Computer-assisted stereotaxic laser resection of intra-axial brain neoplasms

Abstract. We present the design and a prototype implementation of a three-dimensional visualization system to assist with laparoscopic surgical procedures. The system uses 3D visualization, depth extraction from laparoscopic images, and six degree-of-freedom head and laparoscope tracking to display a merged real and synthetic image in the surgeon's video-see-through head-mounted display. We also introduce a custom design for this display. A digital light projector, a camera, and a conventional laparoscope create a prototype 3D laparoscope that can extract depth and video imagery. Such a system can restore the physician's natural point of view and head motion parallax that are used to understand the 3D structure during open surgery. These cues are not available in conventional laparoscopic surgery due to the displacement of the laparoscopic camera from the physician's viewpoint. The system can also display multiple laparoscopic range imaging data sets to widen the effective field of view of the device. These data sets can be displayed in true 3D and registered to the exterior anatomy of the patient. Much work remains to realize a clinically useful system, notably in the acquisition speed, reconstruction, and registration of the 3D imagery.

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“…The first medical application of AR was to neurosurgery [Kelly86]. Similar systems [Lorensen93,Grimson95] have been developed independently.…”

Section: Medical Augmented Reality Systemsmentioning

confidence: 99%

Augmented reality visualization for laparoscopic surgery

Fuchs

Livingston

Raskar

et al. 1998

Lecture Notes in Computer Science

237

153

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“…For planning surgical procedures, such interactive analysis provides a new level of flexibility greater than that previously reported. [33][34][35] The ability to generate detailed 3-D renderings at high speed is essential for the interactive exploration and planning sessions; the surgeon can view different approaches and different relationships of the lesions to vessels and cranial nerves and can use the planning process as an important preview of the surgery. Improvements on the system will facilitate the use of 3-D reconstruction to guide intraoperative navigation, allowing one kind of frameless stereotaxy.…”

mentioning

confidence: 99%

Neurosurgical considerations in supratentorial low-grade gliomas: experience with 175 patients

Nikas

Bello²,

Zamani³

et al. 1998

FOC

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The authors reviewed 175 low-grade hemispheric gliomas surgically treated by one surgeon (P.B.) between 1987 and 1996: 74 astrocytomas (42%), 35 oligodendrogliomas (20%), 52 mixed gliomas (30%), 12 gangliogliomas (7%), and two ependymomas (1%). Patient age ranged from 7.5 to 81.9 years (mean 39.2 years); 84 patients (48%) were males and 91 (52%) females. Postsurgical follow-up review ranged from 0.1 to 225.2 months (mean 36.2 months, median 24.9 months). Either T2-weighted or contrast-enhanced T1-weighted magnetic resonance (MR) images were used to evaluate the percentage of resection achieved and volume of residual disease postoperatively. The majority of patients (55%) had seizures as the presenting symptom, and 45% experienced preoperative symptoms for more than 12 months. Tumor enhancement was present in 21% of cases. In 66% of surgical procedures at least one of the following technical adjuncts was used: monitored local anesthesia, real-time MR imaging, stereotactic guidance with computerized tomography, three dimensional reconstruction, cortical mapping with cortical stimulation, somatosensory or visual evoked potential recording, corticography, or intraoperative ultrasound. Intraoperative MR imaging was used for 40 (22.9%) of the craniotomies and nine (5.14%) biopsies. There were no surgery-related deaths. Complications appeared in 6% of the patients. Progression to a higher-grade tumor occurred in 9.2% of patients within the 3-year follow-up period.

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“…A number of methods have been developed for this purpose but until recently these have involved rigid body registration techniques. Although rigid body techniques have proven clinically useful, there is a body of literature that shows that brain deforms during the procedure [1,2,3]. When this is the case, rigid body transformations are not sufficient to register accurately pre-and intra-operative information.…”

Section: Introductionmentioning

confidence: 99%

Non-rigid Registration of Serial Intra-operative Images for Automatic Brain Shift Estimation

Duay

Sinha

D’Haese

et al. 2003

Biomedical Image Registration

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Measurement of intra-operative brain motion is important to provide boundary conditions to physics-based deformation models that can be used to register pre-and intra-operative information. In this paper we present and test a technique that can be used to measure brain surface motion automatically. This method relies on a tracked laser range scanner (LRS) that can acquire simultaneously a picture and the 3D physical coordinates of objects within its field of view. This reduces the 3D tracking problem to a 2D non-rigid registration problem which we solve with a Mutual Information-based algorithm. Results obtained on images of a phantom and on images acquired intra-operatively that demonstrate the feasibility of the method are presented.

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Computer-assisted stereotaxic laser resection of intra-axial brain neoplasms

Cited by 258 publications

References 26 publications

Augmented reality visualization for laparoscopic surgery

Augmented reality visualization for laparoscopic surgery

Neurosurgical considerations in supratentorial low-grade gliomas: experience with 175 patients

Non-rigid Registration of Serial Intra-operative Images for Automatic Brain Shift Estimation

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