The residual STL volume as a metric to evaluate accuracy and reproducibility of anatomic models for 3D printing: application in the validation of 3D-printable models of maxillofacial bone from reduced radiation dose CT images

The residual STL volume as a metric to evaluate accuracy and reproducibility of anatomic models for 3D printing: application in the validation of 3D-printable models of maxillofacial bone from reduced radiation dose CT images

Background The effects of reduced radiation dose CT for the generation of maxillofacial bone STL models for 3D printing is currently unknown. Images of two full-face transplantation patients scanned with non-contrast 320-detector row CT were reconstructed at fractions of the acquisition radiation do...

Full description

Saved in:
Bibliographic Details
Published in:3D printing in medicine Vol. 1; no. 1; p. 2
Main Authors: Cai, Tianrun, Rybicki, Frank J., Giannopoulos, Andreas A., Schultz, Kurt, Kumamaru, Kanako K., Liacouras, Peter, Demehri, Shadpour, Shu Small, Kirstin M., Mitsouras, Dimitris
Format: Journal Article
Language:English
Published: Cham Springer International Publishing 01-01-2015
Springer Nature B.V
Subjects:
3-D printers
Biomaterials
Biomedical Engineering and Bioengineering
Computed tomography
Fractions
Image contrast
Image reconstruction
Imaging
Maxillofacial
Medical imaging
Medicine
Medicine & Public Health
Printing
Radiation dosage
Radiology
Reproducibility
Surgery
Thin walled shells
Three dimensional printing
Residual Volume
Hounsfield Unit
Filter Back Projection
Filter Back Projection Reconstruction
DICOM Image
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Background The effects of reduced radiation dose CT for the generation of maxillofacial bone STL models for 3D printing is currently unknown. Images of two full-face transplantation patients scanned with non-contrast 320-detector row CT were reconstructed at fractions of the acquisition radiation dose using noise simulation software and both filtered back-projection (FBP) and Adaptive Iterative Dose Reduction 3D (AIDR3D). The maxillofacial bone STL model segmented with thresholding from AIDR3D images at 100 % dose was considered the reference. For all other dose/reconstruction method combinations, a “residual STL volume” was calculated as the topologic subtraction of the STL model derived from that dataset from the reference and correlated to radiation dose. Results The residual volume decreased with increasing radiation dose and was lower for AIDR3D compared to FBP reconstructions at all doses. As a fraction of the reference STL volume, the residual volume decreased from 2.9 % (20 % dose) to 1.4 % (50 % dose) in patient 1, and from 4.1 % to 1.9 %, respectively in patient 2 for AIDR3D reconstructions. For FBP reconstructions it decreased from 3.3 % (20 % dose) to 1.0 % (100 % dose) in patient 1, and from 5.5 % to 1.6 %, respectively in patient 2. Its morphology resembled a thin shell on the osseous surface with average thickness <0.1 mm. Conclusion The residual volume, a topological difference metric of STL models of tissue depicted in DICOM images supports that reduction of CT dose by up to 80 % of the clinical acquisition in conjunction with iterative reconstruction yields maxillofacial bone models accurate for 3D printing.
ISSN:2365-6271
2365-6271
DOI:10.1186/s41205-015-0003-3