Cytogenetic effects in follicular epithelium of thyroid gland under prolonged exposure to gamma-radiation at low-doses

The forming processes of micronucleated follicular thyrocytes in thyroid gland of mature Wistar rats under exposure to the prolonged low-intensity gamma-radiation with 5 and 50 cGy (dose rates: 25, 400 microGy/h; duration: 55, 80 days) were investigated. The chronic exposure to low-intensity gamma-radiation in both doses invokes the frequency of micronuclated thyrocytes three times higher in comparison with control animals. As a result of the small-sized micronuclei formation prevalence in irradiated group, the average size of micronuclei was 1.4-2 times lower than control values. This phenomenon can be reproduced in model experiments with hemithyroidectomized animals exposured to acute gamma-radiation with 2-4 Gy. The obtained results show high sensitivity of micronucleus test to the early determination of radiation-induced genetic damages in follicular epithelium of thyroid gland.     

Membrane structure alterations in rat blood lymphocytes under external low dose rate gamma-radiation exposure

The influence of a 0.72 cGy/day dose rate of gamma-radiation on plasma membranes of peripheral blood lymphocytes of rats exposed to the doses of 1.5, 15, 30, 60 and 100 cGy was studied. Parameters characterizing the viscosity and the polarity of lipid bilayer and also an external membrane surface properties were examined using fluorescent probes pyrene and 1-anilinonaphthalene-8-sulfonate (ANS). Was shown the membrane structural parameters alterations after animal exposure to the doses of 1.5, 15, 60 and 100 cGy, being of a nonmonotonous nature as the dose accumulated. After exposure to the doses lower then than 30 cGy spectral changes were revealed not in each particular experiment that was probably caused by the individual peculiarities of radiation response development. After exposure to the doses higher than 30 cGy the changes were of reproducible character. After a 1.5 cGy dose a slight lipid bilayer polarity decrease and ANS binding parameter multidirectional changes were observed. After exposure to 15, 60 and to 100 cGy was shown polarity elevation and repartition of polar groups within the bilayer, the increase of viscosity of more polar membrane regions and also ANS fluorescence reduction mostly at the expense of quantum yield decrease. After the exposure of 60 cGy was observed a viscosity decrease in hydrophobic regions along with viscosity increase in more polar regions and after a 100 cGy dose accumulation an essential surface charge shift was found. Revealed alterations indicate the reorganization of external membrane surface and of intensification of oxidative processes in lipid bilayer.     

Irradiation and second cancers. The thyroid as a case in point

The thyroid gland is highly sensitive to radiation during childhood: the risk of thyroid tumours is increased for mean doses as low as 100 mGy and for higher doses, the risk increases linearly with the dose. Excess relative risk is important, being 7.7 for 1 Gy delivered to the thyroid gland during childhood. The risk of thyroid tumours is modified by several factors: a) age at exposure: in childhood, the risk decreases with increasing age at exposure and is not significant after 20 years; b) gender: females are two times more likely than males to develop thyroid tumours; c) genetic predisposition due to a defect in DNA repair mechanisms, and dietary and hormonal factors may modify the risk; d) the influence of fractionation and dose rate is not well established. Radioiodine 131 (1311) used for medical purposes has almost no tumourigenic effect on the adult thyroid gland. The consequences of the Chernobyl accident have clearly shown that the risk of thyroid cancer after exposure to 1311 in childhood is important, and that such exposure should be prevented by potassium iodine prophylaxis. RET/PTC rearrangements are found in 60-80% of papillary carcinomas and in 45% of adenomas occurring after radiation exposure. They are found in 5-15% of papillary carcinoma and in no follicular adenomas that occurred in the absence of radiation exposure.     

