Nanoparticle Enhanced Radiation Therapy : Principles, Methods and Applications
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| Autore: |
Sajo Erno
|
| Titolo: |
Nanoparticle Enhanced Radiation Therapy : Principles, Methods and Applications
|
| Pubblicazione: | Bristol : , : Institute of Physics Publishing, , 2021 |
| ©2020 | |
| Edizione: | 1st ed. |
| Descrizione fisica: | 1 online resource (320 pages) |
| Altri autori: |
ZygmanskiPiotr
CifterFulya
ZhengYi
SancheLeon
EmfietzoglouDimitris
IncertiSebastien
KirkbyCharles
KoegerBrandon
BrivioDavide
|
| Nota di contenuto: | Intro -- Editor biographies -- Erno Sajo -- Piotr Zygmanski -- Contributors -- Introduction -- Outline placeholder -- Rationale of nanoparticle-enhanced radiotherapy -- The organization of this book -- References -- Chapter 1 The role of Auger electrons versus photoelectrons in nanoparticle dose enhancement -- 1.1 Fundamentals of the Auger process -- 1.2 The role of fluorescent photons -- 1.3 The contribution of Auger electrons and photoelectrons to dose -- 1.4 Angular anisotropy of electron emission from the GNP -- 1.5 Conclusions -- References -- Chapter 2 Deterministic computation benchmarks of nanoparticle dose enhancement-part I. Nanometer scales -- 2.1 Perspectives -- 2.2 The radiation transport basis of high-Z nanoparticle dose enhancement by x-rays -- 2.3 Deterministic radiation transport computations -- 2.4 The Green's function of dose enhancement -- 2.5 Maximum and spatially averaged dose enhancement ratios -- 2.6 The optimal incident photon energy -- 2.7 Discussion -- 2.8 Conclusions -- 2.9 Appendix -- References -- Chapter 3 Deterministic computation benchmarks of nanoparticle dose enhancement-part II. Microscopic to macroscopic scales -- 3.1 The effect of concentration distributions -- 3.2 Radiation transport computations -- 3.2.1 Case-1 geometries -- 3.2.2 Case-2 geometries -- 3.3 Macroscopic DER effects in case-1 geometries -- 3.3.1 Dependence on concentration in a fixed tumor volume -- 3.3.2 Depth and volume dependence for diffusion in one direction -- 3.3.3 Depth and volume dependence for diffusion in two directions -- 3.3.4 Kerma approximation of dose -- 3.3.5 The effective distance of dose enhancement -- 3.4 Microscopic effects in case-2 geometries-the inadequacy of spatial homogenization -- 3.5 Discussion -- 3.6 Conclusions -- References. |
| Chapter 4 Mechanisms of low energy electron interactions with biomolecules: relationship to gold nanoparticle radiosensitization -- 4.1 Introduction -- 4.1.1 Gold nanoparticle (GNP) radiosensitization -- 4.1.2 Primary mechanisms -- 4.1.3 Biological damage induced by low energy electrons (LEEs) -- 4.2 Interaction of LEEs with condensed-phase biomolecules -- 4.2.1 Basic principles of interaction of LEEs with molecules -- 4.2.2 Transient molecular anions (TMAs) and their decay channels -- 4.2.3 Modification of electron capture and decay of transient anions in biological media -- 4.2.4 Short range and high damage efficiency of LEEs -- 4.3 Interaction of LEEs with water and DNA -- 4.3.1 LEE interaction with water and the indirect effect of radiation -- 4.3.2 Mechanisms of LEE-induced DNA and cellular damage -- 4.3.3 DNA damage from GNP-generated LEEs and LEE-bombarded GNP-DNA complexes -- 4.4 Conclusions and future trends -- 4.5 Abbreviations -- Acknowledgments -- References -- Chapter 5 Monte Carlo models of electron transport for dose-enhancement calculations in nanoparticle-aided radiotherapy -- 5.1 Introduction -- 5.2 The challenge -- 5.3 Monte Carlo simulation of electron transport -- 5.4 Condensed-history models (class I code) -- 5.5 Mixed condensed-history models (class II codes) -- 5.6 The case of PENELOPE and Geant4 -- 5.7 Role of condensed-history simulation in NRT -- 5.8 Track-structure models -- 5.9 Track-structure models for water -- 5.10 Track-structure codes for non-aqueous media -- 5.11 The case of TRAX and Geant4-DNA -- 5.12 Surface effects -- 5.13 Role of TS models in NRT -- 5.14 Monte Carlo codes in NRT -- References -- Chapter 6 Nanoparticle-aided radiation therapy: challenges of treatment planning -- 6.1 Introduction -- 6.2 Nature of energy absorption near high-Z NPs -- 6.3 Uptake and dispersion prediction of NPs. | |
