Nano-Scale Residual Stress Profiling in Thin Multilayer Films with Non-Equibiaxial Stress State.

Silver-based low-emissivity (low-E) coatings are applied on architectural glazing to cost-effectively reduce heat losses, as they generally consist of dielectric/Ag/dielectric multilayer stacks, where the thin Ag layer reflects long wavelength infrared (IR), while the dielectric layers both protect the Ag and act as an anti-reflective barrier. The architecture of the multilayer stack influences its mechanical properties and it is strongly dependent on the residual stress distribution in the stack. Residual stress evaluation by combining focused ion beam (FIB) milling and digital image correlation (DIC), using the micro-ring core configuration (FIB-DIC), offers micron-scale lateral resolution and provides information about the residual stress variation with depth, i.e., it allows depth profiling for both equibiaxial and non-equibiaxial stress distributions and hence can be effectively used to characterize low-E coatings. In this work, we propose an innovative approach to improve the depth resolution and surface sensitivity for residual stress depth profiling in the case of ultra-thin as-deposited and post-deposition annealed Si3N4/Ag/ZnO low-E coatings, by considering different fractions of area for DIC strain analysis and accordingly developing a unique influence function to maintain the sensitivity of the technique at is maximum during the calculation. Residual stress measurements performed using this novel FIB-DIC approach revealed that the individual Si3N4/ZnO layers in the multilayer stack are under different amounts of compressive stresses. The magnitude and orientation of these stresses changes significantly after heat treatment and provides a clear explanation for the observed differences in terms of scratch critical load. The results show that the proposed FIB-DIC combined-areas approach is a unique method for accurately probing non-equibiaxial residual stresses with nano-scale resolution in thin films, including multilayers.

Ionizing radiation-induced gene modulations, cytokine content changes and telomere shortening in mouse fetuses exhibiting forelimb defects.

Several lines of evidence have linked limb teratogenesis to radiation-induced apoptosis and to the p53 status in murine fetuses. In previous reports, we studied the occurrence of various malformations after intrauterine irradiation and showed that these malformations were modulated by p53-deficiency as well as by the developmental stage at which embryos were irradiated. In this new study, we focused onto one particular phenotype namely forelimb defects to further unravel the cellular and molecular mechanisms underlying this malformation. We measured various parameters expected to be directly or indirectly influenced by irradiation damage. The mouse fetuses were irradiated at day 12 p.c. (post conception) and examined for forelimb defects on gestational days 15, 16, 17 and 19 of development. The release of inflammatory cytokines was determined in the amniotic fluid on day 16 p.c. and the mean telomere lengths assessed at days 12, 13 and 19 p.c. Differential gene expression within the forelimb bud tissues was determined using Real Time quantitative PCR (RTqPCR) 24 h following irradiation. Apoptosis was investigated in the normal and malformed fetuses using the TUNEL assay and RTqPCR. First, we found that irradiated fetuses with forelimb defects displayed excessive apoptosis in the predigital regions. Besides, overexpression of the pro-apoptotic Bax gene indicates a mitochondrial-mediated cell death. Secondly, our results showed overexpression of MKK3 and MKK7 (members of the stress-activated MAP kinase family) within the malformed fetuses. The latter could be involved in radiation-induced apoptosis through activation of the p38 and JNK pathways. Thirdly, we found that irradiated fetuses exhibiting forelimb defects showed a marked telomere shortening. Interestingly, telomere shortening was observed as the malformations became apparent. Fourthly, we measured cytokine levels in the amniotic fluid and detected a considerable inflammatory reaction among the irradiated fetuses as evidenced by the increase in pro-inflammatory cytokine levels. Altogether, our data suggest that transcriptional modulations of apoptotic, inflammation, stress, and DNA damage players are early events in radiation-induced forelimb defects. These changes resulted in harsh developmental conditions as indicated by a marked increase in cytokine levels in the amniotic fluid and telomere shortening, two features concomitant with the onset of the forelimb defect phenotype in our study.

Studies on the adaptive response in mouse female germ cells X-irradiated in vitro at two different stages of maturation.