Non-malignant thyroid diseases after a wide range of radiation exposures

The thyroid gland is one of the most radiosensitive human organs. While it is well known that radiation exposure increases the risk of thyroid cancer, less is known about its effects in relation to non-malignant thyroid diseases. The aim of this review is to evaluate the effects of high- and low-dose radiation on benign structural and functional diseases of the thyroid. We examined the results of major studies from cancer patients treated with high-dose radiotherapy or thyrotoxicosis patients treated with high doses of iodine-131, patients treated with moderate- to high-dose radiotherapy for benign diseases, persons exposed to low doses from environmental radiation, and survivors of the atomic bombings who were exposed to a range of doses. We evaluated radiation effects on structural (tumors, nodules), functional (hyper- and hypothyroidism), and autoimmune thyroid diseases. After a wide range of doses of ionizing radiation, an increased risk of thyroid adenomas and nodules was observed in a variety of populations and settings. The dose response appeared to be linear at low to moderate doses, but in one study there was some suggestion of a reduction in risk above 5 Gy. The elevated risk for benign tumors continues for decades after exposure. Considerably less consistent findings are available regarding functional thyroid diseases including autoimmune diseases. In general, associations for these outcomes were fairly weak, and significant radiation effects were most often observed after high doses, particularly for hypothyroidism. A significant radiation dose-response relationship was demonstrated for benign nodules and follicular adenomas. The effects of radiation on functional thyroid diseases are less clear, partly due to the greater difficulties encountered in studying these diseases.     

Thyroid neoplasia following low-dose radiation in childhood

The thyroid gland is highly sensitive to the carcinogenic effects of ionizing radiation. Previously, we reported a significant increase of thyroid cancer and adenomas among 10,834 persons in Israel who received radiotherapy to the scalp for ringworm. These findings have now been extended with further follow-up and revised dosimetry. Overall, 98 thyroid tumors were identified among the exposed and 57 among 10,834 nonexposed matched population and 5392 sibling comparison subjects. An estimated thyroid dose of 9 cGy was linked to a fourfold (95% Cl = 2.3-7.9) increase of malignant tumors and a twofold (95% Cl = 1.3-3.0) increase of benign tumors. The dose-response relationship was consistent with linearity. Age was an important modifier of risk with those exposed under 5 years being significantly more prone to develop thyroid tumors than older children. The pattern of radiation risk over time could be described on the basis of a constant multiplication of the background rate, and an absolute risk model was not compatible with the observed data. Overall, the excess relative risk per cGy for thyroid cancer development after childhood exposure is estimated as 0.3, and the absolute excess risk as 13 per 10(6) PY-cGy. For benign tumors the estimated excess relative risk was 0.1 per cGy and the absolute risk was 15 per 10(6) PY-cGy.     

Comparison of the possibilities of micronuclear and chromosomal aberration tests for evaluation of the effects of radiation of different intensities

The comparative evaluation of sensitivity and specificity of the micronucleus and chromosome aberration tests for human lymphocytes at the delayed terms after acute exposure to high-dose as well as during constant exposure to low-dose gamma-radiation has been done. Accordance between these tests registered only in the cases of acute radiation sickness of second and third degrees of severity (irradiation doses above 200 cGy). Unspecificity of micronucleus test for estimation of the radiation load under constant low-intensity irradiation was found.     

Effect of long-term exposure to low dose gamma-irradiation on the rat thyroid status

The effect of long-term exposure to low-dose external radiation on the rat thyroid status was studied. The experiments were carried out on Wistar female rats. The single doses absorbed were 0.1; 0.25; 0.5 Gy. The rats were irradiated 20 times (5 days x 4 weeks). The animals were decapitated after 1, 30 and 180 days following the last irradiation. Blood serum was assayed for content of thyroxin (T4) and triiodothyronine (T3) radioimmunologically. The liver was spectrophotometrically assayed for thyroid-induced NADP-malatedehydrogenase (NADP-MDH). It was shown that the long-term 0.5-Gy irradiation of the animals induced a decrease in blood T4 and T3 concentrations 1.34-1.71-fold and 1.24-1.43-fold after 1, 30 and 180 days, respectively. The T3 level was diminished most pronouncedly after 1 day, whereas that of T4--after 30 days following the exposure. With the doses of 0.1 and 0.25 Gy absorbed, the T4 and T3 concentration remained unchanged throughout all the periods studied. The activity of NADP-MDH was decreased 1.55-2.46-fold in all the experimental animals, and it was held decreased after 180 days (1.43-1.50-fold) in 0.25- and 0.5-Gy-irradiated groups, which indicates a disturbance in thyroid hormone metabolism in rats exposed chronically to low-dose radiation. After 180 days, the experimental animals experienced an elevation of thyroid gland weight on 15-20%. The thyroid status disturbance seemed to be due to both inhibited T4 and T3 biosynthesis in thyroid and disturbed hormone peripheral metabolism under radiation exposure.     

