds reported in the literature, which are either pre-designed or have a standard structure, this method leads to the creation of highly detailed patient-specific grafts. Greater accuracy and resolution in the macroarchitecture of the scaffolds were achieved during FDM printing compared to bioprinting, with the standard FDM printing profile identified as more suitable in terms of both time and precision. It is easy to follow and has been successfully employed to create 3D models of periodontal defects and 3D-printed scaffolds for three cases of patients, proving its applicability and efficiency in designing and fabricating personalized 3D-printed bone grafts using CBCT data.
Keyphrases
- cone beam computed tomography
- tissue engineering
- bone mineral density
- soft tissue
- end stage renal disease
- bone loss
- bone regeneration
- electronic health record
- ejection fraction
- gene expression
- postmenopausal women
- magnetic resonance imaging
- newly diagnosed
- chronic kidney disease
- systematic review
- prognostic factors
- peritoneal dialysis
- body composition
- magnetic resonance
- computed tomography
- deep learning
- patient reported outcomes
- big data