Validation of a fibula graft cutting guide for mandibular reconstruction: experiment with rapid prototyping mandible model

Lim, Se-Ho; Kim, Yeonho; Kim, Moon-Key; Nam, Woong; Kang, Sang-Hoon

doi:10.3109/24699322.2016.1167245

Cited by 12 publications

(8 citation statements)

References 11 publications

(13 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The results achieved with the MUC-Jig occasionally differed from those achieved with the template at >30 • angles. However, this deviation is still within limits, and it hardly differs from length [16][17][18][22][23][24][25] and angle [18,26,27] deviations of other studies. In the present study, the largest length deviations were usually located in the regions furthest away from the stop.…”

Section: Discussioncontrasting

confidence: 67%

Fibula Graft Cutting Devices: Are 3D-Printed Cutting Guides More Precise than a Universal, Reusable Osteotomy Jig?

Meyer

Hirsch

Leiggener

et al. 2020

JCM

View full text Add to dashboard Cite

Individual cutting guides for the reconstruction of lower jaw defects with fibular grafts are often used. However, the application of these osteotomy tools is costly and time intensive. The aim of this study was to compare the precision of osteotomies using a 3D-printed guide with those using a universal, reusable, and more cost-efficient Multi-Use Cutting Jig (MUC-Jig). In this non-blinded experimental study, 10 cranio-maxillofacial surgeons performed four graft removals each in a randomized order using the same osteotomy angle, both proximally (sagittal cut) and distally (coronal cut), of a graft (45°, 30°, 15°, or 0°), first with the MUC-Jig then with the 3D-printed cutting guide. The 40 fibula transplants (Tx) of each method (n = 80) were then analyzed concerning their Tx length and osteotomy angles and compared to the original planning data. Furthermore, the surgeons’ subjective perception and the duration of the two procedures were analyzed. The mean relative length and mean relative angle deviation between the MUC-Jig (−0.08 ± 1.12 mm; −0.69° ± 3.15°) and the template (0.22 ± 0.90 mm; 0.36° ± 2.56°) group differed significantly (p = 0.002; p = < 0.001), but the absolute deviations did not (p = 0.206; p = 0.980). Consequently, clinically comparable osteotomy results can be achieved with both methods, but from an economic point of view the MUC-Jig is a more cost-efficient solution.

show abstract

Section: Discussioncontrasting

confidence: 67%

Fibula Graft Cutting Devices: Are 3D-Printed Cutting Guides More Precise than a Universal, Reusable Osteotomy Jig?

Meyer

Hirsch

Leiggener

et al. 2020

JCM

View full text Add to dashboard Cite

show abstract

“…[ 54 ] Validation Study Japan Cranial Surgery Craniotomy Training, Simulation 2016 Lim SH et Al. [ 55 ] Validation Study Korea Macillo-Facial Surgery Mandible reconstruction Planning 2015 Pacione D et al [ 56 ] Pilot Study USA Maxillofacial Surgery Deformity of the skull base and craniovertebral junction Planning 2015 Chan HHL et al [ 57 ] Case Series Canada Maxillofacial Surgery Head and neck surgery Training, Simulation 2015 Dickinson KJ et al [ 58 ] Case Report USA Maxillofacial Surgery Endoscopic resection in esophagus Planning 2015 Hochman JB et al [ 59 ] Comparative Study Canada Maxillofacial Surgery Mastoidectomy and skull base surgery Training 2015 Cohen J et al [ 60 ] Validation Study USA Maxillofacial Surgery Mastoidectomy Training 2015 Lim C et al [ 17 ] Case Series Australia - New Zealand Maxillofacial Surgery Orbital reconstruction Planning 2015 Rose AS et al [ 61 ] Case Report USA ENT Surgery Mastoidectomy Planning, Simulation 2015 Ernoult C. et Al. [ 62 ] Case Series France Maxillofacial Surgery ...…”

