The nature of the circahoralian (ultradian) intracellular rhythms. Similarity to fractals]

To evaluate the lifetime carcinogenic hazards of exposure to ionizing radiation during development, 1,680 beagles received whole-body exposures to 60Co gamma rays or sham exposures. Eight groups of 120 dogs each received mean doses of 15.6-17.5 or 80.8-88.3 cGy in early, mid- or late gestation, at 8, 28 or 55 days postcoitus or at 2 days after birth. Another group of 120 dogs received a mean dose of 82.6 cGy as 70-day-old juveniles and one group of 240 dogs received a mean dose of 81.2 cGy as 365-day-old young adults. Sham irradiations were given to 360 controls. Sexes were equally represented. In 1,343 dogs allowed to live out their life span, neoplasia was a major disease, contributing to mortality in 40% of the dogs. There was a significant increase in benign and malignant neoplasms occurring in young dogs (<4 years old), including fatal malignancies, after irradiation in the perinatal (late fetal and neonatal) periods. The lifetime incidence of fatal neoplasms was also increased in dogs irradiated perinatally. Three malignancies-lymphomas, hemangiosarcomas and mammary carcinomas-accounted for 51% of all fatal tumors. There was an apparent lifetime increase and earlier onset of lymphomas in dogs exposed as fetuses. Fatal hemangiosarcomas were increased in dogs irradiated early and late in gestation. Fatal mammary carcinomas were not increased by irradiation, although non-fatal carcinomas were increased after perinatal exposure. Myeloproliferative disorders and central nervous system astrocytomas appeared to be increased in perinatally irradiated dogs. These data suggest that irradiation in both the fetal and neonatal periods is associated with increased early onset and lifetime cancer risk.     

Effects of previous small-dose irradiation on blood reaction and survival of mice after subsequent radiation and combined radiation-thermal injuries]

CBA x C57BL6 mice pre-exposed to 5 cGy gamma-irradiation then inflicted to LD70/30 acute radiation or combined injuries (radiation + thermal burn). In such protocol of the experiments preliminary "adaptive" dose radiation did not modify low 30-day survival rate and did not render an influence to the mean survival time. Leucopenia level and bone marrow devastation in 3 days after sublethal irradiation (4 Gy) or combined injury was similar in mice pre-exposed to low dose radiation (5 cGy) and in their unexposed controls. "Adaptive" dose radiation decreased leukocytes' number within the phase of hemopoiesis recovery (in 14 day after sublethal irradiation or combined injury).     

Dose-rate dependence of heat radiosensitization

The dose rate dependence of heat radiosensitization was studied using rat astrocytoma cells in culture and a clinically relevant protocol of heat dose and heat radiation sequence. Cells were treated with a minimally toxic heat dose of 43 degrees C for 30 minutes, after which they were irradiated with varying doses of radiation at dose rates ranging from 0.567 to 300 cGy/min. This heat dose substantially reduced the extrapolation number (n), but had little effect on Do of the radiation survival curve at dose rates of 50 cGy/min or greater. At dose rates less than 10 cGy/min, 43 degrees C for 30 min had little effect on n and only for the lowest dose rate studied (0.567 cGy/min) was there a significant reduction in Do (60%). The thermal enhancement ratio did not vary inversely with radiation dose rate over the dose rate range studied but, instead, was maximal at the two dose rate extremes (0.567 and 300 cGy/min). These data demonstrate that a clinically relevant heat dose enhances very low dose rate, as well as high dose rate, ionizing radiation, but suggest that little benefit is to be gained from using dose rates intermediate between conventional radiotherapeutic high dose rates or dose rates representative of interstitial implants.     

