Why and how to avoid stenting during brachytherapy

Intracoronary radiation is a promising therapy to reduce restenosis after percutaneous coronary intervention. It may be anticipated that radiation and intracoronary stents - the current standard coronary revascularization procedure - have a synergic antirestenosis effect. However, this potential benefit has not been proven in the clinical scenario. Indeed, this combined approach (stenting plus brachytherapy) may even be harmful. Delayed endothelialization and late stent malapposition are important drawbacks of implanting a metallic prosthesis in the setting of radiation therapy. Owing to the relatively high frequency of late thrombosis after stenting irradiated coronary arteries, the Food and Drug Administration required that the labeling of both gamma- and beta-radiation devices recently approved for clinical use explicitly advise avoidance of the placement of new stents. The pathophysiologic aspects as well as the clinical implications of the implantation of a new stent in association with radiation delivered by radioactive stents or catheter-based systems are discussed in this paper.     

Radiation-induced bystander effects and adaptive responses--the Yin and Yang of low dose radiobiology?

Our current knowledge of the mechanisms underlying the induction of bystander effects by low doses of high or low LET ionizing radiation is reviewed. The question of what actually constitutes a protective effect is discussed in the context of adaptive (often referred to as hormetic or protective) responses. Finally the review considers critically, how bystander effects may be related to observed adaptive responses or other seemingly protective effects of low doses exposures. Bystander effects induce responses at the tissue level, which are similar to generalized stress responses. Most of the work involving low LET radiation exposure discussed in the existing literature measures a death response. Since many cell populations carry damaged cells without being exposed to radiation (so-called "background damage"), it is possible that low doses exposures cause removal of cells carrying potentially problematic lesions, prior to exposure to radiation. This mechanism could lead to the production of "U-shaped" or hormetic dose-response curves. The level of adverse, adaptive or apparently beneficial response will be related to the background damage carried by the original cell population, the level of organization at which damage or harm are scored and the precise definition of "harm". This model may be important when attempting to predict the consequences of mixed exposures involving low doses of radiation and other environmental stressors.     

Unravelling UVA-induced mutagenesis

Ultraviolet A (UVA) radiation represents more than 90% of the solar UV radiation reaching Earth's surface. Exposure to solar UV radiation is a major risk in the occurrence of non-melanoma skin cancer. Whole genome sequencing data of melanoma tumors recently obtained makes it possible also to definitively associate malignant melanoma with sunlight exposure. Even though UVB has long been established as the major cause of skin cancer, the relative contribution of UVA is still unclear. In this review, we first report on the formation of DNA damage induced by UVA radiation, and on recent advances on the associated mechanism. We then discuss the controversial data on the UVA-induced mutational events obtained for various types of eukaryotic cells, including human skin cells. This may help unravel the role of UVA in the various steps of photocarcinogenesis. The connection to photocarcinogenesis is more extensively discussed by other authors in this issue.     

The example of gastrointestinal damage induced by ionising radiation: are there accessible markers?

Ionising radiation exposure occurs during radiotherapy, diagnostic tests or by accident. In all cases the gastrointestinal tract, which is highly sensitive to radiation, may be at risk. Each region may respond differently to radiation exposure which to some extent is reflected by clinical symptoms. The evaluation of injury, whether acute or chronic, depends on the utilization of a variety of techniques. It appears that no definitive tests exist and that a multiparametric analysis should be undertaken. This review addresses the question of accessible markers associated with radiation-induced intestinal pathologies. Several approaches are discussed which include clinical observations, measurement of faecal parameters, changes in inflammatory mediators and possible applications of imaging techniques.     

