Computerized Planning of Cryosurgery Using Cryoprobes and Cryoheaters

Rabin, Yoed; Lung, David C; Stahovich, Thomas F.

doi:10.1177/153303460400300301

Cited by 38 publications

(31 citation statements)

References 15 publications

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“…In fact, due to the typical quality of ultrasound imaging, some surface areas of the organ are interpolated based on imaging data, rather than directly extracted from imaging. Given the quality of agreement between experimental data and numerical simulations presented in the current study, the typical quality of organ reconstruction for cryosurgery applications, and the fact that the defect area concept is the key for computerized planning in parallel studies, it is concluded that the numerical technique presented by Rossi et al (2007) is adequate for the purpose of computerized planning of prostate cryosurgery using the prototype algorithms presented by Lung et al (2004), Rabin et al (2004), and Tanaka et al (2006). An image of a cryoprobe, including two enlarged illustrations displaying the cryoprobe design and functionality.…”

Section: Discussionmentioning

confidence: 99%

“…It follows that uncertainty in estimating the freezing front location in the current study, based on heat transfer simulations, is smaller than the uncertainty in estimating the freezing front location based on ultrasound imaging, in a clinical setup. Furthermore, given the quality of agreement between experimental data and numerical simulations presented in the current study, the typical quality of organ reconstruction for cryosurgery applications, and the fact that the defect area concept is the key for computerized planning in parallel studies , Tanaka et al 2006, it is concluded that the numerical technique presented by Rossi et al (2007) is adequate for the purpose of computerized planning of cryosurgery using the prototype algorithms presented by Lung et al (2004), Rabin et al (2004), andTanaka et al (2006).…”

Section: Defect Values Listed Inmentioning

confidence: 99%

“…Suboptimal cryoprobe localization may leave areas in the target region untreated, may lead to cryoinjury of healthy surrounding tissues, may require an unnecessarily large number of cryoprobes, may increase the duration of the surgical procedure, and may increase the likelihood of post cryosurgery complications, all of which affect the quality and cost of the medical treatment. Computerized planning tools would help to alleviate these difficulties, which is the subject matter of this ongoing research program at the Biothermal Technology Laboratory Rabin et al 2004;Rabin and Stahovich 2003;Rossi et al 2007;Tanaka et al 2006Tanaka et al , 2007.…”

Section: Introductionmentioning

confidence: 99%

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Experimental verification of numerical simulations of cryosurgery with application to computerized planning

Rossi¹,

Rabin²

2007

Phys. Med. Biol.

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As a part of an ongoing effort to develop computerized planning tools for cryosurgery, an experimental study has been conducted to verify a recently developed numerical technique for bioheat transfer simulations. Experiments were performed on gelatin solution as a phantom material, using proprietary liquid-nitrogen cryoprobes. Urethral warming was simulated with the application of a cryoheater, which is a proprietary temperature-controlled electrical heater. The experimental design was aimed at creating a 2D heat-transfer problem. Analysis of experimental results was based on reconstruction of the frozen region from video recordings, using a region-growing segmentation algorithm. Results of this study show an average disagreement of 2.9% in the size of the frozen region, between experimental data and numerical simulation of the same experiment, which validates both the recently developed algorithm for numerical simulations and the newly developed algorithm for segmentation from video recordings.

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Section: Discussionmentioning

confidence: 99%

Section: Defect Values Listed Inmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Experimental verification of numerical simulations of cryosurgery with application to computerized planning

Rossi¹,

Rabin²

2007

Phys. Med. Biol.

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“…Towards this goal, the "force-field" algorithm has been developed [5][6], based on a series of heat transfer simulations and an analogy between the resulting temperature field and forces, which may result in cryoprobes displacement between every two consecutive simulations. A "bubble-packing" algorithm was further developed to identify the most efficient initial condition for the force-field method [7].…”

Section: Automationmentioning

confidence: 99%

“…the objective to provide results useful for understanding and designing the multi-cryoprobe procedure is commendable, critical evaluation of the Magalov et al [3] report must incorporate recent and relevant literature [4][5][6][7][8][9][10][11][12] not cited by these authors. (A few of the publications cited here were published only after [3] in archival journal, but are nonetheless relevant to the current discussion; those subjects have been widely presented in conferences in the past few years.)…”

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confidence: 99%

Key issues in bioheat transfer simulations for the application of cryosurgery planning

Rabin

2008

Cryobiology

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The bioheat transfer simulation is undoubtedly the foundation for developing computerized tools for cryosurgery planning and analysis. While a large variety of techniques for bioheat transfer simulations are available in the literature of the past several decades, it is only their integration with clinical criteria and constraints which can make computerized planning a practical reality. This brief communication outlines (in the opinion of this author) the key issues that must be addressed in the application of bioheat transfer to cryosurgery planning and analysis, while drawing attention to recent and relevant publications in other journals, with reference to the most recent publication on the topic in the Journal of Cryobiology [3]. KeywordsCryosurgery; Simulation; Planning; Bioheat Transfer Dramatic developments in imaging, instrumentation, and computational techniques in recent years have opened new horizons for the application of multi-probe and minimally-invasive cryosurgery. Commercial cryoprobes are now available that are as narrow as 1 mm in diameter, and in a wide range of active lengths. These small diameters, and the variability in active length, can potentially improve the surgeon's control over the minimally-invasive procedure. In prostate cryosurgery for example, up to 14 small diameter cryoprobes are routinely used, where the most appropriate active length can be selected according to the actual dimensions of the particular organ. One negative aspect of using this large number of cryoprobes is the increased complexity of surgical planning: consider the difficulty of visualizing the 3D shape of the organ (i.e., the target region), while seeking an optimal layout for as many as 14 cryoprobes, in order to best match the transient temperature field with the imaged freezing front and criteria for cryosurgery success.It is the opinion of this author that the optimal cryoprobe layout must be obtained with the aid of computerized planning tools, relying upon bioheat transfer simulations of the procedure. While numerical techniques for bioheat transfer are well documented in the literature of the past several decades, only a few studies have systematically addressed the critical problem of the best cryoprobe layout for cryosurgery [1,2]; Magalov et al. [3] is the most recent publication concerning this problem-although in a simplistic setup-in the Journal of Cryobiology. While 1rabin@cmu.edu; Phone/Fax: 412 268 2204. Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers

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