Effect of recombinant human manganese superoxide dismutase on radiosensitivity of murine B cell leukemia (BCL1) cells

Recombinant human manganese superoxide dismutase (SOD) protects cells from oxidative damage and is known to ameliorate post-irradiation damage in mice exposed to whole body or localized chest irradiation. The concept behind the present experiments was to investigate whether it is possible to improve the outcome in leukemia following total body irradiation used as part of the conditioning prior to allogeneic bone marrow transplantation. We determined whether SOD protects leukemic cells from the effects of ionizing irradiation both in vitro and in vivo. Murine B cell leukemia (BCL1) cells, derived from tumor-bearing mice, were irradiated in vitro with or without SOD and injected into BALB/c mice. All mice receiving 10(4) unirradiated BLC1 cells developed leukemia and died within 19-39 days. In vitro exposure of BCL1 cells to 800 cGy or 1600 cGy abolished the potential to induce leukemia by inoculation with 10(4) or 10(6) BCL1 cells, respectively. Addition of SOD in vitro during irradiation increased the resistance of BCL1 cells to ionizing irradiation; all mice receiving 10(6) BCL1 cells previously exposed in vitro to 1200 cGy in the presence of SOD died of leukemia, whereas only 40% of mice receiving a similar inoculum of irradiated BCL1 cells died of leukemia. In contrast, when BCL1-bearing mice were irradiated with 600-800 cGy with or without intravenous injection of SOD (100 mg/kg) 30 minutes prior to irradiation, development of leukemia was unaffected. Residual leukemia cells following therapy were assessed by adoptive transfer of 10(5) spleen cells to secondary BALB/c recipients.(ABSTRACT TRUNCATED AT 250 WORDS)     

Perceptions of tonal changes in normal laryngeal, esophageal, and artificial laryngeal male Cantonese speakers

PURPOSE: Present radiobiological studies for different cell lines in vitro demonstrate the equivalence and efficacy of continuous low-dose-rate brachytherapy (LDR-BT) and pulsed dose rate brachytherapy (PDR-BT) when using small and frequent dose pulses. The aim of this study was to examine monolayer fibroblast cultures in vitro to examine the biological effects of different pulse doses and dose rates under clinically conditions. MATERIAL AND METHODS: B14 cells, Hy B14 FAF 28, peritoneal fibroblasts, were cultured in multi-well plates and exposed to a PDR radiation source at a distance of 9 mm. The following PDR-schemes were compared: dose per pulse: 1 Gy, 2.5 Gy and 5 Gy to a total dose of 5 Gy/5 h (overall time), 10 Gy/10 h, 20 Gy/20 h and 30 Gy/30 h. The pulse duration for the examination of dose rate effects was 20 min, 30 min or 52 min corresponding by dye pulse dose rate of 300 cGy/h, 200 cGy/h or 115 cGy/h. Treatment endpoints were cell measured by dye exclusion test and clonogenic cell survival. RESULTS: Cell survival decreased for pulse doses of 5 Gy compared to 2.5 Gy or 1 Gy per pulse (mean dose rate 200 to 300 cGy/h). No differences were observed with dose rates during irradiation of 300 cGy/h, 200 cGy/h or 115 cGy/h (20 Gy/1 Gy). CONCLUSION: Radiobiological effects of PDR-RT are dependent on the dose per pulse, with differences in biological effects only with a dose per pulse of more than 2.5 Gy, considering the described in-vitro conditions. More examinations with a more pronounced difference in dose rate will be continued for evaluation of dose rate effects.     

Use of hematopoietic cytokines to accelerate the recovery of the immune system in irradiated mice

In our previous studies aimed at designing appropriate strategies to accelerate recovery of the immune system after irradiation, we found that the hematopoietic cytokine recombinant murine (rmu) interleukin (IL)-3 was able to induce differentiation and growth of thymocytes and splenic T and B lymphocytes in mice exposed to x-rays (200-500 cGy). The recovery, however, was complete at 7 days only after a dose of 200 cGy, whereas 2, 3, and 4 weeks were necessary to achieve full recovery after 300, 400, and 500 cGy, respectively. These studies were extended to investigate the effects of another hematopoietic cytokine, recombinant human (rhu) IL-11, a bone marrow stromal-derived cytokine, administered together with IL-3 to irradiated mice. The synergistic effect of the two cytokines was evident when relatively small doses of rhu IL-11 were injected with an optimal dose of rmu IL-3.     

