A review of radiation dosimetry applications using the MCNP Monte Carlo code
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T.D. Solberg
The Monte Carlo code MCNP (Monte Carlo N-Particle) has a significant history dating to the early years of the Manhattan Project. More recently, MCNP has been used successfully to solve many problems in the field of medical physics. In radiotherapy applications MCNP has been used successfully to calculate the bremsstrahlung spectra from medical linear accelerators, for modeling the dose distributions around high dose rate brachytherapy sources, and for evaluating the dosimetric properties of new radioactive sources used in intravascular irradiation for prevention of restenosis following angioplasty. MCNP has also been used for radioimmunotherapy and boron neutron capture therapy applications. It has been used to predict fast neutron activation of shielding and biological materials. One area that holds tremendous clinical promise is that of radiotherapy treatment planning. In diagnostic applications, MCNP has been used to model X-ray computed tomography and positron emission tomography scanners, to compute the dose delivered from CT procedures, and to determine detector characteristics of nuclear medicine devices. MCNP has been used to determine particle fluxes around radiotherapy treatment devices and to perform shielding calculations in radiotherapy treatment rooms. This manuscript is intended to provide to the reader a comprehensive summary of medical physics applications of the MCNP code.
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Articles in the same Issue
- Preface: Nuclear Data for Medical Applications
- Nuclear data for medical applications: an overview
- Overview of nuclear data libraries and online services
- In vivo functional imaging with SPECT and PET
- Dosimetry related to SPECT and PET applications
- Nuclear data relevant to the production and application of diagnostic radionuclide
- Overview of hadron therapy: rationales, present status and future prospects
- Hadrons (protons, neutrons, heavy ions) in radiation therapy: rationale, achievements and expectations
- What accuracy is required and can be achieved in radiation therapy (review of radiobiological and clinical data)
- Fast neutron and proton therapy sources
- Reference dosimetry for fast neutron and proton therapy
- Medium energy neutron and proton nuclear data for therapy
- Therapeutic radionuclides and nuclear data
- Overview of nuclear reaction models used in nuclear data evaluation
- Model calculations and evaluation of nuclear data for medical radioisotope production
- Nuclear reactions in proton, neutron, and photon radiotherapy
- A review of radiation dosimetry applications using the MCNP Monte Carlo code
Articles in the same Issue
- Preface: Nuclear Data for Medical Applications
- Nuclear data for medical applications: an overview
- Overview of nuclear data libraries and online services
- In vivo functional imaging with SPECT and PET
- Dosimetry related to SPECT and PET applications
- Nuclear data relevant to the production and application of diagnostic radionuclide
- Overview of hadron therapy: rationales, present status and future prospects
- Hadrons (protons, neutrons, heavy ions) in radiation therapy: rationale, achievements and expectations
- What accuracy is required and can be achieved in radiation therapy (review of radiobiological and clinical data)
- Fast neutron and proton therapy sources
- Reference dosimetry for fast neutron and proton therapy
- Medium energy neutron and proton nuclear data for therapy
- Therapeutic radionuclides and nuclear data
- Overview of nuclear reaction models used in nuclear data evaluation
- Model calculations and evaluation of nuclear data for medical radioisotope production
- Nuclear reactions in proton, neutron, and photon radiotherapy
- A review of radiation dosimetry applications using the MCNP Monte Carlo code