BACKGROUND: Radioadaptation is a phenomenon whereby cells exposed to a low dose of ionizing radiation are more resistant to a much higher dose delivered some time thereafter. This phenomenon could result from the activation of damage repair and/or antioxidant defense systems by the low dose. MATERIALS AND METHODS: The existence of a cytogenetic adaptive response in female germ cells was investigated using a recently developed in vitro system. Mouse ovarian follicles were cultured from an early preantral stage up to ovulation. The follicles were X-irradiated with either 2 or 4 Gy ("challenge dose") preceded or not by 50 mGy ("conditioning dose", 5 h earlier), on days 0 or 12 of the culture. Ovulated oocytes were collected on day 13, fixed and analyzed for the presence of chromosome aberrations. RESULTS: Irradiation with 2 or 4 Gy on days 0 or 12 did not influence ovulation but had dose-dependent effects on the germinal vesicle breakdown of the oocytes. It also caused dose-dependent chromosome damage, with a greater sensitivity of oocytes to this effect when irradiation occurred on day 12 than on day 0. Prior irradiation of oocytes with the dose of 50 mGy led to a reduction in the yield of chromosome aberrations when irradiation occurred on day 12 but not on day 0. CONCLUSION: These results suggest that pre-irradiation of mouse pre-ovulatory oocytes with a low conditioning dose could confer on them some protection against radiation-induced chromosomal damage by a subsequent challenge dose of a few Gy.

Histone H1 and cdk1 kinase activities in early embryos of four mouse strains after X-irradiation.

The cdk1/cyclin B1 complex is a universal regulator known to be responsible for driving the cell-cycle from the G2- to the M-phase. To investigate the effects of irradiation on the activity of this complex in preimplantation embryos, we irradiated one- and two-cell mouse embryos with X-rays, and measured the fluctuations of histone H1 and cdk1 kinase activity. Four mouse strains with different radiation sensitivities were chosen: the BALB/c and the Heiligenberger (radiation-sensitive) and the C57BL and the CF1 (radiation-resistant) strains. Embryos irradiated in the first cell-cycle arrested in the G2-phase. However, the dynamics of this radiation-induced G2-block were different between the mouse strains tested. Indeed, in the C57BL and the CF1 strains, X-irradiation with 2.5 Gy induced a very short G2 block before the one-cell embryos could then proceed to mitosis. On the contrary, X-irradiation in BALB/c induced a G2-arrest that lasted about 20 h, with the percentage of embryos blocked in G2 depending on the dose, whilst in the Heiligenberger strain, all irradiated embryos developed a G2-block, which was dependent in duration on the radiation dose. In all mouse strains, the histone H1 kinase activity remained low during the G2 arrest, while it showed values comparable to that of control embryos during mitosis. X-irradiation is known to induce a change in the phosphorylation state of the cdk1 protein kinase in adult somatic cells. In embryos from the BALB/c and C57BL strains, the histone H1 kinase activities were confirmed by the cdk1 phosphorylation pattern: the inactive and phosphorylated form of cdk1 was observed in G2 arrested 1-cell embryos, while the active and dephosphorylated form of cdk1 was present in dividing control and irradiated 1-cell embryos. X-irradiation at the 2-cell stage only induced a short G2-arrest in all tested mouse strains. In conclusion, cell-cycle effects in early embryos under normal conditions and after irradiation are strictly paralleled by changes in the activity of the central cell-cycle driving enzyme complex.

Intracellular signal transduction in mouse oocytes and irradiated early embryos.