Hypersensitivity following low one-time irradiation dosage and induced radio resistance

There is now little doubt of the existence of radioprotective mechanisms, or stress responses, that are upregulated in response to exposure with small doses of ionizing radiation and other DNA-damaging agents. Phenomenologically, there are two ways in which these induced mechanisms operate. First, a small conditioning dose (generally below 30 cGy) may protect against a subsequent, separate irradiation. This has been termed the adaptive response. Second, the response to single doses may itself be dose-dependent so that small acute radiation exposures are more effective per unit dose than larger exposures above the threshold where the induced radioprotection is triggered. This combination has been termed low dose hypersensitivity (HRS) and induced radioresistance (IRR) as the dose increases. Both the adaptive response and HRS/IRR have been well documented in studies with yeast, bacteria, protozoa, algae, higher plant cells, insect cells, mammalian and human cells in vitro, and in studies on animal models in vivo. There is indirect evidence that the adaptive response and the IRR phenomenon in response to single doses is a manifestation of the same underlying mechanisms, namely an increase of the amount and rate of DNA repair induced by low radiation doses.     

Radioprotective effects of diltiazem on cytogenetic damage and survival in gamma ray exposed mice

Diltiazem, a calcium ion channel blocker, already in use in cardiovascular therapeutics, has been observed to protect against bone marrow damage (cytogenetic damage, cell death) and mortality in whole body irradiated mice. The micronuclei fraction in bone marrow cells of whole body irradiated (60Co gamma rays, 2.0 Gy) mice was reduced from 2.24 +/- 0.23% to about 0.74 +/- 0.33% by preirradiation administration (-20 min) of 110 mg/kg body wt. diltiazem (ip). Endogenous colony forming unit counts in spleen of mice administered 110 mg/kg body wt. (-20 min) of diltiazem before 10 Gy whole body irradiation were 6 times more than untreated irradiated controls. Pretreatment with diltiazem accelerated the recovery of radiation induced weight loss also. Diltiazem (110 mg/kg body wt, -20 min) enhanced 30 day survival to about 95% and 85% after lethal whole body absorbed dose of 9 and 10 Gy respectively and also mitigated radiation induced life- span shortening. Post-irradiation (10 Gy) administration of diltiazem (+20 to 30 min) enhanced survival from about 2 to 15% only but was highly significant (P < 0.001). Possible modes of radioprotective action of diltiazem have been discussed.     

Toxicity of precocene II in rat hepatocyte cultures: effects of serum and culture time

The embryotoxic effects of neutron radiation on rodent embryos are documented, but there is disagreement about the dose-response relationship and the impact of protracting the dose. Pregnant rats were exposed to total absorbed doses of 0.15 to 1.50 Gy 14.1 MeV neutrons on day 9.5 after conception, coincident with the most sensitive stage of embryonic development for the induction of major congenital malformations. In general terms, the incidence of embryotoxic effects increased with increasing total absorbed dose. However, the dose-response relationship differed depending on the parameter of embryotoxicity chosen, namely, intrauterine death, malformations or very low body weight. In a second study, embryos were exposed to a single embryotoxic absorbed dose (0.75 Gy) administered at a range of dose rates, from 0.10 to 0.50 Gy/h. The results offer no evidence that protraction of this selected dose significantly increased or decreased the incidence or pattern of embryotoxicity of the neutron exposure used in this study. The results do not support the hypothesis of a linear dose-response relationship for the effects of prenatal neutron irradiation that contribute to embryotoxicity for total absorbed doses of 0.15 to 1.50 Gy.     

