S Manimaran1. 1. Division of Physics, School of Science and Humanities, Vellore Institute of Technology, VIT University, Vellore 632 014, Tamil Nadu, India. manimaranq@hotmail.com
Abstract
PURPOSE: The aim of this study was to compare the biological equivalent of low-dose-rate (LDR) and high-dose-rate (HDR) brachytherapy in terms of the more recent linear quadratic (LQ) model, which leads to theoretical estimation of biological equivalence. MATERIALS AND METHODS: One of the key features of the LQ model is that it allows a more systematic radiobiological comparison between different types of treatment because the main parameters alpha/beta and micro are tissue-specific. Such comparisons also allow assessment of the likely change in the therapeutic ratio when switching between LDR and HDR treatments. The main application of LQ methodology, which focuses on by increasing the availability of remote afterloading units, has been to design fractionated HDR treatments that can replace existing LDR techniques. RESULTS: In this study, with LDR treatments (39 Gy in 48 h) equivalent to 11 fractions of HDR irradiation at the experimental level, there are increasing reports of reproducible animal models that may be used to investigate the biological basis of brachytherapy and to help confirm theoretical predictions. This is a timely development owing to the nonavailability of sufficient retrospective patient data analysis. CONCLUSIONS: It appears that HDR brachytherapy is likely to be a viable alternative to LDR only if it is delivered without a prohibitively large number of fractions (e.g., fewer than 11). With increased scientific understanding and technological capability, the prospect of a dose equivalent to HDR brachytherapy will allow greater utilization of the concepts discussed in this article.
PURPOSE: The aim of this study was to compare the biological equivalent of low-dose-rate (LDR) and high-dose-rate (HDR) brachytherapy in terms of the more recent linear quadratic (LQ) model, which leads to theoretical estimation of biological equivalence. MATERIALS AND METHODS: One of the key features of the LQ model is that it allows a more systematic radiobiological comparison between different types of treatment because the main parameters alpha/beta and micro are tissue-specific. Such comparisons also allow assessment of the likely change in the therapeutic ratio when switching between LDR and HDR treatments. The main application of LQ methodology, which focuses on by increasing the availability of remote afterloading units, has been to design fractionated HDR treatments that can replace existing LDR techniques. RESULTS: In this study, with LDR treatments (39 Gy in 48 h) equivalent to 11 fractions of HDR irradiation at the experimental level, there are increasing reports of reproducible animal models that may be used to investigate the biological basis of brachytherapy and to help confirm theoretical predictions. This is a timely development owing to the nonavailability of sufficient retrospective patient data analysis. CONCLUSIONS: It appears that HDR brachytherapy is likely to be a viable alternative to LDR only if it is delivered without a prohibitively large number of fractions (e.g., fewer than 11). With increased scientific understanding and technological capability, the prospect of a dose equivalent to HDR brachytherapy will allow greater utilization of the concepts discussed in this article.
Authors: J A Stitt; J F Fowler; B R Thomadsen; D A Buchler; B P Paliwal; T J Kinsella Journal: Int J Radiat Oncol Biol Phys Date: 1992 Impact factor: 7.038
Authors: Rosa Ballester-Sánchez; Olga Pons-Llanas; Cristian Candela-Juan; Blanca de Unamuno-Bustos; Francisco Javier Celada-Alvarez; Alejandro Tormo-Mico; Jose Perez-Calatayud; Rafael Botella-Estrada Journal: J Contemp Brachytherapy Date: 2017-06-05
Authors: Daniel W Kim; Ivan M Buzurovic; Brandon V Mahal; William Hwang; Oluwadamilola T Oladeru; Desmond A O'Farrell; Thomas C Harris; Danielle N Margalit; Miranda Lam; Phillip M Devlin Journal: J Contemp Brachytherapy Date: 2020-02-28