Expanding radiation quarantine treatments beyond fruit flies

1 The potential of ionizing radiation as a disinfestation treatment for insects other than tephritid fruit flies is discussed. Radiation quarantine treatments are unique in that insects are not killed immediately but rendered sterile or incapable of completing development. 2 The most tolerant insect stage to radiation is that which is most developed. Female insects, but not always mites, are sterilized with equal or lower doses than males. 3 Insects irradiated with sterilizing doses usually have shorter longevities than non‐irradiated ones. Low oxygen conditions often increase tolerance to radiation. 4 Insects in diapause are not more tolerant of radiation than non‐diapausing ones. 5 Some pests of several groups, such as aphids, whiteflies, weevils, scarab beetles, and fruit flies, may be controlled with doses ≤ 100 Gy. Some lepidopterous pests and most mites require about 300 Gy. Stored product moths may require as much as 1 kGy to sterilize, and nematodes could need > 4 kGy. 6 Even though application of irradiation to pallet‐loads of produce could mean that up to three times the minimum required dose is applied to the perimeter of the pallet, many fresh commodities tolerate doses required for quarantine security against many quarantined pests. Irradiation is arguably the most widely applicable quarantine treatment from the standpoint of commodity quality.     

Ultraviolet radiation screening compounds

Amongst the diversity of methods used by organisms to reduce damage caused by ultraviolet (UV) radiation, the synthesis of UV-screening compounds is almost ubiquitous. UV-screening compounds provide a passive method for the reduction of UV-induced damage and they are widely distributed across the microbial, plant and animal kingdoms. They share some common chemical features. It is likely that on early earth strong selection pressures existed for the evolution of UV-screening compounds. Many of these compounds probably had other physiological roles, later being selected for the efficacy of UV screening. The diversity in physiological functions is one of the complications in studying UV-screening compounds and determining the true ecological importance of their UV-screening role. As well as providing protection against ambient UV radiation, species with effective screening may also be at an advantage during natural ozone depletion events. In this review the characteristics of a wide diversity of UV-screening compounds are discussed and evolutionary questions are explored. As research into the range of UV-screening compounds represented in the biosphere continues, so it is likely that the properties of many more compounds will be elucidated. These compounds, as well as providing us with insights into natural responses to UV radiation, may also have implications for the development of artificial UV-screening methods to reduce human exposure to UV radiation.     

Overview of Paleoindian taxonomy and migration hypotheses

New research indicates an ice-free corridor may have been open for 20,000 years in North America and people could have moved southward even at Last Glacial Maximum. Isolation in America led to an adaptive radiation. A formal taxonomic review defines the early Paleoindian groups as Otomid-Sundadonts and compares conventional paleontological methodology with methods used in physical anthropology. Competing migration hypotheses are discussed.     

Time effects in molecular radiation Biology

Summary Radiation action occurs over a broad timescale which extends from the very early physical processes associated with energy absorption to the very late biological effects, such as carcinogenesis which may not become apparent until many years later. The various temporal stages of radiation action are classified and their interrelationships described. Experimental projects in cellular radiation chemistry, including pulse radiolysis, are discussed, together with some applications of the techniques in this general area.The paper also deals with some aspects of the oxygen effect in radiobiology and the mechanisms of its action. Various studies employing fast response techniques have been useful in verifying the role of fast free radical reactions in the oxygen effects and examples are given of some applications. Investigations with other hypoxic cell sensitizers, the electron affinic agents, are also briefly discussed, with an account of how studies of the timescale of radiation sensitization can be valuable in understanding mechanisms. Possible mechanisms of action of radiation sensitization by oxygen and other agents, including radical fixation and direct action processes, are considered in the light of evidence from some model systems.Invited paper, presented at the 14th Annual Meeting of European Society of Radiation Biology, Jülich, Germany, October 8–14, 1978     

OBSERVATIONS ON THE PECULIAR DIURNAL MIGRATION OF A RED TIDE DINOPHYCEAE IN TROPICAL SHALLOW WATERS1

The dinoflagellate Peridinium cf. quinquecorne Abé forms red tide-like blooms in eutrophic shallow waters in the Philippines. The organism moves into a distinct near-surface layer when intensive solar radiation occurs, but only during the incoming tide. Shortly before high tide, regardless of light levels, the dinoflagellates seem to disappear. Simple experiments show that once intensive radiation has been reduced Peridinium quinquecorne moves out of the water column and attaches itself to solid objects away from the light. The morphology of the organism, especially as related to attachment, was studied through SEM. Its high swimming velocity and the reaction to radiation and tidal changes are described. The possibility that, superimposed on its reaction to light, this dinoflagellate may follow intrinsic tide-dependent oscillations is discussed.     