Comparative dynamics of elimination of potential chromosome damage in mouse bone marrow cells after low and moderate doses of radiation

Possible dynamics of the incidence, repair, and realization of potential chromosome aberrations (PAs) was examined by indirect methods based on cytogenetic analysis of radiation effects. PAs were characterized as chemical modifications of DNA responsible for the incidence of structural aberrations of chromosomes. We interpreted our data as providing evidence that two types of radiation-induced PAs, differing in repair rates, could occur in the exposed cells: quick- (short-term) and slow (long-term) repairing PAs. We showed that the PA spectrum gradually changed with an increase in radiation dose within the interval from 24 to 150 cGy. This process was paralleled by changes in the cell response and chromosome resistance to radiation. Short-term PAs were induced mainly by low radiation doses ranging from 24 to 75 cGy. Their incidence was associated with activation of the corresponding repair process. Further increase in radiation dose resulted in changes in the PA spectrum, and doses of 150 cGy induced predominantly long-term PAs with concomitant activation of the appropriate repair process. Induction of repair occurred in the dose intervals limited by lower and upper threshold doses, Dl and Du. In our experiments, short-term PAs were repaired when Dl < 24 cGy and 126 cGy < Du < < 150 cGy. Long-term PAs were repaired when 75 cGy < Dl < 99 cGy and Du > 150 cGy.     

Effects of ionizing radiation on proliferation and differentiation of osteoblast-like cells

Diagnostic radiation for immediate post-surgical assessment of osseointegrated dental implants has been discouraged, due to the possibility of detrimental effects of ionizing radiation on healing and remodeling of bone. To assess this possibility, we investigated the effects of ionizing radiation on proliferation and differentiation of osteoblasts using osteoblast-like cells isolated from the calvariae of newborn rats (ROB) and a clonal osteoblastic cell line (MC3T3-E1). The cells were exposed on day 3 to a single dose of x-rays at either 40, 100, 400, or 4000 mGy, respectively, from a linear accelerator radiotherapeutic machine (Linac) or a 40-mGy dose from a diagnostic chest x-ray machine. The effects of radiation on cell growth and alkaline-phosphatase-specific (ALP) activity were evaluated at three-day intervals after irradiation up to day 12 in ROB cells, and evaluated at day 12 in MC3T3-E1 cells. At the culture end-point, the effects on formation of bone-like nodules were also evaluated in both ROB and MC3T3-E1 cells. Exposure of 4000 mGy differentially affected the two cell types. It inhibited cell growth and alkaline phosphatase activity, and inhibited DNA content in MC3T3-E1 cells. This irradiation also strongly inhibited the formation of bone-like nodules in ROB cells. On the other hand, exposure of 40-, 100-, and 400-mGy (Linac) and 40-mGy (diagnostic quality) irradiation induced no significant changes in cell growth, alkaline phosphatase activity, and formation of bone-like nodules in ROB cells. These doses also induced no significant changes in DNA content and ALP activity in MC3T3-E1 cells. These results indicate that ionizing radiation at a single dose of up to 400 mGy induces no significant changes in cell growth and differentiation of osteoblast-like cells, at least in vitro. Higher radiation doses (4000 mGy) may exert different effects on cell proliferation and cell differentiation of osteoblasts, depending on the cell types affected. Thus, diagnostic radiation seems to have less effect on proliferation and differentiation of osteoblasts.     

Pulmonary and cardiac late effects of ionizing radiations alone or combined with chemotherapy

High doses of ionizing radiation (> 40 Gy) cause severe lung fibrosis in approximately 5% of the cases. There is a twofold increase when chemotherapy is added to ionizing radiation. Lung fibrosis is due to the destruction of lung tissue by ionizing radiation but also to various cytokine effects (PDGF-beta, TGF-beta). Only a minority of patients (approximately 10%) with abnormal X-rays will experience clinical symptoms. The most important radiobiological parameters which accounts for pulmonary tolerance is the fraction size. Irradiation of the heart begets multifarious late sequelae which are often left unrecognized. Chronic pericarditis affects approximately 5% of the patients when the irradiation dose exceeds 40 Gy. Coronary artery disease can be diagnosed in 5 to 10% of the patients. This late complication is more likely to occur if the patient was young at the time of the irradiation or if other risk factors are associated. Valvular defects can be found in 15 to 30% of the patients. However, the mortality rate is very low (0.5%). Finally, conduction defects can also be seen in approximately 5% of the patients. It is very likely that the radiation dose given to the heart should not exceed 30 Gy if late sequelae are to be avoided.     

