Threshold-like dose of local beta irradiation repeated throughout the life span of mice for induction of skin and bone tumors

The backs of female ICR mice were irradiated with beta rays from 90Sr-90Y three times a week throughout life. Previously we observed 100% tumor incidence at five different dose levels ranging from 1.5 to 11.8 Gy per exposure, but no tumor on repeated irradiation with 1.35 Gy for 300 days (Radiat. Res. 115, 488, 1988). In the present study, delay of tumor development was again seen at a dose of 1.5 Gy per exposure, with further delay at 1.0 Gy. The final tumor incidence was 100% with these two doses. At 0.75 Gy per exposure, no tumor appeared within 790 days after the start of irradiation, but one osteosarcoma and one squamous cell carcinoma did finally appear. These findings indicate a threshold-like response of tumor induction in this repeated irradiation system and further suggest that the apparent threshold may be somewhat less than 0.75 Gy per exposure.     

Proliferative activity of Shvetz tumor following single and repeated irradiation]

Autoradiographic study of an experimentally-induced tumour following local irradiation in a dose of 600 rad showed no retardation of the cell cycle 6 to 12 hours after the irradiation. Marked reduction of the mitotic index (MI) and of the labeled nuclei index (LNI) was noted to the 96th hour after the irradiation. In repeated irradiation in a dose of 1200 rad at an interval of 18 hours there was revealed a marked reduction of the MI and of the LNI as a result of the block of the passage of cells from the G1-period into S. However, restoration of the cell proliferation uas noted by the 24th-48th hours. A high MI revealed at all the periods of investigation after repeated tumour irradiation at an interval of 24 hours was possibly caused by an increase in the time of mitosis proper, this also being confirmed by a significant accumulation of the number of late mitotic phases.     

Effects of gamma irradiation and repetitive freeze-thaw cycles on the biomechanical properties of human flexor digitorum superficialis tendons

An increasing number of tissue banks have begun to focus on gamma irradiation and freeze-thaw in the reconstruction of anterior cruciate ligaments using allografts. The purpose of this study was to evaluate the biomechanical properties of human tendons after exposure to gamma radiation and repeated freeze-thaw cycles and to compare them with fresh specimens. Forty flexor digitorum superficialis tendons were surgically procured from five fresh cadavers and divided into four groups: fresh tendon, gamma irradiation, freeze-thaw and gamma irradiation+freeze-thaw. The dose of gamma irradiation was 25 kGy. Each freeze-thaw cycle consisted of freezing at -80 °C for 7 day and thawing at 25 °C for 6 h. These tendons underwent 4 freeze-thaw cycles. Biomechanical properties were analyzed during load-to-failure testing. The fresh tendons were found to be significantly different in ultimate load, stiffness and ultimate stress relative to the other three groups. The tendons of the gamma+freeze-thaw group showed a significant decrease in ultimate load, ultimate stress and stiffness compared with the other three groups. Gamma irradiation and repeated freezing-thawing (4 cycles) can change the biomechanical properties. However, no significant difference was found between these two processes on the effect of biomechanical properties. It is recommended that gamma irradiation (25 kGy) and repetitive freeze-thaw cycles (4 cycles) should not be adopted in the processing of the allograft tendons.     

Controlled surface trap state photoluminescence from CdS QDs impregnated in poly(methyl methacrylate)

A method of microwave (MW) assisted synthesis was employed to prepare cadmium sulfide (CdS) quantum dots (QDs) in dimethylformamide in the presence of poly(methyl methacrylate) (PMMA). The MW irradiation was carried out for a fixed time of 20-30 s and the size of QDs varied from 2.9-5.5 nm. Before each irradiation the solution was cooled down to ambient temperature and the irradiation process was repeated six times. An increase in the intensity and red shift of the characteristic UV-vis absorption peak originating from CdS QDs were observed with repeated MW irradiation, suggesting that the amount of generated CdS QDs increased within the PMMA network and aggregated with repeated MW irradiation. MW irradiation could influence selectively the nucleation and growing rates of PMMA-CdS QDs systems. The broadness and large Stokes shift of the emission from Cd(2+)-rich PMMA-CdS QDs was due to the surface trap state photoluminescence. The recombination of shallow trapped electrons and shallow trapped holes has been considered as the primary source of the surface trap state photoluminescence in Cd(2+)-rich PMMA-CdS QDs. The photoluminescence lifetime was observed to be decreased sharply when the amount of QDs was less, showing the emission decay was dependent on the surface property of PMMA-CdS QDs. The origin of the longer lifetime was due to the involvement of surface trap states and dependent on the amount of CdS QDs present within PMMA and its environment. The effect of the concentration of Cd(2+), S(2-) and PMMA on the generation of CdS QDs within PMMA and the effect of repeated MW irradiation on the optical properties was studied and the results are discussed in this article.     

