Converting absorbed dose to medium to absorbed dose to water for Monte Carlo based photon beam dose calculations. Export

@article{Siebers2000, abstract = {Current clinical experience in radiation therapy is based upon dose computations that report the absorbed dose to water, even though the patient is not made of water but of many different types of tissue. While Monte Carlo dose calculation algorithms have the potential for higher dose accuracy, they usually transport particles in and compute the absorbed dose to the patient media such as soft tissue, lung or bone. Therefore, for dose calculation algorithm comparisons, or to report dose to water or tissue contained within a bone matrix for example, a method to convert dose to the medium to dose to water is required. This conversion has been developed here by applying Bragg-Gray cavity theory. The dose ratio for 6 and 18 MV photon beams was determined by computing the average stopping power ratio for the primary electron spectrum in the transport media. For soft tissue, the difference between dose to medium and dose to water is approximately 1.0\%, while for cortical bone the dose difference exceeds 10\%. The variation in the dose ratio as a function of depth and position in the field indicates that for photon beams a single correction factor can be used for each particular material throughout the field for a given photon beam energy. The only exception to this would be for the clinically non-relevant dose to air. Pre-computed energy spectra for 60Co to 24 MV are used to compute the dose ratios for these photon beams and to determine an effective energy for evaluation of the dose ratio.}, author = {Siebers, J. V. and Keall, P. J. and Nahum, A. E. and Mohan, R.}, citeulike-article-id = {2990630}, journal = {Phys Med Biol}, keywords = {air, algorithms, and, bone, bones, carlo, cobalt, distribution, dose-response, humans, lung, method, monte, photons, radiation, radioisotopes, radiometry, relationship, tissue, water}, month = {Apr}, number = {4}, pages = {983--995}, posted-at = {2008-07-11 21:11:30}, priority = {2}, title = {{C}onverting absorbed dose to medium to absorbed dose to water for {M}onte {C}arlo based photon beam dose calculations.}, volume = {45}, year = {2000} }

TY - JOUR ID - Siebers2000 L3 - citeulike-article-id:2990630 N2 - Current clinical experience in radiation therapy is based upon dose computations that report the absorbed dose to water, even though the patient is not made of water but of many different types of tissue. While Monte Carlo dose calculation algorithms have the potential for higher dose accuracy, they usually transport particles in and compute the absorbed dose to the patient media such as soft tissue, lung or bone. Therefore, for dose calculation algorithm comparisons, or to report dose to water or tissue contained within a bone matrix for example, a method to convert dose to the medium to dose to water is required. This conversion has been developed here by applying Bragg-Gray cavity theory. The dose ratio for 6 and 18 MV photon beams was determined by computing the average stopping power ratio for the primary electron spectrum in the transport media. For soft tissue, the difference between dose to medium and dose to water is approximately 1.0%, while for cortical bone the dose difference exceeds 10%. The variation in the dose ratio as a function of depth and position in the field indicates that for photon beams a single correction factor can be used for each particular material throughout the field for a given photon beam energy. The only exception to this would be for the clinically non-relevant dose to air. Pre-computed energy spectra for 60Co to 24 MV are used to compute the dose ratios for these photon beams and to determine an effective energy for evaluation of the dose ratio. IS - 4 JF - Phys Med Biol EP - 995 TI - {C}onverting absorbed dose to medium to absorbed dose to water for {M}onte {C}arlo based photon beam dose calculations. VL - 45 SP - 983 KW - air KW - algorithms KW - and KW - bone KW - bones KW - carlo KW - cobalt KW - distribution KW - dose-response KW - humans KW - lung KW - method KW - monte KW - photons KW - radiation KW - radioisotopes KW - radiometry KW - relationship KW - tissue KW - water AU - Siebers, JV AU - Keall, PJ AU - Nahum, AE AU - Mohan, R PY - 2000/Apr// ER -