Tc-99m tetrofosmin myocardial perfusion SPECT after dipyridamole combined with low-level exercise in the diagnosis of coronary artery disease

Thymic lymphoma (TL) was observed in different stages of development in 46% of male mice (23/50) following exposure to an acute challenge dose of 2 Gy 60Co gamma-rays. With an adapting dose of 1 cGy 24 h prior to the challenge dose of 2 Gy, similar growth of TL was seen in 42.5% of mice (17/40). TL was not found in unirradiated control mice (0/50) or in the group treated with 1 cGy (0/50). Multiple adapting doses for 5 or 10 consecutive days induced TL in 8/50 and 9/50 mice, respectively (17% in average). When multiple adapting doses were followed by the challenge dose, the yield of TL was much lower, 16% (8/50) and 30% (15/50), respectively. By 15, 30, 60, 90, and 120 days after exposure with 3 Gy of 60Co gamma-rays, TL developed in 30, 70, 70, 80 and 85% of the female mice, respectively. When mice were conditioned with an adapting dose of 1 cGy 24 h prior to the challenge dose, TL was not found 15 days post-irradiation, while about a 25% reduction in the occurrence of TL was noticed at all other intervals. The results suggested that an adapting dose could play a role in bringing about a change in terms of delay and inhibition of the acute effects of radiation, i.e., the onset of TL in mice.     

Induction of acute phase gene expression by brain irradiation

PURPOSE: To investigate the in vivo acute phase molecular response of the brain to ionizing radiation. METHODS AND MATERIALS: C3Hf/Sed/Kam mice were given midbrain or whole-body irradiation. Cerebral expression of interleukins (IL-1 alpha, IL-1 beta, IL-2, IL-3, IL-4, IL-5, IL-6), interferon (IFN-gamma), tumor necrosis factors (TNF-alpha and TNF-beta), intercellular adhesion molecule-1 (ICAM-1), inducible nitric oxide synthetase (iNOS), von Willebrand factor (vWF), alpha 1-antichymotrypsin (EB22/5.3), and glial fibrillary acidic protein (GFAP) was measured at various times after various radiation doses by ribonuclease (RNase) protection assay. The effects of dexamethasone or pentoxifylline treatment of mice on radiation-induced gene expression were also examined. RESULTS: Levels of TNF-alpha, IL-1 beta, ICAM-1, EB22/5.3 and to a lesser extent IL-1 alpha and GFAP, messenger RNA were increased in the brain after irradiation, whether the dose was delivered to the whole body or only to the midbrain. Responses were radiation dose dependent, but were not found below 7 Gy; the exception being ICAM-1, which was increased by doses as low as 2 Gy. Most responses were rapid, peaking within 4-8 h, but antichymotrypsin and GFAP responses were delayed and still elevated at 24 h, by which time the others had subsided. Pretreatment of mice with dexamethasone or pentoxifylline suppressed radiation-induced gene expression, either partially or completely. Dexamethasone was more inhibitory than pentoxifylline at the doses chosen. CONCLUSIONS: The initial response of the brain to irradiation involves expression of inflammatory gene products, which are probably responsible for clinically observed early symptoms of brain radiotherapy. This mechanism explains the beneficial effects of the clinical use of steroids in such circumstances.     

