Tissue surface information for intraoperative incision planning and focus adjustment in laser surgery

Andreas Schoob¹, Dennis Kundrat, Lukas Kleingrothe, Lüder A Kahrs, Nicolas Andreff, Tobias Ortmaier

Affiliations

PMID: 24875655
DOI: 10.1007/s11548-014-1077-x

Tissue surface information for intraoperative incision planning and focus adjustment in laser surgery

Andreas Schoob et al. Int J Comput Assist Radiol Surg. 2015 Feb.

. 2015 Feb;10(2):171-81.

doi: 10.1007/s11548-014-1077-x. Epub 2014 May 30.

Authors

Andreas Schoob¹, Dennis Kundrat, Lukas Kleingrothe, Lüder A Kahrs, Nicolas Andreff, Tobias Ortmaier

Affiliation

¹ Institute of Mechatronic Systems, Leibniz Universität Hannover, 30167 , Hanover, Germany, andreas.schoob@imes.uni-hannover.de.

PMID: 24875655
DOI: 10.1007/s11548-014-1077-x

Abstract

Purpose: Introducing computational methods to laser surgery are an emerging field. Focusing on endoscopic laser interventions, a novel approach is presented to enhance intraoperative incision planning and laser focusing by means of tissue surface information obtained by stereoscopic vision.

Methods: Tissue surface is estimated with stereo-based methods using nonparametric image transforms. Subsequently, laser-to-camera registration is obtained by ablating a pattern on tissue substitutes and performing a principle component analysis for precise laser axis estimation. Furthermore, a virtual laser view is computed utilizing trifocal transfer. Depth-based laser focus adaptation is integrated into a custom experimental laser setup in order to achieve optimal ablation morphology. Experimental validation is conducted on tissue substitutes and ex vivo animal tissue.

Results: Laser-to-camera registration gives an error between planning and ablation of less than 0.2 mm. As a result, the laser workspace can accurately be highlighted within the live views and incision planning can directly be performed. Experiments related to laser focus adaptation demonstrate that ablation geometry can be kept almost uniform within a depth range of 7.9 mm, whereas cutting quality significantly decreases when the laser is defocused.

Conclusions: An automatic laser focus adjustment on tissue surfaces based on stereoscopic scene information is feasible and has the potential to become an effective methodology for optimal ablation. Laser-to-camera registration facilitates advanced surgical planning for prospective user interfaces and augmented reality extensions.

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Mattos LS, Acemoglu A, Geraldes A, Laborai A, Schoob A, Tamadazte B, Davies B, Wacogne B, Pieralli C, Barbalata C, Caldwell DG, Kundrat D, Pardo D, Grant E, Mora F, Barresi G, Peretti G, Ortiz J, Rabenorosoa K, Tavernier L, Pazart L, Fichera L, Guastini L, Kahrs LA, Rakotondrabe M, Andreff N, Deshpande N, Gaiffe O, Renevier R, Moccia S, Lescano S, Ortmaier T, Penza V. Mattos LS, et al. Front Robot AI. 2021 Sep 8;8:664655. doi: 10.3389/frobt.2021.664655. eCollection 2021. Front Robot AI. 2021. PMID: 34568434 Free PMC article. Review.

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Tissue surface information for intraoperative incision planning and focus adjustment in laser surgery

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Tissue surface information for intraoperative incision planning and focus adjustment in laser surgery

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Abstract

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