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International Journal of Computer Assisted Radiology and Surgery

Erschienen in:

04.06.2023 | Original Article

Contactless surface registration of featureless anatomy using structured light camera: application to fibula navigation in mandible reconstruction

verfasst von: Lénaïc Cuau, Marie De Boutray, João Cavalcanti Santos, Nabil Zemiti, Philippe Poignet

Erschienen in: International Journal of Computer Assisted Radiology and Surgery | Ausgabe 11/2023

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Abstract

Purpose

Mandibular reconstruction using fibula free flap is a challenging surgical procedure. To assist osteotomies, computer-assisted surgery (CAS) can be used. Nevertheless, precise registration is required and often necessitates anchored markers that disturb the patient and clinical flow. This work proposes a new contactless surface-based method adapted to featureless anatomies such as fibula to achieve a fast, precise, and reproducible registration.

Methods

Preoperatively, a CT-scan of the patient is realized and osteotomies are virtually planned. During surgery, a structured light camera digitizes the fibula. The obtained intraoperative point cloud is coarsely registered with the preoperative model using 3 points defined in the CT-scan and located on the patient’s bone with a laser beam. Then, a fine registration is performed using an ICP algorithm. The registration accuracy was evaluated comparing the position of points engraved in a 3D-printed fibula with their position in the registered model and evaluating resulting osteotomies. Accuracy and execution time were compared to a conventional stylus-based registration method. The work was validated in vivo.

Results

The experiment performed on a 3D-printed model showed that execution time is equivalent to surface-based registration using a stylus, with a better accuracy (mean TRE of 0.9 mm vs 1.3 mm using stylus) and guarantee good osteotomies. The preliminary in vivo study proved the feasibility of the method.

Conclusion

The proposed contactless surface-based registration method using structured light camera gave promising results in terms of accuracy and execution speed and should be useful to implement CAS for mandibular reconstruction.

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Hidalgo DA (1989) Fibula free flap: a new method of mandible reconstruction. Plast Reconstr Surg 84(1):71–79CrossRefPubMed

Blackwell KE, Brown MT, Gonzalez D (1997) Overcoming the learning curve in microvascular head and neck reconstruction. Arch Otolaryngol Head Neck Surg 123(12):1332–1335CrossRefPubMed

Niklas R, Rainer KM, Hagen RN, Josef BFM, Klaus-Dietrich W, Jochen W (2017) Mandible reconstruction with free fibula flaps: outcome of a cost-effective individual planning concept compared with virtual surgical planning. J Cranio-Maxillofac Surg 45(8):1246–1250CrossRef

Fan W, Dai Y, Giordano G (2020) CAOS TKA provides improved functional outcomes compared to conventional TKA. In: CAOS 2020. The 20th annual meeting of the international society for computer assisted orthopaedic surgery, pp 74–69

Shan X-F, Chen H-M, Liang J, Huang J-W, Zhang L, Cai Z-G, Chuanbin G (2016) Surgical navigation-assisted mandibular reconstruction with fibula flaps. Int J Oral Maxillofac Surg 45(4):448–453CrossRefPubMed

Li P, Xuan M, Liao C, Tang W, Wang X, Tian W, Long J (2016) Application of intraoperative navigation for the reconstruction of mandibular defects with microvascular fibular flaps-preliminary clinical experiences. J Craniofac Surg 27(3):751–755

Chao AH, Weimer K, Raczkowsky J, Zhang Y, Kunze M, Cody D, Selber JC, Hanasono MM, Skoracki RJ (2016) Pre-programmed robotic osteotomies for fibula free flap mandible reconstruction: a preclinical investigation: robotic osteotomies of fibula free flaps. Microsurgery 36(3):246–249CrossRefPubMed

Zhu J-H, Deng J, Liu X-J, Wang J, Guo Y-X, Guo C-B (2016) Prospects of robot-assisted mandibular reconstruction with fibula flap: comparison with a computer-assisted navigation system and freehand technique. J Reconstr Microsurg 32(9):661–669CrossRefPubMed

de Boutray M, Cavalcanti Santos J, Bourgeade A, Ohayon M, Chammas P-E, Garrel R, Poignet P, Zemiti N (2022) Fibular registration using surface matching in navigation-guided osteotomies: a proof of concept study on 3d-printed models. Int J Comput Assist Radiol Surg 17(7):1321–1331CrossRefPubMed

10.

