Browsing by Subject "Photothermal therapy"
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Item Intravascular photoacoustics as a theranostic platform for atherosclerosis(2014-08) Yeager, Douglas Edward; Emelianov, Stanislav Y.; Baker, Aaron; Sessler, Jonathan; Smalling, Richard; Sokolov, KonstantinThe persistence of high global mortality rates directly attributable to cardiovascular disease drives ongoing research into novel approaches for improved diagnosis and treatment of its primary underlying cause, atherosclerosis. Combined intravascular ultrasound and photoacoustic (IVUS/IVPA) imaging is one such modality, actively being developed as a tool for improved characterization of high-risk atherosclerotic plaques. The pathophysiology associated with progression and destabilization of atherosclerotic plaques leads to characteristic changes in arterial morphology and composition. IVUS/IVPA imaging seeks to expand upon the ability of clinically utilized intravascular ultrasound (IVUS) imaging to assess vessel anatomy by adding improved sensitivity to image the underlying cellular and molecular composition through intravascular photoacoustic (IVPA) imaging of either endogenous chromophores (e.g. lipid) or exogenously delivered contrast agents. This dissertation focuses on the expansion of IVUS/IVPA imaging using exogenous contrast agents to enable the detection and subsequent optically-triggered therapy of atherosclerotic plaques. The passive extravasation and aggregation of systemically injected plasmonic gold nanorods absorbing within the near infrared tissue optical window within plaques of atherosclerotic rabbit models is first demonstrated, along with the ability to localize the contrast agents using ex vivo IVUS/IVPA imaging. The motivation for nanoparticle labeling of atherosclerosis is then expanded from that of purely image contrast agents to vehicles for image-guided, dual-modality phototherapy. The integrated IVUS/IVPA imaging catheter is utilized for photothermal delivery with simultaneous IVPA temperature monitoring using the high optical absorption of gold nanorod contrast agents to enable localized heating. Subsequently, the potential role for IVUS/IVPA-guided phototherapy is further expanded through the characterization and in vitro assessment of novel multifunctional theranostic nanoparticles comprised of a gold nanorod core with a degradable, photosensitizer-doped silica shell. Together, the results presented within this dissertation provide a framework for ongoing research into the expansion of IVUS/IVPA imaging as a platform for complimentary diagnosis and local treatment of atherosclerotic plaques using multifunctional theranostic nanoparticle contrast agents.Item Nanoparticle-mediated photothermal therapy of tumors : a comparative study of heating efficiencies for different particle types(2010-05) Pattani, Varun Paresh; Tunnell, James W.; Ren, PengyuCancer is one of the most notorious diseases affecting the human population today with very few effective treatments. Due to the disparate nature of cancers, it is difficult to obtain a treatment that can cure cancer. Thus, there is a large influx of research towards cancer therapies, leading to one of the discovery that cancer cells (tumors) have a low thermotolerance in comparison to normal cells. If the temperature of the cancer cells is increased into the hyperthermia range (~45°C) thermal damage occurs, causing cell death by protein denaturation and membrane disruption. A recent development in this field has been in the photothermal treatment of tumors, which is starting to utilize plasmonic particles to enhance the specificity of the treatment. The plasmonic nanoparticles, specifically gold, can reach the tumor site using passive targeting and when irradiated with a tuned laser will emit heat localized to a small region around the nanoparticle killing the surrounding cancer cells. This process has been shown to reduce tumor size in vivo with gold nanoshells and gold nanorods. However, it has not been shown which particle is better at delivering the heat to the tumor site. Therefore in this study, it will be shown which particle generates the most heat. Solutions of tissue simulating phantom and different concentrations of nanoparticles were irradiated with a laser to measure the increase in temperature. Additionally, simulations were performed using Mie Theory for nanoshells and the Discrete Dipole Approximation for nanorods. Based on the physical parameters of the nanoshells and nanorods used in this experiment, the adjusted absorption cross-section was determined. It was found that nanoshells generated the most amount of heat on a per particle basis, and that it was necessary to have a nanorod concentration of 5.5 times the concentration of nanoshells to generate the same amount of heat as nanoshells. These results were confirmed using Monte Carlo and Finite Difference Modeling of the nanoparticle heating experiments. However, the choice of nanoparticle still depends on the application and the targeting efficiency in vivo.Item Photoacoustic imaging for temperature monitoring and photothermal therapy guidance(2015-08) Dumani Jarquin, Diego Sayed; Emelianov, Stanislav Y.; Aglyamov, Salavat; Cook, JasonCancer is among the leading causes of death in the United States and the world. Using combined ultrasound (US) and photoacoustic (PA) imaging can provide both anatomical and molecular information of cancerous cells for both diagnostic and therapeutic purposes. This thesis is focused on combining these two modalities, in conjunction with nanoparticles, to treat cancerous tumors and monitor the progress of the therapy. Specifically, the work evaluates the use of photoacoustic imaging as a temperature monitoring tool during photothermal therapy. In this study, the mathematical relationship between photoacoustic signal and temperature is presented and validated with a glass tube phantom using gold nanoparticles. Then in vitro and ex vivo studies were performed to validate the effect of photothermal therapy and the monitoring capability of photoacoustic imaging. The results show that photoacoustic imaging can be used to monitor temperature during photothermal therapy. Future directions include in vivo studies of image guided photothermal therapy and survival studies.Item Understanding cell death response to gold nanoparticle-mediated photothermal therapy in 2D and 3D in vitro tumor models for improving cancer therapy(2013-12) Pattani, Varun Paresh; Tunnell, James W.Gold nanoparticles, a class of plasmonic nanoparticle, have increasingly been explored as an imaging and therapeutic agent to treat cancer due to their characteristic surface plasmon resonance phenomenon and penchant for tumor accumulation. Photothermal therapy has been shown as a promising cancer treatment by delivering heat specifically to the tumor site via gold nanoparticles. In this study, we demonstrate that gold nanorod (GNR)-mediated photothermal therapy can be more effective through the understanding of cell death mechanisms. By targeting GNRs to various cellular localizations, we explored the association of GNR localization with cell death pathway response to photothermal therapy. Furthermore, we compared the 2D monolayer experiments with 3D in vitro tumor models, multicellular tumor spheroids (MCTS), to mimic the structure of in vivo tumors. With MCTS, we evaluated the cell death response with GNRs distributed only on the periphery, as seen in typical in vivo studies, and distributed evenly throughout the tumor. We demonstrated that GNR localization influences the cell death response to photothermal therapy by showing the power threshold necessary to induce significant apoptotic and necrotic increases was lower for internalized GNRs than membrane-bound GNRs. Furthermore, apoptosis was found to increase with increasing laser power until the necrotic threshold and decreased above it, as necrosis became the dominant cell death pathway response. A similar trend was revealed with the 3D MCTS; however, the overall cell death percentages were lower, most likely due to the upregulated cell repair response and varied GNR distributions due to the presence of cell-cell and cell-matrix interactions. Furthermore, the uniformly distributed GNRs induced more apoptosis and necrosis than GNRs located in the MCTS periphery. In conclusion, we quantitatively analyzed the cell death pathway response to GNR-mediated photothermal therapy to establish that it has some dependence on GNR localization and distribution to gain a more thorough understanding of this response for photothermal therapy optimization.