Comparative od adaptive response to gamma-radiation and nickel sulfate treatment in human cells

Increased viability of human cells (line rhabdomyosarcoma) to challenge doses of NiSO4 (10(-5)-10(-3) M) was formed when cells were preirradiated with low doses of gamma-radiation (10-14 cGy). Observed adaptive response was similar to radioadaptive response in human fibroblasts, pretreated with low doses of gamma-radiation and challenge dose of the same mutagen. Pretreatment with low concentration of NiSO4 induced in human fibroblasts increased resistance of DNA to the treatment with challenge doses of gamma-radiation and stimulated DNA repair synthesis after treatment with NiSO4 and 4-nitroquinoline-1-oxide. These data confirm the existence of cross-adaptation in the experiments with NiSO4.     

Study of genome instability using DNA fingerprinting of the offspring of male mice subjected to chronic low dose gamma irradiation

By a polymerase chain reaction with an arbitrary primer (AP-PCR), the possibility of transmission of genome instability to somatic cells of the offspring (F1 generation) from male parents of mice exposed to chronic low-level gamma-radiation was studied. Male BALB/c mice 15 days after exposure to 10-50 cGy were mated with unirradiated females. Biopsies were taken from tale tips of two month-old offspring mice and DNA was isolated. The primer in the AP-PCR was a 20-mer oligonucleotide flanking the microsatellite locus Atp1b2 on chromosome 11 of the mouse. A comparative analysis of individual fingerprints of AP-PCR products on DNA-templates from the offspring of irradiated and unirradiated male mice revealed an increased variability of microsatellite-associated sequences in the genome of the offspring of the males exposed to 25 and 50 cGy. The DNA-fingerprints of the offspring of male mice exposed to chronic irradiation with the doses 10 and 25 cGy 15 days before fertilization (at the post-meiotic stage of spermatogenesis) showed an increased frequency of "non-parent bands". The results of the study point to the possibility of transmission to the offspring somatic cells of changes increasing genome instability from male parents exposed to chronic low-level radiation prior to fertilization.     

Quantitative characteristics of radiation injury of the spermatogenic epithelium and the rate of its recovery after exposure to fast neutrons and gamma-radiation

The paper submits the results of studies on the kinetics of spermatogenous epithelium cell number after exposure to fast neutrons (60-300 cGy) and gamma-radiation (200-600 cGy). It was shown that a relative decrease in the quantity of spermatocytes is determined by an exponential dose-response curve with D0 of 35 and 120 cGy for neutrons and gamma-radiation respectively. For spermatides and spermatozoa a single D0 value of 20 and 55 cGy was obtained for neutrons and gamma-radiation respectively. As the radiation dose increases the recovery process in the epithelium is substantially decelerated. The equation T1/2 = T1/2(0)e0.0009D well describes the dependence of the half-recovery period T1/2 upon the equivalent dose.     

Carcinogenic effects of combined exposure to 241Am and gamma-radiation

In experiments on Wistar rats a study was made of the carcinogenic effects of the combined exposure to 241Am administered intraperitoneally (6.7 to 229.4 kBq/kg body weight) and external gamma-radiation (137Cs, 175 cGy). The occurrence of osteosarcoma, leucosis, skin and mammary tumors increased in the exposed animals. The combined irradiation produced an additive carcinogenic effect.     

