Issues Critical to the Successful Application of Cryosurgical Ablation of the Prostate

Baust, John G.; Gage, Andrew A.; Klossner, Daniel P.; Clarke, Dominic M.; Miller, Rodney A.; Cohen, Jeffrey K.; Katz, Aaron E.; Polascik, Thomas J.; Clarke, Harry S.; Baust, John M.

doi:10.1177/153303460700600206

Cited by 50 publications

(35 citation statements)

References 91 publications

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“…At pathology, tissue changes from high-temperature ablation have been grossly divided into a central ‘white’ zone of immediately coagulated tissue and a periablational ‘red zone’ of reactive inflammation [28]. Currently, all ablation application algorithms have largely prioritized obtaining the most completely uniform ‘white zone’ in a clinically efficient manner (i.e., ablating the desired target volume in the shortest amount of time) or achieving a specific ablation geometry (i.e., spherical ablation volume) [29,30,31]. However, there is now greater appreciation of the various secondary reactions that occur in the periablational rim exposed to non-lethal hyperthermic injury, with increases in protective heat shock protein expression, microvascular permeability, growth factor production, and reactive oxygen species, reported [32].…”

Section: Discussionmentioning

confidence: 99%

Effect of thermal dose on heat shock protein expression after radio-frequency ablation with and without adjuvant nanoparticle chemotherapies

Moussa

Goldberg

Kumar

et al. 2016

International Journal of Hyperthermia

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Purpose To evaluate the effect of different radiofrequency ablation(RFA) thermal doses on coagulation and heat shock protein(HSP) response with and without adjuvant nanotherapies. Materials and Methods First, Fischer rats were assigned to nine different thermal doses of hepatic RFA(50°C–90°C, 2–20min; n=3/group) or no treatment(n=3). Next, 5 of these RF thermal doses were combined with liposomal-doxorubicin(Lipo-Dox, 1mg IV) in R3230 breast tumors, or no treatment tumors(n=5/group). Finally, RFA/Lipo-Dox was given without and with an HSP70 inhibitor, micellar quercetin(Mic-Qu, 0.3mg IV) for two different RFA doses with similar coagulation but differing periablational HSP70(RFA/Lipo-Dox at 70°Cx5min and 90°Cx2min;single tumors, n=5/group). All animals were sacrificed 24hr post-RFA and gross tissue coagulation and HSP70(maximum rim thickness and % cell positivity) were correlated to thermal dose including cumulative equivalent minutes at 43°C(CEM43°C). Results Incremental increases in thermal dose(CEM43°C) correlated to increasing liver tissue coagulation(R2=0.7), but not with periablational HSP70 expression(R2=0.14). Similarly, increasing thermal dose correlated to increasing R3230 tumor coagulation for RF alone and RFA/Lipo-Dox(R2=0.7 for both). The addition of Lipo-Dox better correlated to increasing HSP70 expression compared to RFA alone(RFA:R2=0.4, RFA/Lipo-Dox:R2=0.7). Finally, addition of Mic-Qu to two thermal doses combined with Lipo-Dox resulted in greater tumor coagulation(p<0.0003) for RFA at 90°Cx2min (i.e. greater baseline HSP70 expression) than an RFA dose that produced similar coagulation but less HSP expression(p<0.0004). Conclusion Adjuvant IV Lipo-Dox increases periablational HSP70 expression in a thermally dependent manner. Such expression can be exploited to produce greater tumor destruction when adding a second adjuvant nano-drug (Mic-Qu) to suppress periablational HSP expression.

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Section: Discussionmentioning

confidence: 99%

Effect of thermal dose on heat shock protein expression after radio-frequency ablation with and without adjuvant nanoparticle chemotherapies

Moussa

Goldberg

Kumar

et al. 2016

International Journal of Hyperthermia

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“…The results were compared to a control case in which the electric field was calculated for a constant physiological temperature, 310.15 K. The initial temperature was assumed to be the physiological temperature, 310.15 K. At the onset of freezing, a temperature of 268.15 K was imposed on one surface (the left hand side outer surface in the slab like configuration, Figure 1a, and the central cryoprobe in the cylindrical configuration, Figure 1b). The right hand side of the slab and the outer edge of the cylinder were kept at physiological body temperature, 310.15 K. A temperature of 268.15 K (−5°C) was implemented because in very conservative estimates cell survival occurs at temperatures above 258.15 K in cryosurgery [2], [3], [9], [10]. Therefore, this thermal condition represents the outer margin of a frozen cryosurgical lesion where cells survive freezing [2], [3]; which is a range of temperatures where phenomena related to the Cryo/PEF concept occur.…”

Section: Methodsmentioning

confidence: 99%

“…These limitations are related to the mechanism of cell death by freezing and the incomplete cell death in certain ranges of subfreezing temperatures [2], [3], [8], [9], [10]. A recent review [3] points out that: “The tissue temperature is a key factor in causing injury… As a guide for the treatment of neoplasms, the many experiments suggesting that about −20°C is adequate for tissue destruction should be viewed with caution.…”

Section: Introductionmentioning

confidence: 99%

“…Indeed the same review [3] suggests that: “The greatest opportunity for improved efficacy (of cryosurgery) is in the management of the periphery of the cryogenic lesion where cell destruction is partial. Therapy adjunctive to cryosurgery, such as chemical agents, cytotoxic drugs, or irradiation should prove helpful in completing destruction of cells in the periphery of the frozen volume.” Cryoadjunctive strategies to enhance cancer cell sensitivity to freezing is the subject of several investigations [3], [8], [9], [11], [12], [13]. The goal of this study is to explore, with a mathematical model, the feasibility of using pulsed electric fields delivered through the cryosurgical probe during cryosurgery as a cryoadjunctive modality to ablate cells in the temperature range in which they survive freezing.…”