Free thymidine in the blood serum of irradiated rats with different levels of cellular depletion of the thymus and spleen

The levels of the postirradiation thymidinemia, with an equal degree of the proceeding cell depletion of lymphoid organ tissues caused by the administration of dexamethasone and exposure of rats to 3 Gy radiation, markedly varied. Three days after the injection of the hormone, the organism responded to irradiation by an increase in the concentration of thymidine in blood serum in the same manner as intact animals did. The preirradiation with a dose of 3 Gy reduced sharply the ability of the organism to respond the repeated irradiation (after 3 days) by thymidinemia. There was a lesser increase in the thymidine concentration in the blood after the injection of dexamethasone than after irradiation inducing the same cell depletion of the thymus and spleen.     

Near-infrared theranostic photoimmunotherapy (PIT): repeated exposure of light enhances the effect of immunoconjugate

Armed antibody-based targeted molecular therapies offer the possibility of effective tumor control with a minimum of side effects. Photoimmunotherapy (PIT) employs a monoclonal antibody-phototoxic phthalocyanine dye, IR700 conjugate, that is activated by focal near-infrared (NIR) light irradiation after antibody binding to the targeted tumor cell surface leading to rapid necrotic cell death. Therapy by single NIR light irradiation was effective without significant side effects; however, recurrences were seen in most treated mice probably because of inhomogeneous distribution of panitumumab-IR700 immunoconjugate in the tumor, leading to ineffective PIT. We describe here an optimized regimen of effective PIT method for the same HER1-overexpressing tumor model (A431) with fractionated administration of panitumumab-IR700 conjugate followed by systematic repeated NIR light irradiation to the tumor based on timing of antibody redistribution into the remnant tumor under the guidance of IR700 fluorescence signal. Eighty percent of the A431 tumors were eradicated with repeated PIT without apparent side effects and survived tumor-free for more than 120 days even after stopping therapy at day 30. Therapeutic effects were monitored using IR700 fluorescent signal. PIT is a promising highly selective and clinically feasible theranostic method for treatment of mAb-binding tumors with minimal off-target effects.     

Quantitative regularities and peculiarities of the development of the cerebral form of radiation sickness at fractionated irradiation

Several peculiarities in manifestations of cerebral form of radiation sickness have been revealed at a fractionated double irradiation with equal and unequal doses per fraction and different intervals between the fractions. A reliable increase in average lifespan of rats irradiated with (100 + 100 Gy) equal doses at 10 and 60 min intervals between two fractions compared to the single radiation exposure to 200 Gy has been obtained. Lifespan of rats irradiated with a total dose greater than 200 Gy in most cases of double exposures with 10 min interval was reliably less than that for animals after a single exposure. The influence of the first dose on the reduction of animal average lifespan increased with fraction dose increasing from 150 to 300 Gy and was most pronounced at the total exposure dose of 400 Gy. Reaction of rats on the repeated irradiation was significantly weakened in comparison with the reaction on the first exposure. At a study of capacitation the interval of 30 min appeared to be more favorable compared to 10 min interval. Importance of a dose value in the first fraction has been demonstrated: the higher this value the worse the capacity of the rats 3 hours after the repeated exposure.     

Influence of repeated lyophilization on the survival ofDeinococcus proteolyticus,Micrococcus luteus andEscherichia coli

Repeated lyophilization of Deinococcus proteolyticus, Micrococcus luteus and Escherichia coli cells results in a successive decrease of their survival. The survival curve is exponential with E. coli and M. luteus, and sigmoidal with a broad shoulder with D. proteolyticus both after repeated lyophilization and after UV- or gamma-irradiation. When cells were subjected to gamma-irradiation after a 20-fold freeze-drying, the corresponding survival curve became exponential without the shoulder. Hence we assume that irradiation and repeated lyophilization afflict the same cellular structures and/or functions.     

Effect of temperature on the development of chromosome aberrations in human blood lymphocytes irradiated in pulse and continuous modes at BARS-6 reactor

Summarized results of 5 repeated experiments of comparative study of radiation effects of the pulse reactor BARS-6 either in a single pulse or a continuos irradiation mode on human lymphocytes are presented. Higher efficiency (30-40%) of continuous irradiation (exposure duration 1 h) rather than pulse irradiation with ultra-high dose rates (1-2.5) x 10(6) Gy/min (pulse duration 65 micros) was confirmed. The efficiency ratio did not depend on the temperature, 20 degrees C or 0 degrees C, during the exposure. Cell repair system and chromatin conformation influence on the results obtained is discussed.     