Section: Resultsmentioning

confidence: 99%

3D printed bone models in oral and cranio-maxillofacial surgery: a systematic review

et al. 2020

View full text Add to dashboard Cite

Aim This systematic review aimed to evaluate the use of three-dimensional (3D) printed bone models for training, simulating and/or planning interventions in oral and cranio-maxillofacial surgery. Materials and methods A systematic search was conducted using PubMed® and SCOPUS® databases, up to March 10, 2019, by following the Preferred Reporting Items for Systematic reviews and Meta-Analysis (PRISMA) protocol. Study selection, quality assessment (modified Critical Appraisal Skills Program tool) and data extraction were performed by two independent reviewers. All original full papers written in English/French/Italian and dealing with the fabrication of 3D printed models of head bone structures, designed from 3D radiological data were included. Multiple parameters and data were investigated, such as author’s purpose, data acquisition systems, printing technologies and materials, accuracy, haptic feedback, variations in treatment time, differences in clinical outcomes, costs, production time and cost-effectiveness. Results Among the 1157 retrieved abstracts, only 69 met the inclusion criteria. 3D printed bone models were mainly used as training or simulation models for tumor removal, or bone reconstruction. Material jetting printers showed best performance but the highest cost. Stereolithographic, laser sintering and binder jetting printers allowed to create accurate models with adequate haptic feedback. The cheap fused deposition modeling printers exhibited satisfactory results for creating training models. Conclusion Patient-specific 3D printed models are known to be useful surgical and educational tools. Faced with the large diversity of software, printing technologies and materials, the clinical team should invest in a 3D printer specifically adapted to the final application.

show abstract

“…In recent years, computer‐assisted surgery (CAS) has been recognized as a valuable method to support FFF mandibular reconstruction . Nowadays, the most popular CAS technique is computer‐aided design and manufacturing (CAD/CAM).…”

Section: Introductionmentioning

confidence: 99%

“…In this method, a virtual surgery plan (VSP) is developed, and then patient‐specific osteotomy guides are manufactured according to the VSP. Using the guides, the surgeon can harvest the FFF with predefined shape and dimensions . Whereas some studies demonstrated that use of the guides contributed to greater accuracy of the reconstruction procedures and shorter operating time, the influence of this technique on the overall treatment cost is still a matter of debate …”

Section: Introductionmentioning

confidence: 99%

Supporting fibula free flap harvest with augmented reality: A proof‐of‐concept study

et al. 2019

View full text Add to dashboard Cite

Objective: To analyze a novel navigation system utilizing augmented reality (AR) as a supporting method for fibula free flap (FFF) harvest and fabrication.Methods: A total of 126 simulated osteotomies supported with a cutting guide or one of two AR-based intraoperative navigation modules-simple AR (sAR) or navigated AR (nAR)-were carried out on 18 identical models of the fibula (42 osteotomies per method). After fusing postoperative computed tomography scans of the operated fibulas with the virtual surgical plan based on preoperative images, the objective outcomes-angular deviations from the planned osteotomy trajectory ( o ) and deviations of control points marked on the trajectory (mm)-were determined.Results: All analyzed methods provided similar accuracy of assisted osteotomies. The only significant difference referred to angular deviation in the sagittal plane, which was smaller after the cutting guide-assisted procedures than after the application of sAR and nAR (4.1 AE 2.29 vs. 5.08 AE 3.64 degrees, P = 0.031 and 4.1 AE 2.29 vs. 4.97 AE 2.91, P = 0.002, respectively). Mean deviation of control points after the cutting guide-assisted procedures was 2.76 AE 1.06 mm, as compared with 2.67 AE 1.09 mm for sAR and 2.95 AE 1.11 mm for nAR.Conclusion: Our study demonstrated that both novel AR-based methods provided similar accuracy of assisted harvesting and contouring of the FFF as the cutting guides. This fact, as well as the acceptability of the concept by clinicians, justify their further development and evaluation in preclinical settings.

show abstract

Validation of a fibula graft cutting guide for mandibular reconstruction: experiment with rapid prototyping mandible model

Cited by 12 publications

References 11 publications

Fibula Graft Cutting Devices: Are 3D-Printed Cutting Guides More Precise than a Universal, Reusable Osteotomy Jig?

Fibula Graft Cutting Devices: Are 3D-Printed Cutting Guides More Precise than a Universal, Reusable Osteotomy Jig?

3D printed bone models in oral and cranio-maxillofacial surgery: a systematic review

Supporting fibula free flap harvest with augmented reality: A proof‐of‐concept study

Contact Info

Product

Resources

About