Effects of protons and HZE particles on glutamate transport in astrocytes, neurons and mixed cultures

Radiation-induced neurotoxicity is a well-characterized phenomenon. However, the underlying mechanism of this toxicity is poorly understood. In the central nervous system (CNS), excitotoxic mechanisms are implicated in many neurodegenerative disease processes. Pivotal to the excitotoxic pathway is dysfunction of glutamate signaling. We reported previously that exposure to low-LET γ radiation results in altered glutamate transport in neurons and astrocytes. In the present study, we sought to investigate the effects of various particle radiations of differing LET on glutamate transport as a measure of the neurochemical vulnerability of the CNS. NTera2-derived neurons and astrocytes isolated as pure and mixed cultures were exposed to doses of 10 cGy, 50 cGy or 2 Gy of 250 MeV protons, 290 MeV/nucleon carbon ions, or 1000 MeV/nucleon iron ions. Transporter function was assessed at 3 h, 2 days and 7days after exposure. Functional assessment of glutamate transport revealed that neurons and astrocytes respond in a reciprocal manner after exposure to particle radiation. Uptake activity in neurons increased after particle irradiation. This effect was evident as late as our last time (7 days) after exposure (P < 0.05). In astrocytes, transporter activity decreased after exposure. The decrease in uptake observed in astrocytes was evident 7 days after exposure to carbon and iron ions. Uptake in mixed cultures after exposure to all three forms of radiation revealed a muted interactive response suggestive of the individual responses of each cellular phenotype acting in opposition.     

Effect of low doses of ionizing irradiation on viability of cortical thymocytes

The cortical thymocytes of rats in whole organism, isolated lobes of thymus and cells suspension were exposed to ionizing radiation in a wide range of doses (0.1-200 cGy). In contrast to relatively high dose radiation (50-200 cGy), exposure to doses of 10 cGy resulted in cell death without DNA degradation. The level of doses lower than 10 cGy (0.5-5 cGy) induced thymocyte death which is independent of DNA degradation, RNA and protein synthesis. With decrease in radiation dose, the increase of latent period preceding cell death took place.     

Response of the developing thyroid gland of rats to a single gamma-irradiation in the period of intrauterine development

A single external exposure of pregnant rats to 2 Gy gamma-radiation caused changes in the functional status of the thyroid gland in offsprings at varying times of the postnatal development. The disturbance of the thyroid hormones balance in the blood, destruction of the thyroid gland combined with high functional tension of secretory elements, and activation of the thyrotropic function of hypophysis were revealed at remote times after irradiation.     

Risk of second primary thyroid cancer after radiotherapy for a childhood cancer in a large cohort study: an update from the childhood cancer survivor study

Previous studies have indicated that thyroid cancer risk after a first childhood malignancy is curvilinear with radiation dose, increasing at low to moderate doses and decreasing at high doses. Understanding factors that modify the radiation dose response over the entire therapeutic dose range is challenging and requires large numbers of subjects. We quantified the long-term risk of thyroid cancer associated with radiation treatment among 12,547 5-year survivors of a childhood cancer (leukemia, Hodgkin lymphoma and non-Hodgkin lymphoma, central nervous system cancer, soft tissue sarcoma, kidney cancer, bone cancer, neuroblastoma) diagnosed between 1970 and 1986 in the Childhood Cancer Survivor Study using the most current cohort follow-up to 2005. There were 119 subsequent pathologically confirmed thyroid cancer cases, and individual radiation doses to the thyroid gland were estimated for the entire cohort. This cohort study builds on the previous case-control study in this population (69 thyroid cancer cases with follow-up to 2000) by allowing the evaluation of both relative and absolute risks. Poisson regression analyses were used to calculate standardized incidence ratios (SIR), excess relative risks (ERR) and excess absolute risks (EAR) of thyroid cancer associated with radiation dose. Other factors such as sex, type of first cancer, attained age, age at exposure to radiation, time since exposure to radiation, and chemotherapy (yes/no) were assessed for their effect on the linear and exponential quadratic terms describing the dose-response relationship. Similar to the previous analysis, thyroid cancer risk increased linearly with radiation dose up to approximately 20 Gy, where the relative risk peaked at 14.6-fold (95% CI, 6.8-31.5). At thyroid radiation doses >20 Gy, a downturn in the dose-response relationship was observed. The ERR model that best fit the data was linear-exponential quadratic. We found that age at exposure modified the ERR linear dose term (higher radiation risk with younger age) (P < 0.001) and that sex (higher radiation risk among females) (P = 0.008) and time since exposure (higher radiation risk with longer time) (P < 0.001) modified the EAR linear dose term. None of these factors modified the exponential quadratic (high dose) term. Sex, age at exposure and time since exposure were found to be significant modifiers of the radiation-related risk of thyroid cancer and as such are important factors to account for in clinical follow-up and thyroid cancer risk estimation among childhood cancer survivors.     

