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

PurposeIntroducing 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.MethodsTissue 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.ResultsLaser-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.ConclusionsAn 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.

[1]  Carlos Suárez,et al.  Transoral Microsurgery for Treatment of Laryngeal and Pharyngeal Cancers , 2013, Current Oncology Reports.

[2]  Jerry L. Prince,et al.  Generalized gradient vector flow external forces for active contours , 1998, Signal Process..

[3]  Guang-Zhong Yang,et al.  Real-Time Stereo Reconstruction in Robotically Assisted Minimally Invasive Surgery , 2010, MICCAI.

[4]  A. Freemont,et al.  An in vitro comparison of the erbium: YAG laser and the carbon dioxide laser in laryngeal surgery , 1993, The Journal of Laryngology & Otology.

[5]  M. Strong,et al.  Laser excision of carcinoma of the larynx , 1975, The Laryngoscope.

[6]  Roberto Manduchi,et al.  Bilateral filtering for gray and color images , 1998, Sixth International Conference on Computer Vision (IEEE Cat. No.98CH36271).

[7]  Florent Brunet,et al.  Feature-Driven Direct Non-Rigid Image Registration , 2010, International Journal of Computer Vision.

[8]  J. Tukey,et al.  Variations of Box Plots , 1978 .

[9]  S. Nedevschi,et al.  Optimizing the Census Transform on CUDA enabled GPUs , 2012, 2012 IEEE 8th International Conference on Intelligent Computer Communication and Processing.

[10]  Milind Rajadhyaksha,et al.  Endoscopic laser scalpel for head and neck cancer surgery , 2012, Photonics West - Biomedical Optics.

[11]  T J Flotte,et al.  Er:YAG laser ablation of tissue: Effect of pulse duration and tissue type on thermal damage , 1989, Lasers in surgery and medicine.

[12]  Nikhil Deshpande,et al.  A novel computerized surgeon–machine interface for robot‐assisted laser phonomicrosurgery , 2014, The Laryngoscope.

[13]  Heinz Wörn,et al.  Planning and simulation of microsurgical laser bone ablation , 2010, International Journal of Computer Assisted Radiology and Surgery.

[14]  Ken Masamune,et al.  A Coaxial Laser Endoscope with Arbitrary Spots in Endoscopic View for Fetal Surgery , 2009, MICCAI.

[15]  M. Remacle,et al.  Reliability and efficacy of a new CO2 laser hollow fiber: a prospective study of 39 patients , 2012, European Archives of Oto-Rhino-Laryngology.

[16]  Petra Ambrosch,et al.  Endoscopic Laser Surgery of the Upper Aerodigestive Tract: With Special Emphasis on Cancer Surgery , 2000 .

[17]  P. Nicolai,et al.  Function preservation using transoral laser surgery for T2–T3 glottic cancer: oncologic, vocal, and swallowing outcomes , 2013, European Archives of Oto-Rhino-Laryngology.

[18]  L Reinisch,et al.  Bone ablation with Er:YAG and CO2 laser: Study of thermal and acoustic effects , 1992, Lasers in surgery and medicine.

[19]  M. Strong,et al.  Laryngeal carcinoma: transoral treatment utilizing the CO2 laser. , 1978, American journal of surgery.

[20]  Sebastian Bodenstedt,et al.  Dense GPU-enhanced surface reconstruction from stereo endoscopic images for intraoperative registration. , 2012, Medical physics.

[21]  A. Naganawa,et al.  Laser distance measurement using a newly developed composite-type optical fiberscope for fetoscopic laser surgery , 2010 .

[22]  R. Anderson,et al.  Pulsed CO2 laser tissue ablation: Effect of tissue type and pulse duration on thermal damage , 1988, Lasers in surgery and medicine.

[23]  Zhengyou Zhang,et al.  A Flexible New Technique for Camera Calibration , 2000, IEEE Trans. Pattern Anal. Mach. Intell..

[24]  Danail Stoyanov,et al.  Real-Time Dense Stereo Reconstruction Using Convex Optimisation with a Cost-Volume for Image-Guided Robotic Surgery , 2013, MICCAI.

[25]  N. Andreff,et al.  Preliminary variation on multiview geometry for vision-guided laser surgery. , 2013 .

[26]  Morgan Quigley,et al.  ROS: an open-source Robot Operating System , 2009, ICRA 2009.

[27]  Gregory D. Hager,et al.  Stereo-Based Endoscopic Tracking of Cardiac Surface Deformation , 2004, MICCAI.

[28]  T. Ortmaier,et al.  Online measurement and evaluation of the Er:YAG laser ablation process using an integrated OCT system , 2012 .

[29]  Marc Rubinstein,et al.  Transoral laser microsurgery for laryngeal cancer: A primer and review of laser dosimetry , 2010, Lasers in Medical Science.

[30]  Chao Liu,et al.  Three-dimensional Motion Tracking for Beating Heart Surgery Using a Thin-plate Spline Deformable Model , 2010, Int. J. Robotics Res..

[31]  Ralf Schneider,et al.  Connected component labeling on a 2D grid using CUDA , 2011, J. Parallel Distributed Comput..

[32]  R. Hayden,et al.  Transoral laser microsurgery for advanced laryngeal cancer. , 2007, Archives of otolaryngology--head & neck surgery.

[33]  M. Ptok,et al.  Erbium:YAG-Laserchirurgie an Stimmlippengewebe , 2006, HNO.

[34]  G. Jako Laser surgery of the vocal cords An experimental study with carbon dioxide lasers on dogs , 1972, The Laryngoscope.

[35]  Tobias Ortmaier,et al.  Stereoscopic Surface Reconstruction in Minimally Invasive Surgery using Efficient Non-Parametric Image Transforms , 2013 .

[36]  Arne Böttcher,et al.  Use of a microsecond Er:YAG laser in laryngeal surgery reduces collateral thermal injury in comparison to superpulsed CO2 laser , 2014, European Archives of Oto-Rhino-Laryngology.