Excretion of cyclic nucleotides during prolonged gamma irradiation of rats

Excretion of cGMP in urine was significantly increased and cAMP/cGMP ratio decreased in rats subjected to long-term repeated gamma irradiation with cumulative doses of 15 to 20 Gy.     

Immobilization of Streptomyces phaerochromogenes by radiation-induced polymerization of glass-forming monomers.

Immobilization of Streptomyces phaerochromogenes was studied by radiation-induced polymerization of 2-hydroxyethyl methacrylate at low temperatures. Radiation damage of the enzyme could be avoided by choosing irradiation at low temperatures. The enzymatic activity of immobilized cells increased remarkably with a decrease in the irradiation temperature of about -24 degrees C. In constrast to the case of cell-free enzyme immobilization, the most characteristic case was than in these immobilized cells, the enzymatic activity did not decrease with repeated use even in the composite obtained at much lower monomer concentrations. Another characteristic of immobilized cells was the increase in enzymatic activity in the initial stage of repeated use, which could be attributed to the swelling effect of the polymer matrix, thereby increasing the enzymatic activity of whole cells.     

Phototropic Responses of Vaucheria geminata to Intermittent Blue Light Stimuli

Phototropic responses of a tip-growing coenocytic alga Vaucheria geminata to intermittent blue light pulses were analyzed. Curvatures caused by repeated light pulses separated by dark intervals of various lengths were as large as those obtained by continuous light of the same incident energy, unless the length of the dark interval exceeded a critical value of about 30 to 40 seconds. If the dark interval was longer than the critical length, bending no longer took place. Another response to intermittent irradiation was found. In a narrow range of light pulse and dark interval lengths, i.e. light pulses longer than 10 milliseconds and dark intervals shorter than a value ranging from 15 to 150 milliseconds, intermittent irradiation was more effective than continuous irradiation of the same total energy. In this region, the maximum response to repeated pulses was equal to the curvature caused by a continuous irradiation of the same total elapsed time. It is evident that in this condition the dark interval is not perceived and the alga responds as if it were in light. The results suggest that two different dark reactions may be involved in the phototropic response of this algal cell.     

HPM长期辐照的眼生物效应研究

目的：研究高功率微波（HPM）在不同平均功率和不同重复频率条件下长期多次照射对眼组织结构的生物效应,为我国HPM安全防护提供生物学依据。方法：采用自行研制的HPM效应模拟源远场平面波（峰值功率密度50W／cm^2）分3个不同平均功率水平,每天6min持续照射1个月,并在照后5个时间点通过眼底镜、裂隙灯观察、组织病理学方法等研究HPM长期照射对动物眼重要部位结构的生物效应。结果：HPM照射后眼角膜、晶状体、眼底等组织结构都出现了不同程度的病理变化,并呈现出一定的时效和量效关系;其中角膜病变依剂量不同可分别于照后2月到照后6月恢复正常,而晶状体病变在观察期内（照后6月）仍未见恢复,照射后动物眼底动静脉和毛细血管稍有扩张充血,但未见瘢痕、裂隙、出血等表现。结论：实验所用剂量范围内的HPM重复照射可以对动物角膜、晶状体、玻璃体等部位造成一定程度的生物效应,并呈现出一定的量效关系;在实验的观察期内,角膜和眼底依照射剂量不同可分别于照后不同期间恢复正常,但晶状体混浊在观察期末仍未见恢复,能否发展成微波白内障尚需观察。     

Use of 8-methoxypsoralen and light (lambda--365 nm) for studying repair in yeasts]

The lethal effect of 8-metoxypsoralen (8/MOP) plus light (lambda = 365 nm) on the haploid radioresistant and UV-sensitive strains of Saccharomyces cerevisiae was studied. The mutation uvs1 increased the sensitivity to the lethal effect of 8-MOP more than 2.8 times as compared to radioresistant strain. The method of repeated irradiation allowed to study kinetics of excision of monoadducts induced by 8-MOP. The mutant uvs1 was characterized by the absence of excision of monoadducts. The radioresistant strain removed monoadducts very efficiently (80%) after the incubation in complete liquid medium for 2.5 hours at 28 degrees before repeated irradiation. After the incubation of this strain in buffer (pH 7.0) monoadducts were removed considerably less efficiently (30%).     

Ovarian dysgerminoma, investigations on cell-and humoral-mediated immunologic reactions.

A 17-year-old girl with repeated ovarian dysgerminoma is described. Postoperative immunologic investigations prior to irradiation showed a transient increased cell--an humoral--mediated immunologic responsiveness of the patient for approximately 2 1/2 months. After irradiation, a markedly defective response to PHA was observed which improved when reexamined 11 months later. The patient is well 22 months after the second operation.     