Thyroid cancer after exposure to external radiation: a pooled analysis of seven studies

The thyroid gland of children is especially vulnerable to the carcinogenic action of ionizing radiation. To provide insights into various modifying influences on risk, seven major studies with organ doses to individual subjects were evaluated. Five cohort studies (atomic bomb survivors, children treated for tinea capitis, two studies of children irradiated for enlarged tonsils, and infants irradiated for an enlarged thymus gland) and two case-control studies (patients with cervical cancer and childhood cancer) were studied. The combined studies include almost 120,000 people (approximately 58,000 exposed to a wide range of doses and 61,000 nonexposed subjects), nearly 700 thyroid cancers and 3,000,000 person years of follow-up. For persons exposed to radiation before age 15 years, linearity best described the dose response, even down to 0.10 Gy. At the highest doses (>10 Gy), associated with cancer therapy, there appeared to be a decrease or leveling of risk. For childhood exposures, the pooled excess relative risk per Gy (ERR/Gy) was 7.7 (95% CI = 2.1, 28.7) and the excess absolute risk per 10(4) PY Gy (EAR/10(4) PY Gy) was 4.4 (95% CI = 1.9, 10.1). The attributable risk percent (AR%) at 1 Gy was 88%. However, these summary estimates were affected strongly by age at exposure even within this limited age range. The ERR was greater (P = 0.07) for females than males, but the findings from the individual studies were not consistent. The EAR was higher among women, reflecting their higher rate of naturally occurring thyroid cancer. The distribution of ERR over time followed neither a simple multiplicative nor an additive pattern in relation to background occurrence. Only two cases were seen within 5 years of exposure. The ERR began to decline about 30 years after exposure but was still elevated at 40 years. Risk also decreased significantly with increasing age at exposure, with little risk apparent after age 20 years. Based on limited data, there was a suggestion that spreading dose over time (from a few days to >1 year) may lower risk, possibly due to the opportunity for cellular repair mechanisms to operate. The thyroid gland in children has one of the highest risk coefficients of any organ and is the only tissue with convincing evidence for risk at about 0.10 Gy.     

Accumulation, activation and interindividual variation of the epidermal TP53 protein in response to ionizing radiation in organ cultured human skin

