Construction and accuracy assessment of patient-specific biocompatible drill template for cervical anterior transpedicular screw (ATPS) insertion: an in vitro study

With the properties of three-column fixation and anterior-approach-only procedure, anterior transpedicular screw (ATPS) is ideal for severe multilevel traumatic cervical instabilities. However, the accurate insertion of ATPS remains challenging. Here we constructed a patient-specific biocompatible d...

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Bibliographic Details
Published in:PloS one 2013-01, Vol.8 (1), p.e53580-e53580
Main Authors: Fu, Maoqing, Lin, Lijun, Kong, Xiangxue, Zhao, Weidong, Tang, Lei, Li, Jianyi, Ouyang, Jun
Format: Article
Language:English
Subjects:
Accuracy
Aged
Analysis
Biocompatibility
Biocompatible Materials - pharmacology
Biology
Biomechanics
Bone Screws
CAD
Cadavers
CAT scans
Cement
Cervical Vertebrae - drug effects
Computed tomography
Computer aided design
Computer simulation
Cytotoxicity
Engineering
Ethics
Female
Formaldehyde
Humans
Imaging, Three-Dimensional
In Vitro Techniques
Insertion
Laboratories
Male
Materials Testing - methods
Medicine
Middle Aged
Models, Anatomic
Multilevel
Orthopedic Procedures - methods
Patient assessment
Planes
Polymethyl methacrylate
Polymethylmethacrylate
Printing
Quality
Rapid prototyping
Reconstruction
Science
Screws
Spine
Surgery
Therapeutic applications
Three dimensional models
Vertebra
Vertebrae
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Summary:With the properties of three-column fixation and anterior-approach-only procedure, anterior transpedicular screw (ATPS) is ideal for severe multilevel traumatic cervical instabilities. However, the accurate insertion of ATPS remains challenging. Here we constructed a patient-specific biocompatible drill template and evaluated its accuracy in assisting ATPS insertion. After ethical approval, 24 formalin-preserved cervical vertebrae (C2-C7) were CT scanned. 3D reconstruction models of cervical vertebra were obtained with 2-mm-diameter virtual pin tracts at the central pedicles. The 3D models were used for rapid prototyping (RP) printing. A 2-mm-diameter Kirschner wire was then inserted into the pin tract of the RP model before polymethylmethacrylate was used to construct the patient-specific biocompatible drill template. After removal of the anterior soft tissue, a 2-mm-diameter Kirschner wire was inserted into the cervical pedicle with the assistance of drill template. Cadaveric cervical spines with pin tracts were subsequently scanned using the same CT scanner. A 3D reconstruction was performed of the scanned spines to get 3D models of the vertebrae containing the actual pin tracts. The deviations were calculated between 3D models with virtual and actual pin tracts at the middle point of the cervical pedicle. 3D models of 3.5 mm-diameter screws were used in simulated insertion to grade the screw positions. The patient-specific biocompatible drill template was constructed to assist ATPS insertion successfully. There were no significant differences between medial/lateral deviations (P = 0.797) or between superior/inferior deviations (P = 0.741). The absolute deviation values were 0.82±0.75 mm and 1.10±0.96 mm in axial and sagittal planes, respectively. In the simulated insertion, the screws in non-critical position were 44/48 (91.7%). The patient-specific drill template is biocompatible, easy-to-apply and accurate in assisting ATPS insertion. Its clinical applications should be further researched.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0053580