| 6.4 Nanoparticle distribution within tissues and organs -- 6.5 Determination of NP concentrations on the macroscopic scale -- 6.6 Cellular internalization -- 6.7 Dosimetry in the presence of NPs -- 6.8 NPRT dosimetry on the macroscopic scale -- 6.9 NPRT dosimetry on the microscopic scale -- 6.10 Challenges to modelling biological response -- 6.11 Further evidence for an NP-induced biological effect -- 6.12 Conclusions and a look forward -- References -- Chapter 7 Nanoparticle enhanced radiotherapy: quality assurance perspective -- 7.1 General -- 7.2 Imaging and verification of NP distribution -- 7.3 Macroscopic dose calculation -- 7.4 Radiobiological effect from macroscopic dose enhancement -- 7.5 Microscopic dose calculation -- 7.6 Radiobiological effect from microscopic dose enhancement -- 7.7 Summary -- 7.8 Experimental/computation setup -- 7.9 Benchmark and validation tests and data -- References -- Chapter 8 Optimal nanoparticle concentrations, toxicity and safety and gold nanoparticle design for radiation therapy applications -- 8.1 Introduction -- 8.2 Biomedical applications of gold nanoparticles -- 8.3 Gold nanoparticles are effective, biocompatible tumor-targeting nanocarriers -- 8.4 Gold nanoparticles in radiation therapy -- 8.5 Challenges of GNP radiotherapy -- 8.6 Design considerations for optimal radiosensitization using GNPs -- 8.7 Size and concentration/dose of GNPs -- 8.8 Surface charge and multi-functionalities of GNPs -- 8.9 Toxicity and safety associated with GNP-based radiotherapy -- 8.10 AuRad platform -- 8.11 AuRad Platform targeting tumor vasculature -- 8.12 AuRad platform tumor vasculature disruption -- 8.13 Summary -- References -- Chapter 9 Translational nanomaterials for cancer radiation therapy -- 9.1 Introduction -- 9.1.1 Silica-based nanoparticles -- 9.1.2 Superparamagnetic iron oxide nanoparticles (SPIONs). | |
| 9.1.3 Quantum dots (QDs) -- 9.2 High-Z metals and radiosensitization -- 9.2.1 Platinum nanoparticles -- 9.2.2 Gold nanoparticles -- 9.2.3 Hafnium oxide nanoparticles -- 9.3 Theranostics nanoparticles -- 9.3.1 Gadolinium nanoparticles -- 9.3.2 Bismuth complexes and nanoparticles -- 9.4 Mechanism of action -- 9.5 Bystander effect -- References -- Chapter 10 Gold nanoparticle enhanced radiosensitivity of cells: considerations and contradictions from model systems and basic investigations of cell damaging for radiation therapy -- 10.1 Cell viability upon cell irradiation in the presence of nanoparticles-colony formation assay (CFA) -- 10.2 DNA damage upon cell irradiation in the presence of nanoparticles-super-resolution microscopic analysis of γH2AX foci -- 10.3 Nanoparticle-mediated radio-sensitization of tumor cells independent of nuclear DNA damage -- 10.4 Conclusions -- 10.5 Materials and methods -- 10.5.1 Cell culture, gold nanoparticle incorporation, and specimen irradiation -- 10.5.2 Clonogenic assay (colony forming assay) -- 10.5.3 γH2AX immunostaining -- 10.5.4 Single molecule localization microscopy -- Acknowledgement -- References -- Chapter 11 Super-resolution microscopy of nanogold-labelling -- 11.1 Electron microscopy -- 11.2 Light microscopy and localization microscopy -- Acknowledgments -- References -- Chapter 12 X-ray based nanoparticle imaging -- 12.1 Computed tomography (CT) -- 12.2 Dual- and multi-energy CT (DECT, MECT) -- 12.3 X-ray fluorescence computed tomography (XFCT) -- 12.4 SPECT/PET -- References -- Chapter 13 MRI based nanoparticle imaging -- References -- Chapter 14 Nanoparticle detection using photoacoustic imaging (PAI) -- References -- Chapter 15 Radiotherapy application with in situ dose-painting (RAiD) via inhalation delivery -- 15.1 Introduction -- 15.2 Materials and methods -- 15.3 Results -- 15.4 Discussion. | |
| 15.5 Conclusion -- Acknowledgments -- References -- Chapter 16 High-Z ORAYA therapy for wet AMD and ocular cancers -- 16.1 Introduction -- 16.2 Materials and methods -- 16.3 Results -- 16.4 Discussion -- References -- Chapter 17 Cerium oxide and titanium dioxide -- 17.1 Introduction -- 17.2 CONP mediated ROS scavenging -- 17.3 TONP aided radiation sensitization -- 17.4 Discussion -- References -- Chapter 18 Accelerated Partial Breast Irradiation (APBI) -- 18.1 Methods -- 18.2 Results -- 18.3 Discussion -- 18.4 Conclusion -- References. | |
| Sommario/riassunto: | The central purpose of nanoparticle enhanced radiotherapy (NPRT) is to more precisely control where the radiation dose is to be delivered, desirably with subcellular precision. The contents of this text covers the rationale and fundamental principles of NPRT, optimal nanoparticle size, concentrations and clinical applications. This volume will serve as a resource for researchers, educators and industry. |
| Titolo autorizzato: | Nanoparticle Enhanced Radiation Therapy |
| ISBN: | 0-7503-4115-7 |
| Formato: | Materiale a stampa  |
| Livello bibliografico | Monografia |
| Lingua di pubblicazione: | Inglese |
| Record Nr.: | 9910861038303321 |
| Lo trovi qui: | Univ. Federico II |
| Opac: | Controlla la disponibilità qui |
Serie:
IOP Series in Global Health and Radiation Oncology Series