Prevention of radiation induced taste aversion in rats

Diltiazem, a calcium channel blocker, and a cardiovascular therapeutic agent offers significant protection to mice against lethal dose of ionizing radiation. Considering the potential efficacy of diltiazem as a radioprotector for human use, it was deemed necessary to investigate its influence on radiation-induced behavioural changes like nausea, vomiting, learning, memory and performance. In the present studies, conditioned taste aversion (CTA) test based on consumption of saccharin solution, was used as a marker of behavioural changes. Significant CTA (97 +/- 2%) was observed in rats irradiated with Co-60 gamma rays (absorbed dose 1 Gy). Administration of diltiazem at doses greater than 10 mg/kg, body wt, evoked CTA in a dose-dependent manner and that was found to be further aggravated on irradiation. At a lower dose of 5 mg/kg, body wt, diltiazem did not evoke CTA and protected against radiation induced aversion significantly (62 +/- 3%). The results suggest that diltiazem at concentrations lower than 10 mg/kg, body wt, in rats may be useful in preventing radiation induced behavioural changes. This observation could be of particular significance in clinical radiotherapy where radiation induced nausea and vomiting are of great concern.     

The Peperomia mitochondrial coxI group I intron: timing of horizontal transfer and subsequent evolution of the intron

PURPOSE: To review the results of recent studies on radiation-induced germline instability at mammalian minisatellite loci. RESULTS: Evidence has been obtained recently that germline mutation at minisatellites is remarkably sensitive to ionizing radiation, in both mice and humans. In mice, an elevated mutation rate was found after acute irradiation of pre-meiotic spermatogonia, with a doubling dose of 0.33 Gy, a value close to those obtained in mice after acute spermatogonia irradiation using other systems for mutation detection. In humans, analysis of germline mutation rate at minisatellites among children born in areas of the Mogilev district of Belarus, which was heavily polluted after the Chernobyl accident, has shown a twofold higher mutation rate in exposed families compared with non-irradiated families from the United Kingdom. Within the Belarus cohort, the mutation rate was significantly greater in families exposed to a higher parental radiation dose, consistent with radiation induction of germline mutation. The data in this study also demonstrate the indirect nature of radiation-induced germline mutation at mammalian minisatellite loci suggesting a strong similarity with the phenomenon of genomic instability in somatic cells. CONCLUSIONS: Minisatellite loci provide a powerful system for the efficient monitoring of germline mutation in humans and are capable of detecting induced mutations in relatively small population samples.     

Synergism and interference in the combined biological action of ionizing and SHF radiation

In experiments with 933 (CBA x C57Bl)F1 mice it has been found that with any variant of alternation and sequence of single ionizing and SHF irradiation with lethal doses, the radiation affection caused by gamma quanta is aggravated. Preirradiation with gamma or SHF radiation ameliorates the severity of the affection caused by the subsequent SHF radiation. Parenteral injection of colloidal sulfur 60 min before SHF radiation causes a 2-5-fold increase in the survival rate of exposed and protected mice as compared to unprotected animals.     

Rate-dependent, nonlinear photoablation of ocular tissue at 308 nm

Alpha-difluoromethylornithine (DFMO) was used to reduce 125I-induced brain injury in normal beagle dogs. Different DFMO doses and administration schedules were used to determine if the reduction in brain injury was dependent on dose and/or dependent upon when the drug was administered relative to the radiation treatment. Doses of DFMO of 75 mg/kg/day and 37.5 mg/kg/day given 2 days before, during and for 14 days after irradiation reduced levels of putrescine (PU) in the cerebrospinal fluid relative to controls. Volume of edema was significantly reduced by 75 mg/kg/day of DFMO before, during and after irradiation and by the same dose when the drug was started immediately after irradiation. A reduction in edema volume after 37.5 mg/kg/day before, during and after irradiation was very near significance. Ultrafast CT studies performed on dogs that received a DFMO dose of 75 mg/kg/day before, during and after irradiation suggested that the reduced edema volume was associated with reduced vascular permeability. Volume of necrosis and volume of contrast enhancement (breakdown of the blood-brain barrier) were significantly lower than controls only after a DFMO dose of 75 mg/kg/day before, during and after irradiation. These latter data, coupled with the findings relative to edema, suggest that different mechanisms may be involved with respect to the effects of DFMO on brain injury, or that the extents of edema, necrosis and breakdown of the blood-brain barrier may depend upon different levels of polyamine depletion. The precise mechanisms by which DFMO exerts the effects observed here need to be determined.