Section: Introductionmentioning

confidence: 99%

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Cryosurgery with Pulsed Electric Fields

Daniels

Rubinsky

2011

PLoS ONE

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This study explores the hypothesis that combining the minimally invasive surgical techniques of cryosurgery and pulsed electric fields will eliminate some of the major disadvantages of these techniques while retaining their advantages. Cryosurgery, tissue ablation by freezing, is a well-established minimally invasive surgical technique. One disadvantage of cryosurgery concerns the mechanism of cell death; cells at high subzero temperature on the outer rim of the frozen lesion can survive. Pulsed electric fields (PEF) are another minimally invasive surgical technique in which high strength and very rapid electric pulses are delivered across cells to permeabilize the cell membrane for applications such as gene delivery, electrochemotherapy and irreversible electroporation. The very short time scale of the electric pulses is disadvantageous because it does not facilitate real time control over the procedure. We hypothesize that applying the electric pulses during the cryosurgical procedure in such a way that the electric field vector is parallel to the heat flux vector will have the effect of confining the electric fields to the frozen/cold region of tissue, thereby ablating the cells that survive freezing while facilitating controlled use of the PEF in the cold confined region. A finite element analysis of the electric field and heat conduction equations during simultaneous tissue treatment with cryosurgery and PEF (cryosurgery/PEF) was used to study the effect of tissue freezing on electric fields. The study yielded motivating results. Because of decreased electrical conductivity in the frozen/cooled tissue, it experienced temperature induced magnified electric fields in comparison to PEF delivered to the unfrozen tissue control. This suggests that freezing/cooling confines and magnifies the electric fields to those regions; a targeting capability unattainable in traditional PEF. This analysis shows how temperature induced magnified and focused PEFs could be used to ablate cells in the high subzero freezing region of a cryosurgical lesion.

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“…135 / 021002-1 Copyright V C 2013 by ASME temperatures. Estimates of these threshold temperatures can range from À20C to À40 C [10,11] and new preconditioning techniques utilizing adjuvants have demonstrated the potential to raise this limit up to as high as 0 C [12,13]. While biological freeze destruction is an important area of research, there are multiple mechanisms at the cellular, vascular, and even immunological level that contribute, putting this topic beyond the scope of this current work.…”

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confidence: 90%

Methods for Characterizing Convective Cryoprobe Heat Transfer in Ultrasound Gel Phantoms

Etheridge

Choi

Ramadhyani³

et al. 2013

Journal of Biomechanical Engineering

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While cryosurgery has proven capable in treating of a variety of conditions, it has met with some resistance among physicians, in part due to shortcomings in the ability to predict treatment outcomes. Here we attempt to address several key issues related to predictive modeling by demonstrating methods for accurately characterizing heat transfer from cryoprobes, report temperature dependent thermal properties for ultrasound gel (a convenient tissue phantom) down to cryogenic temperatures, and demonstrate the ability of convective exchange heat transfer boundary conditions to accurately describe freezing in the case of single and multiple interacting cryoprobe(s). Temperature dependent changes in the specific heat and thermal conductivity for ultrasound gel are reported down to À150 C for the first time here and these data were used to accurately describe freezing in ultrasound gel in subsequent modeling. Freezing around a single and two interacting cryoprobe(s) was characterized in the ultrasound gel phantom by mapping the temperature in and around the "iceball" with carefully placed thermocouple arrays. These experimental data were fit with finite-element modeling in COMSOL Multiphysics, which was used to investigate the sensitivity and effectiveness of convective boundary conditions in describing heat transfer from the cryoprobes. Heat transfer at the probe tip was described in terms of a convective coefficient and the cryogen temperature. While model accuracy depended strongly on spatial (i.e., along the exchange surface) variation in the convective coefficient, it was much less sensitive to spatial and transient variations in the cryogen temperature parameter. The optimized fit, convective exchange conditions for the single-probe case also provided close agreement with the experimental data for the case of two interacting cryoprobes, suggesting that this basic characterization and modeling approach can be extended to accurately describe more complicated, multiprobe freezing geometries. Accurately characterizing cryoprobe behavior in phantoms requires detailed knowledge of the freezing medium's properties throughout the range of expected temperatures and an appropriate description of the heat transfer across the probe's exchange surfaces. Here we demonstrate that convective exchange boundary conditions provide an accurate and versatile description of heat transfer from cryoprobes, offering potential advantages over the traditional constant surface heat flux and constant surface temperature descriptions. In addition, although this study was conducted on Joule-Thomson type cryoprobes, the general methodologies should extend to any probe that is based on convective exchange with a cryogenic fluid. [DOI: 10.1115/1.4023237] Keywords: cryosurgery, cryotherapy, cryoablation, thermal properties, heat transfer modeling, clinical modeling IntroductionCryosurgery is a minimally invasive technique in which freezing temperatures are used to destroy tissue in the body to treat various conditions, including cancer (prosta...

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Issues Critical to the Successful Application of Cryosurgical Ablation of the Prostate

Cited by 50 publications

References 91 publications

Effect of thermal dose on heat shock protein expression after radio-frequency ablation with and without adjuvant nanoparticle chemotherapies

Effect of thermal dose on heat shock protein expression after radio-frequency ablation with and without adjuvant nanoparticle chemotherapies

Cryosurgery with Pulsed Electric Fields

Methods for Characterizing Convective Cryoprobe Heat Transfer in Ultrasound Gel Phantoms

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