In this study, we examined effects of low-dose ionizing radiation on organ cultured human foreskin and, in particular, on the epidermis. Diagnostic, therapeutic, natural environmental and incidental exposures to moderate to low doses of radiation are inevitable and, although information on cultured cells continues to accumulate, little is known about the effects of low-dose radiation on human tissues. Our hypothesis is that ex vivo organ cultured foreskin is a simple and reliable model to study the biochemical effects of low-dose radiation exposure on skin. A model such as this will aid in the identification and quantification of low-dose radiation-induced changes in proteins in human skin and may be useful in the development of a precise, non-invasive, and reliable assay of exposure. In this work, several aspects of skin responses to culture conditions and radiation were examined. The responses of epidermal TP53 from organ cultured skin irradiated in medium with and without serum were found to be similar. TP53 levels in organ cultured neonatal foreskin epidermis were then examined for baseline TP53 expression. After an initial increase at 4 h, the TP53 D01 signal returned to low steady-state levels for at least 72 h. Irradiated skin samples from different individuals revealed variations in the TP53 D01 signal. The dose and temporal response of dermis and epidermis to radiation were examined by Western blotting from 0 to 24 h after exposure. After irradiation and incubation, the epidermis was removed and assayed by Western blotting and was found to have increases in the TP53 D01 epitope and the TP53 phosphoserine 15 (TP53-S15p) epitope that reached a maximum at about 3 h. In the epidermis, doses of 1-5 cGy of radiation were detectable with the TP53 D01, and CDKN1A antibodies and doses greater than 10 cGy were detectable with the TP53-S15p antibody. When the dermis was compared to epidermis, it was found that dermis had a smaller response to radiation and more phosphorylated TP53.     

Exposure to non-ionizing radiation provokes changes in rat thyroid morphology and expression of HSP-90

Non-ionizing radiation at 2.45 GHz may modify the morphology and expression of genes that codify heat shock proteins (HSP) in the thyroid gland. Diathermy is the therapeutic application of non-ionizing radiation to humans for its beneficial effects in rheumatological and musculo-skeletal pain processes. We used a diathermy model on laboratory rats subjected to maximum exposure in the left front leg, in order to study the effects of radiation on the nearby thyroid tissue. Fifty-six rats were individually exposed once or repeatedly (10 times in two weeks) for 30 min to 2.45 GHz radiation in a commercial chamber at different non-thermal specific absorption rates (SARs), which were calculated using the finite difference time domain technique. We used immunohistochemistry methods to study the expression of HSP-90 and morphological changes in thyroid gland tissues. Ninety minutes after radiation with the highest SAR, the central and peripheral follicles presented increased size and the thickness of the peripheral septa had decreased. Twenty-four hours after radiation, only peripheral follicles radiated at 12 W were found to be smaller. Peripheral follicles increased in size with repeated exposure at 3 W power. Morphological changes in the thyroid tissue may indicate a glandular response to acute or repeated stress from radiation in the hypothalamic–pituitary–thyroid axis. Further research is needed to determine if the effect of this physical agent over time may cause disease in the human thyroid gland.     

Regularities in forming chromosome aberrations in cattle lymphocytes in external and combined radiation exposure

Aberrations in lymphocytes of cattle blood exposed to gamma-radiation and combined radiation were found. It was shown that seven days after the exposure to doses from 64.5 to 103.3 mC/kg a number of aberration varied in the range from 16.1 to 37.7 per 100 cells, whereas a frequency of aberrated cells was from 13.5 to 29.8. After the exposure to 77.3 mC/h and the following inclusion of fused radioactive particles into the fodder (48.1-762.2 Mbq/kg of the live weight), the number of aberrations increased from 25.5 up to 55.0 per 100 cells and the number of aberrated cells increased from 21 up to 43%.     

Iodine metabolism and pathologic processes in the thyroid gland under radioiodine lesions in the regions of goitrous endemia

An existing discrepancy between the prognostic estimations and real thyroid gland sickness rate due to radiation exposure from Chernobyl is an evidence of inaccuracy of radiation doses determination. The estimation of the thyroid cancer risks is based on the assumption that the absorbed dose is uniformly distributed in the organ. But functional asynchronicity specific for iodine metabolism in thyroid may modify a space distribution of the dose. The biochemical features of the contaminated areas including iodine deficit and goitrous endemia usually are not taken into account may influence the second phase of thyroid carcinogenesis that is the promotion due to increased accumulation of some carcinogenic microelements in goitrous thyroid. In the work we consider these problems which can make significant changes in radiation risks estimation.