SOI microdosimetry and modified MKM for evaluation of relative biological effectiveness for a passive proton therapy radiation field.

With more patients receiving external beam radiation therapy with protons, it becomes increasingly important to refine the clinical understanding of the relative biological effectiveness (RBE) for dose delivered during treatment. Treatment planning systems used in clinics typically implement a constant RBE of 1.1 for proton fields irrespective of their highly heterogeneous linear energy transfer (LET). Quality assurance tools that can measure beam characteristics and quantify or be indicative of biological outcomes become necessary in the transition towards more sophisticated RBE weighted treatment planning and for verification of the Monte Carlo and analytical based models they use. In this study the RBE for the CHO-K1 cell line in a passively delivered clinical proton spread out Bragg peak (SOBP) is determined both in vitro and using a silicon-on-insulator (SOI) microdosimetry method paired with the modified microdosimetric kinetic model. The RBE along the central axis of a SOBP with 2 Gy delivered at the middle of the treatment field was found to vary between 1.11-1.98 and the RBE for 10% cell survival between 1.07-1.58 with a 250 kVp x-ray reference radiation and between 1.19-2.34 and 0.95-1.41, respectively, for a Co60 reference. Good agreement was found between RBE values calculated from the SOI-microdosimetry-MKM approach and in vitro. A strong correlation between proton lineal energy and RBE was observed particularly in the distal end and falloff of the SOBP.

MICRODOSIMETRIC MEASUREMENT OF SECONDARY RADIATION IN THE PASSIVE SCATTERED PROTON THERAPY ROOM OF iTHEMBA LABS USING A TISSUE-EQUIVALENT PROPORTIONAL COUNTER.

Measurements of the dose equivalent at different distances from the isocenter of the proton therapy center at iThemba LABS were previously performed with a tissue-equivalent proportional counter (TEPC). These measurements showed that the scattered radiation levels were one or two orders of magnitude higher in comparison to other passive scattering delivery systems. In order to reduce these radiation levels, additional shielding was installed shortly after the measurements were done. Therefore, the aim of this work is to quantify and assess the reduction of the secondary doses delivered in the proton therapy room at iThemba LABS after the installation of the additional shielding. This has been performed by measuring microdosimetric spectra with a TEPC at 11 locations around the isocenter when a clinical modulated beam of 200 MeV proton was impinging onto a water phantom placed at the isocenter.

Radiation Sensitivity of Human CD34(+) Cells Versus Peripheral Blood T Lymphocytes of Newborns and Adults: DNA Repair and Mutagenic Effects.

As hematopoietic stem and progenitor cells (HSPCs) self-renew throughout life, accumulation of genomic alterations can potentially give rise to radiation carcinogenesis. In this study we examined DNA double-strand break (DSB) induction and repair as well as mutagenic effects of ionizing radiation in CD34(+) cells and T lymphocytes from the umbilical cord of newborns. The age dependence of DNA damage repair end points was investigated by comparing newborn T lymphocytes with adult peripheral blood T lymphocytes. As umbilical cord blood (UCB) contains T lymphocytes that are practically all phenotypically immature, we examined the radiation response of separated naive (CD45RA(+)) and memory (CD45RO(+)) T lymphocytes. The number of DNA DSBs was assessed by microscopic scoring of γ-H2AX/53BP1 foci 0.5 h after low-dose radiation exposure, while DNA repair was studied by scoring the number of residual γ-H2AX/53BP1 foci 24 h after exposure. Mutagenic effects were studied by the cytokinesis block micronucleus (CBMN) assay. No significant differences in the number of DNA DSBs induced by low-dose (100-200 mGy) radiation were observed among the three different cell types. However, residual γ-H2AX/53BP1 foci levels 24 h postirradiation were significantly lower in CD34(+) cells compared to newborn T lymphocytes, while newborn T lymphocytes showed significantly higher foci yields than adult T lymphocytes. No significant differences in the level of radiation-induced micronuclei at 2 Gy were observed between CD34(+) cells and newborn T lymphocytes. However, newborn T lymphocytes showed a significantly higher number of micronuclei compared to adult T lymphocytes. These results confirm that CD34(+) cell quiescence promotes mutagenesis after exposure. Furthermore, we can conclude that newborn peripheral T lymphocytes are significantly more radiosensitive than adult peripheral T lymphocytes. Using the results from the comparative study of radiation-induced DNA damage repair end points in naive (CD45RA(+)) and memory (CD45RO(+)) T lymphocytes, we could demonstrate that the observed differences between newborn and adult T lymphocytes can be explained by the immunophenotypic change of T lymphocytes with age, which is presumably linked with the remodeling of the closed chromatin structure of naive T lymphocytes.

γ-H2AX foci as in vivo effect biomarker in children emphasize the importance to minimize x-ray doses in paediatric CT imaging.

OBJECTIVES: Investigation of DNA damage induced by CT x-rays in paediatric patients versus patient dose in a multicentre setting. METHODS: From 51 paediatric patients (median age, 3.8 years) who underwent an abdomen or chest CT examination in one of the five participating radiology departments, blood samples were taken before and shortly after the examination. DNA damage was estimated by scoring γ-H2AX foci in peripheral blood T lymphocytes. Patient-specific organ and tissue doses were calculated with a validated Monte Carlo program. Individual lifetime attributable risks (LAR) for cancer incidence and mortality were estimated according to the BEIR VII risk models. RESULTS: Despite the low CT doses, a median increase of 0.13 γ-H2AX foci/cell was observed. Plotting the induced γ-H2AX foci versus blood dose indicated a low-dose hypersensitivity, supported also by an in vitro dose-response study. Differences in dose levels between radiology centres were reflected in differences in DNA damage. LAR of cancer mortality for the paediatric chest CT and abdomen CT cohort was 0.08 and 0.13 ‰ respectively. CONCLUSION: CT x-rays induce DNA damage in paediatric patients even at low doses and the level of DNA damage is reduced by application of more effective CT dose reduction techniques and paediatric protocols. .

Realising the European network of biodosimetry: RENEB-status quo.

Creating a sustainable network in biological and retrospective dosimetry that involves a large number of experienced laboratories throughout the European Union (EU) will significantly improve the accident and emergency response capabilities in case of a large-scale radiological emergency. A well-organised cooperative action involving EU laboratories will offer the best chance for fast and trustworthy dose assessments that are urgently needed in an emergency situation. To this end, the EC supports the establishment of a European network in biological dosimetry (RENEB). The RENEB project started in January 2012 involving cooperation of 23 organisations from 16 European countries. The purpose of RENEB is to increase the biodosimetry capacities in case of large-scale radiological emergency scenarios. The progress of the project since its inception is presented, comprising the consolidation process of the network with its operational platform, intercomparison exercises, training activities, proceedings in quality assurance and horizon scanning for new methods and partners. Additionally, the benefit of the network for the radiation research community as a whole is addressed.