Neoteny, evolution and the New Zealand Parsonsia hybrids (Apocynaceae)

The striking diversification of leaf shape in juveniles of the hybrids between Parsonsia heterophylla A. Cunn. and P. capsularis (Forst. f.) R. Br. is described and illustrated. The applicability of Turing's diffusion reaction theory of morphogenesis was tested, and it was found that the diversity could be explained as a result of interactions between sine-wave-like gradients of morphogens in the leaf primordia. Precession in the onset of sexual maturity leads to the fixation of juvenile leaf characters. This neotenic process combined with natural selection may then lead to speciation and adaptive radiation, as in the Australian Parsonsia spp. The operation of these processes in other New Zealand genera and in Australian Proteaceae is discussed in relation to adaptive radiation and evolution.     

UV-B辐射增强对陆地生态系统碳循环的影响

作为全球变化的重要现象之一,紫外射线B(UV-B,波长280～320 nm)辐射增强对陆地生态系统碳循环具有重要影响.UV-B辐射增强主要通过改变植物的光合作用、凋落物分解以及土壤呼吸来影响陆地生态系统碳的输入和转化输出.其他气候因子(大气CO2浓度、温度和水分)可能会促进或减缓UV-B辐射对陆地生态系统碳循环的作用.本文介绍了UV-B辐射增强的背景,综述了国内外近年来UV-B辐射增强及与其他气候因子交互作用对陆地生态系统碳循环的影响,总结了目前研究存在的不足,讨论了未来的研究重点和方向.     

Experimental radiation pneumonitis. Corticosteroids increase the replicative activity of alveolar type 2 cells

Corticosteroid administration during radiation pneumonitis in mice markedly improves the physiologic abnormalities and decreases mortality, an effect that has been attributed to the stimulation of surfactant synthesis and secretion by type 2 alveolar epithelial cells. In the present experiments we explored the effects of corticosteroids on the replicative activity of type 2 cells of lethally irradiated lungs at the height of the radiation reaction. The labeling index of type 2 cells of irradiated mice was increased threefold above that of sham-irradiated controls. Corticosteroids given continuously from 10 weeks after thoracic irradiation further increased the type 2 cell labeling index another threefold above that of irradiated untreated mice. The enhanced reproductive activity of type 2 cells following thoracic irradiation is seen as a protective response that is augmented by corticosteroids, whose effect may be both to improve the physiology of the alveolar surface and to maintain the population of alveolar epithelial cells. The bearing of this result on the controversial role of the type 2 cell as a target in radiation pneumonitis is discussed.     

Cellular senescence, radiation damage to mitochondria, and the compensatory response in ripening pear fruits

A compensatory response, viz. in vivo recovery from radiation damage to mitochondria, occurs in preclimacteric pear fruits (Pyrus communis L.) treated with ionizing radiation. The compensatory response is absent or markedly impaired in senescent fruits irradiated at or near the climacteric peak. Senescent cells failed to recover from harmful effects of radiation on: 1) mitochondrial yield, 2) in vivo incorporation of amino acids into mitochondrial protein, and 3) mitochondrial respiratory control and ADP/O. A diminished response to “split-dose” irradiation and a delayed rate of recovery confirmed the degeneracy and loss of compensatory power with cell age.