Photochemical production of psoralen - DNA monoadducts capable of subsequent photocrosslinking.

Irradiation of 4' -aminomethyl-4,5' ,8-trimethyl psoralen in the presence of DNA at wavelengths between 380 and 400nm leads to efficient production of monoadducts with no significant amount of crosslinking. The yield of monoadduct attainable is high (about 35 adducts per 1000 base pairs) and can be made still higher by repeated irradiation with fresh psoralen derivative. Subsequent irradiation at 350nm results in crosslinking of a almost half of the monoattached psoralen. Studies of the yield of nonoadduct and crosslink as function of irradiation wavelength show that the action spectrum for crosslink formation is blue-shifted relative to that for monoadduct formation.     

Irradiation Decreases the Neuroendocrine Biomarker Pro-Opiomelanocortin in Small Cell Lung Cancer Cells In Vitro and In Vivo

Background

Small cell lung cancer (SCLC) is an extremely aggressive disease, commonly displaying therapy-resistant relapse. We have previously identified neuroendocrine and epithelial phenotypes in SCLC tumours and the neuroendocrine marker, pro-opiomelanocortin (POMC), correlated with worse overall survival in patients. However, the effect of treatment on these phenotypes is not understood. The current study aimed to determine the effect of repeated irradiation treatment on SCLC cell phenotype, focussing on the neuroendocrine marker, POMC.

Results

Human SCLC cells (DMS 79) were established as subcutaneous xenograft tumours in CBA nude mice and then exposed to repeated 2Gy irradiation. In untreated animals, POMC in the blood closely mirrored tumour growth; an ideal characteristic for a circulating biomarker. Following repeated localised irradiation in vivo, circulating POMC decreased (p< 0.01), in parallel with a decrease in tumour size, but remained low even when the tumours re-established. The excised tumours displayed reduced and distinctly heterogeneous expression of POMC compared to untreated tumours. There was no difference in the epithelial marker, cytokeratin. However, there were significantly more N-cadherin positive cells in the irradiated tumours. To investigate the tumour response to irradiation, DMS79 cells were repeatedly irradiated in vitro and the surviving cells selected. POMC expression was reduced, while mesenchymal markers N-cadherin, β1-integrin, fibroblast-specific protein 1, β-catenin and Zeb1 expression were amplified in the more irradiation-primed cells. There were no consistent changes in epithelial marker expression. Cell morphology changed dramatically with repeatedly irradiated cells displaying a more elongated shape, suggesting a switch to a more mesenchymal phenotype.

Conclusions

In summary, POMC biomarker expression and secretion were reduced in SCLC tumours which regrew after irradiation and in repeatedly irradiation (irradiation-primed) cells. Therefore, POMC was no longer predictive of tumour burden. This highlights the importance of fully evaluating biomarkers during and after therapy to assess clinical utility. Furthermore, the gain in mesenchymal characteristics in irradiated cells could be indicative of a more invasive phenotype.     

Increased Radiation Resistance of Vegetative Bacillus pumilus

A 4.5-fold increase in vegetative cell radiation resistance of Bacillus pumilus E601, the internationally recognized biological standard for irradiation sterilization, was obtained by the repeated passage of resistant survivors through successive sublethal doses of (60)Co irradiation. This increase in resistance was accompanied by a corresponding increase in spore resistance through the seventh irradiation passage. By the fifteenth passage, the ability for spore formation was lost. Other effects noted by the successive irradiation dosages included loss of motility and pellicle formation, and changes in the Gram reaction, cell morphology, and colonial morphology. Increased resistance was also accompanied by an increased nutritional requirement for specific amino acids. Radiation resistance was not transferred from vegetative cells to spores.     

Radiation resistance of animals subjected to lethal irradiation with chemical protection

The data are presented on radioresistance of mice 1, 5 and 9 months after irradiation (LD95-99/30) in conditions of protection with cystamine. It was shown that the resistance of these animals to repeated irradiation with LD50/30 is considerably lower than that of the animals not exposed previously. The radioresistance and such indices of the haemopoietic system status as quantity of caryocytes and colony-forming capacity of the bone marrow are compared.     

Some effects of radiation hormesis for bacterial and yeast cells

A comparative study of chronic and acute action of ionizing radiation on the processes of aging and dying off of bacterial and yeast cells was carried out. It was ascertained that chronic action of ionizing radiation, 2-10,000 times exceeded the natural background, resulted in slowing down of aging and dying off of both pro- and eukaryotic cells. A single acute irradiation of yeast also resulted in the retardation of dying off of the yeast cells surviving after irradiation. The data is presented demonstrating a great increase in the survival of yeast cells under their repeated irradiation after recovery from potentially lethal radiation.