In order to determine the effect of X-irradiation on intracellular signal transduction in mouse oocytes and embryos, JNK, ERK and p38 kinase activities were measured by the state of phosphorylation of their respective substrates (c-Jun, Elk-1 and ATF-2, respectively) in two mouse strains differing in radiation sensitivity, namely C57BL and BALB/c. In a first step, control oocytes and embryos were compared for their respective kinase activities at various stages of oocyte maturation (germinal vesicle and metaphases of 1st and 2nd meiosis stages) and early embryonic development (1-, 2-, 4-, 8- and 16-cell, morula and blastula stages). Levels of p38, ERK or JNK kinase activities were shown to vary with the stage of oocyte maturation and embryo development. In a second step, 1- and 2-cell embryos were X-irradiated with 2.5 Gy during the S-phase of the 1st or the 2nd cell-cycle, respectively. There were no significant differences in p38, ERK and JNK kinase activities between control and irradiated embryos, whatever the stage or mouse strain was considered. In conclusion, p38, ERK and JNK kinase activities were shown to vary during oocyte maturation and early embryonic development. Apparently, X-irradiation did not affect these kinase activities at the 1- and 2-cell stages in either mouse strains regardless of their difference in radiation sensitivity.

Telomere shortening is associated with malformation in p53-deficient mice after irradiation during specific stages of development.

The natural ends of linear chromosomes, the telomeres, recruit specific proteins in the formation of protective caps that preserve the integrity of the genome. Unprotected chromosomes induce DNA damage checkpoint cascades and ultimately lead to senescence both in mouse and man in a p53 dependent manner and initial telomere length setting therefore determines the proliferative capacity of each cell. Yet, only little information is available on telomere biology during embryonic development. We have previously shown that the p53 gene plays a crucial role in the development of malformations (exencephaly, gastroschisis, polydactyly, cleft palate and dwarfism) in control and irradiated mouse embryos. Here, we investigated telomere biology and the outcome of radiation exposure in wild type (p53+/+) and p53-mutant (p53+/-- and--/--) C57BL mouse foetuses irradiated at three different developmental stages. We show that telomeres are significantly shorter in malformed foetuses as compared to normal counterparts. In addition, our results indicate that the observed telomere attrition is primarily associated with p53-deficiency but is also modulated by irradiation, more specifically during the gastrulation and organogenesis stages. In conclusion, we formulate a hypothesis in which telomere shortening is linked to the absence of p53 in mouse foetuses and that when, in the presence of shorter telomeres, these foetuses are irradiated, the chance for the occurrence of developmental defects increases substantially.

Increased radiation sensitivity of an eosinophilic cell line following treatment with epigallocatechin-gallate, resveratrol and curcuma.

Ionizing radiation is widely used in radiotherapy, in order to promote an apoptotic response in cancerous cells. Since the need to find new substances that would enhance the radiation-induced apoptosis in cancerous cells is great, we studied the effect of epigallocatechin-gallate (EGCG, a tea component), resveratrol (a wine component) and curcuma on cell proliferation and radiation-induced apoptosis in the human leukaemic cell line, EOL-1, derived from a patient with eosinophilic leukaemia. Cells were X-irradiated with 0, 2, 4, 6 or 8 Gy and cultured in the presence of EGCG, resveratrol or curcuma (concentrations ranging from 0 to 200 microM) for 1, 2 or 3 days of culture. Cell proliferation was measured using trypan blue exclusion. Apoptosis was evaluated using light microscopy (morphology study after May-Grunwald Giemsa staining) and flow cytometry (annexin-V staining). Irradiation alone induced a dose-related reduction in cell proliferation and the appearance of polyploid cells in EOL-1 cells. Additionally, EOL-1 cells underwent a dose-related increase of apoptosis which, from the second day on, was accompanied by a dose-related increase of necrosis. When cells were exposed to EGCG, resveratrol or curcuma alone, a decrease in cell proliferation was observed, beginning from 25 microM EGCG and 50 microM resveratrol and curcuma, while an increase in the percentage of apoptotic cells was noted from 50 microM EGCG, 100 microM resveratrol and curcuma in EOL-1 cells, after only one day of culture. Simultaneous exposure to X-irradiation and, EGCG, resveratrol or curcuma resulted in a synergistic decrease of cell proliferation as well as in a synergistic increase of apoptosis and necrosis. These results suggest that, depending on the concentration, EGCG, resveratrol and curcuma enhance radiation-induced apoptosis in the leukaemic cell line, EOL-1 (EGCG >resveratrol >curcuma). In order to further characterise the radiation-induced apoptosis of this leukaemic cell line, other flow cytometrical analyses are in progress.