A loss of restorative activity, especially in mitochondria that supply the cell with essential energy, may underlie the more obvious signs of cumulative stress that accompany cellular senescence. Use of ionizing radiation as an investigative tool and the molecular implications of radiation damage, recovery, and cellular senescence are discussed.

     

Cancer as an emergent phenomenon in systems radiation biology

Radiation-induced DNA damage elicits dramatic cell signaling transitions, some of which are directed towards deciding the fate of that particular cell, while others lead to signaling to other cells. Each irradiated cell type and tissue has a characteristic pattern of radiation-induced gene expression, distinct from that of the unirradiated tissue and different from that of other irradiated tissues. It is the sum of such events, highly modulated by genotype that sometimes leads to cancer. The challenge is to determine as to which of these phenomena have persistent effect that should be incorporated into models of how radiation increases the risk of developing cancer. The application of systems biology to radiation effects may help to identify which biological responses are significant players in radiation carcinogenesis. In contrast to the radiation biology paradigm that focuses on genomic changes, systems biology seeks to integrate responses at multiple scales (e.g. molecular, cellular, organ, and organism). A key property of a system is that some phenomenon emerges as a property of the system rather than of the parts. Here, the idea that cancer in an organism can be considered as an emergent phenomenon of a perturbed system is discussed. Given the current research goal to determine the consequences of high and low radiation exposures, broadening the scope of radiation studies to include systems biology concepts should benefit risk modeling of radiation carcinogenesis. Presented at the First International Workshop on Systems Radiation Biology, February 14–16 2007, GSF-Research Centre, Neuherberg, Germany.     

Kybernetische Aspekte der Strahlenschädigung

Starting with experimentally established radiobiological facts concerning cellular effects of ionizing radiation, the differences between single cells and tissues are discussed. A new classification for “size”-controlled tissues is proposed, and the relevant mathematical formulations are outlined. It is suggested that the different sensitivities of tissues against ionizing radiation may be explained on the basis of differently operating control mechanisms. As examples, root meristems, intestinal epithelium and blood forming organs are described in more detail.     

Structural chromosome organisation and radiation-induced interchromosomal aberrations

The quantitative prediction of the biological effects of radiation is one of the actual tasks of radiobiology. The experimental study may be impossible under certain conditions (low doses, complex radiation fields, etc). The development of theoretical tools is required to predict biological and medical consequence of the irradiation of cell and organism. The effect under the consideration in the present paper is chromosome aberrations (CA) induced by low and high LET radiation. One of the most uncertain factors in CA prediction is the impact of chromosomal and nuclear architecture. In the present study the quantitative evaluation of the mechanisms of CA induction are discussed in the framework of the biophysical modelling technique taking into account interphase chromosomes structure in the nucleus of living (human) cell. We show that the surface contacts mechanism of interchromosomal aberrations (interchange) formation does not explain the observed ratio of simple/complex interchanges induced by both low and high LET radiation. The chromatin structure repositioning following irradiation is proposed as a possible mechanism involved in the formation of the complex aberrations.     

一些海洋浮游植物量子产值的研究

现场实验以及用硅藻、金藻和绿藻所做的实验表明,在光饱和深度以下,随着深度的增加,浮游植物的量子产懂具有不变、增加和下降3种垂直变化趋势。偏离理论模式的后两种结果可能是由浮游植物的光强适应(Light-shade adaptation)等原因引起。还探讨了量子产值作为初级生产力模型和光利用效率模型中的参数的问题。     

Internal filters: Prospects for UV-acclimation in higher plants

Wavelength-selective absorption of solar radiation within plant leaves allows penetration of visible radiation (400–700 nm) to the chloroplasts, while removing much of the damaging ultraviolet-B (UV-B, 280–320 nm) radiation. Flavonoids are important in this wavelength-selective absorption. Induction of flavonoid synthesis by solar radiation, and specifically by UV-B radiation, is discussed as this relates to the potential acclimation of plants to enhanced solar UV-B radiation that would result from stratospheric ozone reduction.