Your search keyword '"Marissa Nichole Rylander"' showing total 2 results

1. An Experimental and Numerical Investigation of Phase Change Electrodes for Therapeutic Irreversible Electroporation

Author

Marissa Nichole Rylander, Rafael V. Davalos, Christopher B. Arena, and Roop L. Mahajan

Subjects

Phase transition, Materials science, Finite Element Analysis, Temperature, Biomedical Engineering, Reproducibility of Results, chemistry.chemical_element, Gallium, Irreversible electroporation, Plasma, Phase-change material, Electroporation, Thermal conductivity, chemistry, Physiology (medical), Electrode, ELECTROSURGICAL DEVICE, Animals, Electrodes, Biomedical engineering

Abstract

Irreversible electroporation (IRE) is a new technology for ablating aberrant tissue that utilizes pulsed electric fields (PEFs) to kill cells by destabilizing their plasma membrane. When treatments are planned correctly, the pulse parameters and location of the electrodes for delivering the pulses are selected to permit destruction of the target tissue without causing thermal damage to the surrounding structures. This allows for the treatment of surgically inoperable masses that are located near major blood vessels and nerves. In select cases of high-dose IRE, where a large ablation volume is desired without increasing the number of electrode insertions, it can become challenging to design a pulse protocol that is inherently nonthermal. To solve this problem we have developed a new electrosurgical device that requires no external equipment or protocol modifications. The design incorporates a phase change material (PCM) into the electrode core that melts during treatment and absorbs heat out of the surrounding tissue. Here, this idea is reduced to practice by testing hollow electrodes filled with gallium on tissue phantoms and monitoring temperature in real time. Additionally, the experimental data generated are used to validate a numerical model of the heat transfer problem, which is then applied to investigate the cooling performance of other classes of PCMs. The results indicate that metallic PCMs, such as gallium, are better suited than organics or salt hydrates for thermal management, because their comparatively higher thermal conductivity aids in heat dissipation. However, the melting point of the metallic PCM must be properly adjusted to ensure that the phase transition is not completed before the end of treatment. When translated clinically, phase change electrodes have the potential to continue to allow IRE to be performed safely near critical structures, even in high-dose cases.

Published

2013

2. A Two-State Cell Damage Model Under Hyperthermic Conditions: Theory and In Vitro Experiments

Author

Yusheng Feng, Marissa Nichole Rylander, and J. Tinsley Oden

Subjects

Male, Cell Survival, Population, Biomedical Engineering, Thermodynamics, Models, Biological, Article, symbols.namesake, Physiology (medical), Tumor Cells, Cultured, medicine, Humans, Gas constant, Computer Simulation, Viability assay, education, Absolute zero, Cell damage, Physics, Arrhenius equation, education.field_of_study, Prostatic Neoplasms, Hyperthermia, Induced, Function (mathematics), medicine.disease, symbols, Constant (mathematics), Biomedical engineering

Abstract

The ultimate goal of cancer treatment utilizing thermotherapy is to eradicate tumors and minimize damage to surrounding host tissues. To achieve this goal, it is important to develop an accurate cell damage model to characterize the population of cell death under various thermal conditions. The traditional Arrhenius model is often used to characterize the damaged cell population under the assumption that the rate of cell damage is proportional to exp(-EaRT), where Ea is the activation energy, R is the universal gas constant, and T is the absolute temperature. However, this model is unable to capture transition phenomena over the entire hyperthermia and ablation temperature range, particularly during the initial stage of heating. Inspired by classical statistical thermodynamic principles, we propose a general two-state model to characterize the entire cell population with two distinct and measurable subpopulations of cells, in which each cell is in one of the two microstates, viable (live) and damaged (dead), respectively. The resulting cell viability can be expressed as C(tau,T)=exp(-Phi(tau,T)kT)(1+exp(-Phi(tau,T)kT)), where k is a constant. The in vitro cell viability experiments revealed that the function Phi(tau,T) can be defined as a function that is linear in exposure time tau when the temperature T is fixed, and linear as well in terms of the reciprocal of temperature T when the variable tau is held as constant. To determine parameters in the function Phi(tau,T), we use in vitro cell viability data from the experiments conducted with human prostate cancerous (PC3) and normal (RWPE-1) cells exposed to thermotherapeutic protocols to correlate with the proposed cell damage model. Very good agreement between experimental data and the derived damage model is obtained. In addition, the new two-state model has the advantage that is less sensitive and more robust due to its well behaved model parameters.

Published

2008