On the monoclonality of tumours (original) (raw)

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The Biophysical Stage of Radiation Carcinogenesis Cover Page

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The Effects of Radiation and Dose-Fractionation on Cancer and Non-Tumor Disease Development Cover Page

Concepts of association between cancer and ionising radiation: accounting for specific biological mechanisms

Radiation and Environmental Biophysics

The probability that an observed cancer was caused by radiation exposure is usually estimated using cancer rates and risk models from radioepidemiological cohorts and is called assigned share (AS). This definition implicitly assumes that an ongoing carcinogenic process is unaffected by the studied radiation exposure. However, there is strong evidence that radiation can also accelerate an existing clonal development towards cancer. In this work, we define different association measures that an observed cancer was newly induced, accelerated, or retarded. The measures were quantified exemplarily by Monte Carlo simulations that track the development of individual cells. Three biologically based two-stage clonal expansion (TSCE) models were applied. In the first model, radiation initiates cancer development, while in the other two, radiation has a promoting effect, i.e. radiation accelerates the clonal expansion of pre-cancerous cells. The parameters of the TSCE models were derived from ...

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Concepts of association between cancer and ionising radiation: accounting for specific biological mechanisms Cover Page

Biological complexities in radiation carcinogenesis and cancer radiotherapy: impact of new biological paradigms

Genes, 2012

Although radiation carcinogenesis has been shown both experimentally and epidemiologically, the use of ionizing radiation is also one of the major modalities in cancer treatment. Various known cellular and molecular events are involved in carcinogenesis. Apart from the known phenomena, there could be implications for carcinogenesis and cancer prevention due to other biological processes such as the bystander effect, the abscopal effect, intrinsic radiosensitivity and radioadaptation. Bystander effects have consequences for mutation initiated cancer paradigms of radiation carcinogenesis, which provide the mechanistic justification for low-dose risk estimates. The abscopal effect is potentially important for tumor control and is mediated through cytokines and/or the immune system (mainly cell-mediated immunity). It results from loss of growth and stimulatory and/or immunosuppressive factors from the tumor. Intrinsic radiosensitivity is a feature of some cancer prone chromosomal breaka...

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Biological complexities in radiation carcinogenesis and cancer radiotherapy: impact of new biological paradigms Cover Page

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In vivo mammary tumourigenesis in the Sprague–Dawley rat and microdosimetric correlates Cover Page

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Hallmarks of radiation carcinogenesis: ignored concepts Cover Page

A Nontarget Mechanism to Explain Carcinogenesis Following α-Irradiation

Dose-Response

This commentary highlights the published data on the metabolic processes that lead to the development of cancer following intakes of asbestos and chemical agents. Following exposure to both, the key initiating event is cell injury leading to cell death that may further lead to inflammation, fibrosis, and cancer. Since α-particle transits also kill cells, it is suggested that cell death and inflammation will also trigger carcinogenesis within tissues irradiated by these particles. Such an explanation would be consistent with the inflammation and fibrosis seen in tumor-bearing tissues irradiated by radon-222, radium-226, thorium-232, plutonium-239, and other α-emitting radionuclides. It would also provide an explanation for dose-related changes in latency and in the similar dose–responses for the same tissue in differently sized species.

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A Nontarget Mechanism to Explain Carcinogenesis Following α-Irradiation Cover Page

An examination of radiation hormesis mechanisms using a multistage carcinogenesis model

Nonlinearity in biology, toxicology, medicine, 2004

A multistage cancer model that describes the putative rate-limiting steps in carcinogenesis is developed and used to investigate the potential impact on cumulative lung cancer incidence of the hormesis mechanisms suggested by Feinendegen and Pollycove. In the model, radiation and endogenous processes damage the DNA of target cells in the lung. Some fraction of the misrepaired or unrepaired DNA damage induces genomic instability and, ultimately, leads to the accumulation of malignant cells. The model explicitly accounts for cell birth and death processes, the clonal expansion of initiated cells, malignant conversion, and a lag period for tumor formation. Radioprotective mechanisms are incorporated into the model by postulating dose and dose-rate-dependent radical scavenging. The accuracy of DNA damage repair also depends on dose and dose rate. As currently formulated, the model is most applicable to low-linear-energy-transfer (LET) radiation delivered at low dose rates. Sensitivity s...

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An examination of radiation hormesis mechanisms using a multistage carcinogenesis model Cover Page

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Analysis of radiation effects using a combined cell cycle and multistage carcinogenesis model Cover Page

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A new perspective of carcinogenesis from protracted high-let radiation arises from the two-stage clonal expansion model Cover Page