Exposure to diagnostic radiation and risk of breast cancer among carriers of BRCA1/2 mutations: retrospective cohort study (GENE-RAD-RISK)

Pijpe, Anouk; Andrieu, Nadine; Easton, Doug; Kesminiene, Ausrele; Cardis, Elisabeth; Noguès, Catherine; Gauthier‐Villars, Marion; Lasset, Christine; Fricker, Jean Pierre; Peock, Susan; Frost, Debra; Evans, D. Gareth; Eeles, Rosalind A.; Paterson, Joan; Manders, Peggy; Asperen, C. J. van; Ausems, Margreet G. E. M.; Meijers-Heijboer, Hanne; Thierry-Chef, Isabelle; Hauptmann, Michael; Goldgar, David E.; Rookus, Matti A.; Leeuwen, Flora E. van

doi:10.1136/bmj.e5660

Cited by 193 publications

(140 citation statements)

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“…In the analysis of cancer risk in children from 160 families irradiated in Israel after World War II for an epidemic of tinea capitis, it was found that the increased meningioma incidence in irradiated children was determined by a subgroup of only 17 families (11%), where 4 of 5 children developed meningioma. 105 In addition, the large European cohort study GENE-RAD-RISK 106 has recently concluded that in carriers of BRCA1/2 mutations, any exposure to diagnostic radiation before the age of 30 years is associated with an increased risk of breast cancer. The relative risk in the mutant carrier was 1.9 and increased with dose.…”

Section: Carcinogenesismentioning

confidence: 99%

“…The relative risk in the mutant carrier was 1.9 and increased with dose. 106 Genetic predisposition may also drive the risk from exposure to charged particles. This is a critical issue for paediatric patients, a group that is often referred to proton therapy because much normal tissue can be spared compared with X-rays and, therefore, toxicity is reduced.…”

Section: Carcinogenesismentioning

confidence: 99%

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New challenges in high-energy particle radiobiology

Durante

2014

BJR

125

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Densely ionizing radiation has always been a main topic in radiobiology. In fact, a-particles and neutrons are sources of radiation exposure for the general population and workers in nuclear power plants. More recently, high-energy protons and heavy ions attracted a large interest for two applications: hadrontherapy in oncology and space radiation protection in manned space missions. For many years, studies concentrated on measurements of the relative biological effectiveness (RBE) of the energetic particles for different end points, especially cell killing (for radiotherapy) and carcinogenesis (for late effects). Although more recently, it has been shown that densely ionizing radiation elicits signalling pathways quite distinct from those involved in the cell and tissue response to photons. The response of the microenvironment to charged particles is therefore under scrutiny, and both the damage in the target and non-target tissues are relevant. The role of individual susceptibility in therapy and risk is obviously a major topic in radiation research in general, and for ion radiobiology as well. Particle radiobiology is therefore now entering into a new phase, where beyond RBE, the tissue response is considered. These results may open new applications for both cancer therapy and protection in deep space.Biological effects of densely ionizing radiation have been studied since the beginning of radiobiology. As a matter of fact, a-particles deliver the main contribution to the background radiation dose on Earth, owing to inhalation of the indoor radon.1 Neutrons have also been extensively studied because of protection of workers in nuclear power plants; use of fast neutrons in radiotherapy; and of the exposure of the survivors of the atomic bomb in Hiroshima and Nagasaki, where a neutron component was added to g-rays. Bacq and Alexander 2 already elegantly described the radiobiology of a-particles and neutrons in their 1955 seminal book.More recently, radiobiology research has focused on highenergy protons and heavy ions, mostly for two reasons: charged particle therapy (CPT) in oncology and radiation protection in manned space missions. In both cases, charged particles at energies .100 MeV n 21 are involved. The characteristic depth-dose distribution with the sharp Bragg peak at the end of the range can be exploited for killing tumours; on the other hand, densely ionizing radiation can effectively delay tissue morbidity. Notwithstanding the many differences in exposure conditions, CPT and space radiation protection share several research topics, including individual sensitivity, non-targeted effects, late stochastic effects and so forth.3 Research in these fields requires large high-energy accelerators and is often performed by the same research groups with a common interest in particle radiobiology. Research is rapidly moving forward owing to the diffusion of CPT centres in the USA, Europe, and Asia 4 and to the growing interest in manned space exploration, now a priority for all space agencies, 5 but wi...

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Section: Carcinogenesismentioning

confidence: 99%

Section: Carcinogenesismentioning

confidence: 99%

New challenges in high-energy particle radiobiology

Durante

2014

BJR

125

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“…For low-risk premenopausal women, alternative tests without radiation exposure (eg, ECG) or a no-testing strategy should be strongly considered. 40 Table 3 details the typical effective radiation dose for MPI, angiography, and CCTA. 35,41 Average background radiation exposure per year for a member of the US population is ≈3.1 mSv.…”

Section: Diagnostic Procedures For Ihd That Expose Women To Ionizingmentioning

confidence: 99%

Role of Noninvasive Testing in the Clinical Evaluation of Women With Suspected Ischemic Heart Disease

Mieres¹,

Gulati²,

Merz³

et al. 2014

Circulation

220

176

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“…This does not account for higher background risks of breast cancer or increased radiosensitivity suggested for BRCA1/BRCA2 carriers whose genetic defects give rise to impairment in DNA repair by homologous recombination, once the cell has lost both functioning copies of the gene. 15 However, it still remains to be shown that the cells which are heterozygous for a mutation are more radiosensitive. The current study is not powered to assess any effects in BRCA1/2 mutation carriers specifically, and as these females qualify for the more sensitive MRI screening, they may not need mammography.…”

mentioning

confidence: 99%

“…Nevertheless, we would not advocate commencing mammography ,30, in line with current UK recommendations. 15 The lower sensitivity of mammography in younger females 16 should be taken into account in determining its potential risks and benefits in these females. There was also no evidence of a greater carcinogenic effect of radiation in those estimated at particularly high breast cancer risk (.30%).…”

mentioning

confidence: 99%