Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry

abstract: Rapid development of new technology has significantly disrupted the way radiotherapy is planned and delivered. These processes involve delivering high radiation doses to the target tumor while minimizing dose to the surrounding healthy tissue. However, with rapid implementation of these ne...

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Other Authors: Subramaniam Pushpavanam, Karthik (Author)
Format: Doctoral Thesis
Language:English
Published: 2019
Subjects:
Online Access:http://hdl.handle.net/2286/R.I.53679
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spelling ndltd-asu.edu-item-536792019-05-16T03:01:35Z Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry abstract: Rapid development of new technology has significantly disrupted the way radiotherapy is planned and delivered. These processes involve delivering high radiation doses to the target tumor while minimizing dose to the surrounding healthy tissue. However, with rapid implementation of these new technologies, there is a need for the detection of prescribed ionizing radiation for radioprotection of the patient and quality assurance of the technique employed. Most available clinical sensors are subjected to various limitations including requirement of extensive training, loss of readout with sequential measurements, sensitivity to light and post-irradiation wait time prior to analysis. Considering these disadvantages, there is still a need for a sensor that can be fabricated with ease and still operate effectively in predicting the delivered radiation dose. The dissertation discusses the development of a sensor that changes color upon exposure to therapeutic levels of ionizing radiation used during routine radiotherapy. The underlying principle behind the sensor is based on the formation of gold nanoparticles from its colorless precursor salt solution upon exposure to ionizing radiation. Exposure to ionizing radiation generates free radicals which reduce ionic gold to its zerovalent gold form which further nucleate and mature into nanoparticles. The generation of these nanoparticles render a change in color from colorless to a maroon/pink depending on the intensity of incident ionizing radiation. The shade and the intensity of the color developed is used to quantitatively and qualitatively predict the prescribed radiation dose. The dissertation further describes the applicability of sensor to detect a wide range of ionizing radiation including high energy photons, protons, electrons and emissions from radioactive isotopes while remaining insensitive to non-ionizing radiation. The sensor was further augmented with a capability to differentiate regions that are irradiated and non-irradiated in two dimensions. The dissertation further describes the ability of the sensor to predict dose deposition in all three dimensions. The efficacy of the sensor to predict the prescribed dose delivered to canine patients undergoing radiotherapy was also demonstrated. All these taken together demonstrate the potential of this technology to be translatable to the clinic to ensure patient safety during routine radiotherapy. Dissertation/Thesis Subramaniam Pushpavanam, Karthik (Author) Rege, Kaushal (Advisor) Sapareto, Stephen (Committee member) Nannenga, Brent (Committee member) Green, Matthew (Committee member) Mu, Bin (Committee member) Arizona State University (Publisher) Nanoscience Biomedical engineering Particle physics eng 320 pages Doctoral Dissertation Chemical Engineering 2019 Doctoral Dissertation http://hdl.handle.net/2286/R.I.53679 http://rightsstatements.org/vocab/InC/1.0/ 2019
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic Nanoscience
Biomedical engineering
Particle physics
spellingShingle Nanoscience
Biomedical engineering
Particle physics
Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry
description abstract: Rapid development of new technology has significantly disrupted the way radiotherapy is planned and delivered. These processes involve delivering high radiation doses to the target tumor while minimizing dose to the surrounding healthy tissue. However, with rapid implementation of these new technologies, there is a need for the detection of prescribed ionizing radiation for radioprotection of the patient and quality assurance of the technique employed. Most available clinical sensors are subjected to various limitations including requirement of extensive training, loss of readout with sequential measurements, sensitivity to light and post-irradiation wait time prior to analysis. Considering these disadvantages, there is still a need for a sensor that can be fabricated with ease and still operate effectively in predicting the delivered radiation dose. The dissertation discusses the development of a sensor that changes color upon exposure to therapeutic levels of ionizing radiation used during routine radiotherapy. The underlying principle behind the sensor is based on the formation of gold nanoparticles from its colorless precursor salt solution upon exposure to ionizing radiation. Exposure to ionizing radiation generates free radicals which reduce ionic gold to its zerovalent gold form which further nucleate and mature into nanoparticles. The generation of these nanoparticles render a change in color from colorless to a maroon/pink depending on the intensity of incident ionizing radiation. The shade and the intensity of the color developed is used to quantitatively and qualitatively predict the prescribed radiation dose. The dissertation further describes the applicability of sensor to detect a wide range of ionizing radiation including high energy photons, protons, electrons and emissions from radioactive isotopes while remaining insensitive to non-ionizing radiation. The sensor was further augmented with a capability to differentiate regions that are irradiated and non-irradiated in two dimensions. The dissertation further describes the ability of the sensor to predict dose deposition in all three dimensions. The efficacy of the sensor to predict the prescribed dose delivered to canine patients undergoing radiotherapy was also demonstrated. All these taken together demonstrate the potential of this technology to be translatable to the clinic to ensure patient safety during routine radiotherapy. === Dissertation/Thesis === Doctoral Dissertation Chemical Engineering 2019
author2 Subramaniam Pushpavanam, Karthik (Author)
author_facet Subramaniam Pushpavanam, Karthik (Author)
title Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry
title_short Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry
title_full Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry
title_fullStr Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry
title_full_unstemmed Radiation-induced Nanoparticle Formation as Novel Means of in Vivo / in Vitro Dosimetry
title_sort radiation-induced nanoparticle formation as novel means of in vivo / in vitro dosimetry
publishDate 2019
url http://hdl.handle.net/2286/R.I.53679
_version_ 1719183440226549760