about
Charged state of a spherical plasma in vacuum.Charged particles in radiation oncology.Magnetic resonance imaging for adaptive cobalt tomotherapy: A proposal.Vision 20/20: proton therapy.The physics of proton therapy.Positron emission tomography imaging approaches for external beam radiation therapies: current status and future developmentsRadiobiological description of the LET dependence of the cell survival of oxic and anoxic cells irradiated by carbon ions.Sequential evaluation of hepatic functional reserve by 99mTechnetium-galactosyl human serum albumin scintigraphy after proton beam therapy: a report of three cases and a review of the literatures.Radiotherapy-induced malignancies: review of clinical features, pathobiology, and evolving approaches for mitigating riskA systems biology approach to radiation therapy optimization.Particle therapy for noncancer diseases.Modelling tumour oxygenation, reoxygenation and implications on treatment outcome.Dose or 'LET' painting--What is optimal in particle therapy of hypoxic tumors?Vision 20/20: Positron emission tomography in radiation therapy planning, delivery, and monitoring.Comprehensive track-structure based evaluation of DNA damage by light ions from radiotherapy-relevant energies down to stopping.In vitro and in vivo studies on radiobiological effects of prolonged fraction delivery time in A549 cells.Theoretical implications of incorporating relative biological effectiveness into radiobiological equivalence relationships.Hypoxia imaging with [F-18] FMISO-PET in head and neck cancer: potential for guiding intensity modulated radiation therapy in overcoming hypoxia-induced treatment resistance.A pencil beam algorithm for helium ion beam therapy.Theoretical substantiation of biological efficacy enhancement for β-delayed particle decay (9)C beam: A Monte Carlo study in combination with analysis with the local effect model approach.Can particle beam therapy be improved using helium ions? - a planning study focusing on pediatric patients.Impact of prolonged fraction dose-delivery time modeling intensity-modulated radiation therapy on hepatocellular carcinoma cell killing.Implementation of spot scanning dose optimization and dose calculation for helium ions in Hyperion.Cross-section scaling for track structure simulations of low-energy ions in liquid water.Dose and linear energy transfer distributions of primary and secondary particles in carbon ion radiation therapy: A Monte Carlo simulation study in water.The determination of a dose deposited in reference medium due to (p,n) reaction occurring during proton therapyImproving accuracy of electron density measurement in the presence of metallic implants using orthovoltage computed tomography.Modelling the expected increase in demand for particle radiotherapy: implications for the UK.Monte Carlo simulations of ³He ion physical characteristics in a water phantom and evaluation of radiobiological effectiveness.Phase I Study of Carbon Ion Radiotherapy and Image-Guided Brachytherapy for Locally Advanced Cervical Cancer
P2860
Q33221395-4410A76E-6B23-42D0-8652-0B91379EF06BQ33273594-318B7E8F-2BA9-47D1-B70C-6BE07ABE5664Q34415525-64BA9AB8-4406-432F-98C9-B2ABF9618CBEQ34963839-C002460C-E427-4F83-9FB3-681084C872CCQ35531022-5D20EAFA-4E5F-414A-BEFC-3EAEF74E7991Q36325435-C0E938AC-0413-4194-A804-217A44A41B56Q36500010-2B09B603-E266-42B1-A38C-A2B88AC9569CQ36659857-70A2F2B2-3537-47EC-AF39-43701300E1D1Q36736612-F16A3D67-7435-4D0A-A631-7C06F9BBF428Q37700260-CF748925-8F67-495E-9490-DACA124DCFF5Q38000635-312B1989-ECAC-45CC-A547-E00A01A77C17Q38080844-690A5847-931A-4690-9EE0-390293B1CCADQ38413503-585DF771-9757-4BF3-BD0B-3DF6B7A930E1Q38657514-71E90021-3C8D-4093-AB0C-D89B221D72E8Q38874502-932E70E1-0B5F-4DD1-81C5-AB5D6E36753CQ39254732-D79DF197-9082-47B4-8367-DB105C3B770CQ39294829-DE0DD336-456D-4FE2-A233-54C743B1108BQ39421908-78180D9B-9F2F-4DB3-8713-BA0179FC2782Q39525328-4783D289-BE64-4569-84C6-94CBFA35706EQ39952200-FE7C902C-2A85-460F-BA04-06ED873F942EQ40124111-6AA9EED0-21E3-4F26-8A26-488B1C99AD53Q40446081-4E426170-AEA4-4BE8-B78D-F3133115FE0FQ40585831-6EB5C38B-9AB9-4D22-BC79-CA5F5BB2E8FEQ40944819-422BB3B8-D23D-47CC-BCAD-705A8B4BD50AQ42269127-A795877B-9614-458B-8A35-6D7F4B392E3CQ42291169-8AC98EF0-3C51-4651-B790-E78F48E76FF1Q47629375-92C72BCC-816E-413A-A3F5-6FC1FE145726Q51369631-A309B49F-B016-428F-BC9B-B80EB189EBC0Q51536159-5F41CB90-9C3B-4659-85CF-E1EE58923F49Q58723292-0B29EE93-C106-4E51-B3ED-707F5B20CE51
P2860
description
2004 nî lūn-bûn
@nan
2004年の論文
@ja
2004年論文
@yue
2004年論文
@zh-hant
2004年論文
@zh-hk
2004年論文
@zh-mo
2004年論文
@zh-tw
2004年论文
@wuu
2004年论文
@zh
2004年论文
@zh-cn
name
Recent advances in light ion radiation therapy.
@ast
Recent advances in light ion radiation therapy.
@en
type
label
Recent advances in light ion radiation therapy.
@ast
Recent advances in light ion radiation therapy.
@en
prefLabel
Recent advances in light ion radiation therapy.
@ast
Recent advances in light ion radiation therapy.
@en
P1476
Recent advances in light ion radiation therapy.
@en
P2093
Anders Brahme
P304
P356
10.1016/J.IJROBP.2003.09.034
P407
P577
2004-02-01T00:00:00Z