Hoffmann J, Westendorff C, Leitner C, Bartz D, Reinert S (2005) Validation of 3d-laser surface registration for image-guided cranio-maxillofacial surgery. J Cranio-Maxillofac Surg 33(1):13–18CrossRef

11.

Sta S, Ogor J, Letissier H, Stindel E, Hamitouche C, Dardenne G (2021) Towards markerless computer assisted surgery: application to total knee arthroplasty. Int J Med Robot Comput Assist Surg 17:e2296CrossRef

12.

Torres PMB, Gonçalves PJS, Martins JMM (2018) Robotic system navigation developed for hip resurfacing prosthesis surgery. In: Husty M, Hofbaur M (eds) New trends in medical and service robots, vol 48. Mechanisms and machine science. Springer, Berlin, pp 173–183CrossRef

13.

Enebuse I, Foo M, Ibrahim BSKK, Ahmed H, Supmak F, Eyobu OS (2021) A comparative review of hand-eye calibration techniques for vision guided robots. IEEE Access 9:113143–113155CrossRef

14.

Kahn S, Haumann D, Willert V (2014) Hand-eye calibration with a depth camera: 2D OR 3D? In: 2014 international conference on computer vision theory and applications (VISAPP), vol 3, pp 481–489

15.

Cuau L (2022) Fast and automatic optical 3D cameras calibration for contactless surface registration in computer assisted surgery. In: 2022 11th conference on new technologies for computer and robot assisted surgery

16.

Yang L, Cao Q, Lin M, Zhang H, Ma Z (2018) Robotic hand-eye calibration with depth camera: a sphere model approach. In: 2018 4th international conference on control, automation and robotics (ICCAR). IEEE, pp 104–110

17.

Zhang Z (1994) Iterative point matching for registration of free-form curves and surfaces. Int J Comput Vis 13(2):119–152CrossRef

18.

Yaniv Z (2015) Which pivot calibration? In Webster RJ, Ziv RY (eds) SPIE medical imaging, p 941527

19.

Qi CR, Su H, Mo K, Guibas LJ (2016) Pointnet: deep learning on point sets for 3d classification and segmentation. CoRR, arxiv:1612.00593

20.

Myronenko A, Song X (2010) Point set registration: coherent point drift. IEEE Trans Pattern Anal Mach Intell 32(12):2262–2275CrossRefPubMed

21.

Segal A, Haehnel D, Thrun S (2009) Generalized-ICP. In: Robotics: science and systems V. Robotics: Science and Systems Foundation

22.

Yang J, Li H, Jia Y (2013) Go-ICP: solving 3d registration efficiently and globally optimally. In: 2013 IEEE international conference on computer vision. IEEE, pp 1457–1464

23.

Pellini R, Mercante G, Spriano G (2012) Step-by-step mandibular reconstruction with free fibula flap modelling. Acta Otorhinolaryngol Ital 32(6):405–409PubMedPubMedCentral

Titel: Contactless surface registration of featureless anatomy using structured light camera: application to fibula navigation in mandible reconstruction
verfasst von: Lénaïc Cuau
Marie De Boutray
João Cavalcanti Santos
Nabil Zemiti
Philippe Poignet
Publikationsdatum: 04.06.2023
Verlag: Springer International Publishing
Erschienen in: International Journal of Computer Assisted Radiology and Surgery / Ausgabe 11/2023
Print ISSN: 1861-6410
Elektronische ISSN: 1861-6429
DOI: https://doi.org/10.1007/s11548-023-02966-3

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Abstract

Purpose

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Conclusion

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