An Investigation of Thermal Mitigation Strategies for Electroporation-Based Therapies

O'Brien, Timothy J.

16 July 2019

Irreversible electroporation (IRE) is an energy directed focal ablation technique. This procedure typically involves the placement of two or more electrodes into, or around, a region of interest within the tissue and administering a sequence of short, intense, pulsed electric fields (PEFs). The application of these PEFs results in an increase in the transmembrane potential of all cells within the electric field above a critical value, destabilizing the lipid bilayer of the cellular membrane and increasing the cell-tissue permeability. For years, many have used this phenomenon to assist the transport of macromolecules typically unable to penetrate the cell membrane with the intent of avoiding cell necrosis or irreversible electroporation. More recently, however, irreversible electroporation has proven to be a successful alternative for the treatment of cancer. Proper tuning of the pulse parameters has allowed for a targeted treatment of localized tumors, and has shown immense value in the treatment of surgically inoperable tumors located near major blood vessels and nerves. While it is critical to ensure sufficient treatment of the target tissue, it can be equally vital to the treatment and patients overall outcome that the pulsing conditions are set to moderate the associated thermal effects with the electroporation of biological tissue. The development of thermal mitigation strategies for IRE treatment is the focus of this dissertation. Herein, the underlying theory and thermal considerations of tissue electroporation in various scenarios are described. Additionally, new thermal mitigation approaches with the intention of maintaining tissue temperature below a thermally damaging threshold, while also preserving or improving IRE lesion volume are detailed. Further, numerical models were developed and ex vivo tissue experiments performed using a perfused organ model to examine three thermal mitigation strategies in their ability to moderate temperature. Tests conducted using thermally mitigating treatment delivery on live tissue confirm the capacity to deliver more energy to the tissue at a thermally acceptable temperature, and provide the potential for a replete IRE lesion. / Doctor of Philosophy / Irreversible electroporation (IRE) is a minimally invasive therapy utilized to treat a variety of cancers. This procedure involves the delivery energy in the form of pulsed electric fields (PEFs) through two or more needle electrodes. These PEFs destabilize the cell membrane, increase the cell-tissue permeability, and ultimately induce cell death for any given cell within the targeted treatment region. Over the years, this treatment modality has shown a great deal of promise in the treatment of unresectable tumors in which the tumor is positioned near or around sensitive regions making the surgical removal of the tumor impossible and thermal ablation techniques limited in their ability to treat without irrevocably damaging the underlying tissue architecture and other critical surrounding structures. Thus, it can be vital to the treatment and patients overall outcome that the IRE therapy is set to moderate any associated thermal effects with the electroporation of biological tissue. However, the design of an electric field that simultaneously maps the entire region of interest for a single treatment and avoids undesirable thermal effects can be challenging when treating larger or irregularly shaped volumes of tissue. Thus, in this dissertation, we demonstrate various treatment delivery methods/ enhancements to reduce temperature rise during IRE therapy. The underlying theory of tissue electroporation and associated thermal considerations are described to provide a foundation and general context. Additionally, novel approaches to tissue electroporation therapy with the intention of maintaining tissue temperature below a thermally damaging threshold throughout treatment are detailed.

Irreversible Electroporation (IRE)

Thermal Mitigation

Thermal mitigation effects of hydroponic rooftop greening in urban areas / 都市域における屋上水耕栽培の熱緩和効果

Tanaka, Yoshikazu

26 March 2018

京都大学 / 0048 / 新制・課程博士 / 博士(農学) / 甲第21155号 / 農博第2281号 / 新制||農||1059(附属図書館) / 学位論文||H30||N5129(農学部図書室) / 京都大学大学院農学研究科地域環境科学専攻 / (主査)教授 川島 茂人, 教授 星野 敏, 教授 藤原 正幸 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DFAM

Green rooftop

Heat balance components

Hydroponic system

Thermal environment

Thermal mitigation

610

Modeling Watershed-Wide Bioretention Stormwater Retrofits to Achieve Thermal Pollution Mitigation Goals

Chen, Helen Yuen

08 April 2020

Stream ecosystems are increasingly at risk for thermal impairment as urbanization intensifies, resulting in more heated runoff from impervious cover that is less likely to be cooled naturally. While several best management practices, including bioretention filters, have been able to reduce thermal pollution, success has been limited. The extent of thermal mitigation required to prevent ecological damage is unknown. A calibrated runoff temperature model of a case study watershed in Blacksburg, VA was developed to determine the cumulative treatment volume of bioretention filters required to reduce thermal impacts caused by runoff from development in the watershed to biologically acceptable levels. A future build out scenario of the study watershed was also analyzed. Results from this study established that runoff thermal pollution cannot be fully reduced to goal thresholds during all storms using bioretention filter retrofits. While retrofitting significantly decreased temperatures and heat exports relative to the controls, increasing treatment volumes did not really enhance mitigation. Alternate thermal mitigation methods which actively remove runoff volume should be considered where more thermal mitigation is required. / Master of Science / Stream temperature is a significant ecological, biological, and chemical property affecting the long-term health of streams. However, as development intensifies, stream ecosystems are increasingly at risk of being damaged by thermal pollution, which causes warmer and less stable temperatures that distress aquatic organisms. While several stormwater management methods that reduce runoff-related pollution, known as best management practices (BMPs), were found to also decrease thermal pollution, their success has been limited. Furthermore, the extent of thermal mitigation required to prevent ecological damage is unclear. This study aimed to determine how much treatment by a popular BMP, the bioretention filter, was necessary across a watershed in Blacksburg, VA to adequately reduce thermal pollution to protect stream health. Mitigation impacts were tested on both existing and predicted future development conditions through model simulations. Results from this study established that thermal pollution from runoff cannot be fully reduced to goal thresholds consistently using bioretention filter retrofits. While retrofitting significantly decreased thermal pollution, increasing treatment volume did not considerably enhance mitigation. Results suggested that bioretention filters are not an effective method, and alternate thermal mitigation practices which actively remove runoff volume should instead be considered where intensive reductions in thermal pollution are necessary.

stormwater management

best management practice (BMP)

bioretention

Temperature

thermal pollution

thermal mitigation

Modeling

MINUHET