Radiation sensitivity of the gastrula-stage embryo: Chromosome aberrations and mutation induction in lacZ transgenic mice: The roles of DNA double-strand break repair systems.

At the gastrula phase of development, just after the onset of implantation, the embryo proper is characterized by extremely rapid cell proliferation. The importance of DNA repair is illustrated by embryonic lethality at this stage after ablation of the genes involved. Insight into mutation induction is called for by the fact that women often do not realize they are pregnant, shortly after implantation, a circumstance which may have important consequences when women are subjected to medical imaging using ionizing radiation. We screened gastrula embryos for DNA synthesis, nuclear morphology, growth, and chromosome aberrations (CA) shortly after irradiation with doses up to 2.5Gy. In order to obtain an insight into the importance of DNA repair for CA induction, we included mutants for the non-homologous end joining (NHEJ) and homologous recombination repair (HRR) pathways, as well as Parp1-/- and p53+/- embryos. With the pUR288 shuttle vector assay, we determined the radiation sensitivity for point mutations and small deletions detected in young adults. We found increased numbers of abnormal nuclei 5h after irradiation; an indication of disturbed development was also observed around this time. Chromosome aberrations 7h after irradiation arose in all genotypes and were mainly of the chromatid type, in agreement with a cell cycle dominated by S-phase. Increased frequencies of CA were found for NHEJ and HR mutants. Gastrula embryos are unusual in that they are low in exchange induction, even after compromised HR. Gastrula embryos were radiation sensitive in the pUR288 shuttle vector assay, giving the highest mutation induction ever reported for this genetic toxicology model. On theoretical grounds, a delayed radiation response must be involved. The compromised developmental profile after doses up to 2.5Gy likely is caused by both apoptosis and later cell death due to large deletions. Our data indicate a distinct radiation-sensitive profile of gastrula embryos, including some stage-specific aspects that are not as yet understood.

Study of the combined effect of X-irradiation and epigallocatechin-gallate (a tea component) on the growth inhibition and induction of apoptosis in human cancer cell lines.

Over the past 15 years, some potential anticarcinogenic and anti-inflammatory effects of antioxidants have been defined. Antioxidants are known to act as powerful free-radical scavengers. Free radicals are able to induce DNA strand breaks and oxidative modifications of DNA bases and are not only produced naturally in the cell following a stress or respiration but also following ionizing radiation. The present study was undertaken in order to explore whether some antioxidants naturally present in the food or in the beverages could enhance apoptosis in cancerous cells submitted to X-irradiation. Epigallocatechin gallate (EGCG), a potent antioxidant present in tea was tested on three human cancerous cell lines: HeLa (derived from cervix carcinoma), K-562 (derived from chronic myelogenous leukaemia) and IM-9 (derived from multiple myeloma). The parameters investigated were cell proliferation, morphological changes, cell cycle effects and apoptosis. When given alone, irradiation induced a decrease of cell proliferation and an increase of apoptosis as well as the appearance of polyploid cells in the three cell lines. All these effects were dose-dependent. Taking into account the various parameters, IM-9 cells appeared as the most radiation sensitive and HeLa cells as the least radiation sensitive, while K-562 cells exhibited an intermediary radiation sensitivity. EGCG had no effect on cell proliferation, while it induced a dose-dependent increase of apoptosis in the three cell lines. IM-9 cells were again most sensitive to this effect, while HeLa and K-562 cells were slightly less sensitive. A combined treatment by X-irradiation and EGCG resulted in a significant enhancement of apoptosis correlated with a decrease of proliferation in IM-9 and K-562 cells and at a lesser extent, in HeLa cells, compared to treatments by either EGCG or ionising radiation alone. In conclusion, these preliminary results show that depending on the concentration and on the cell line, EGCG could act as a radiation enhancer on cancerous cell lines.

Enhanced radiation-induced apoptosis of cancer cell lines after treatment with resveratrol.

A search for new agents that can sensitise cancer cells to ionising radiation is of continual interest and mainly due to the use of radiation in cancer therapy. Resveratrol, a powerful antioxidant has been shown to inhibit carcinogenesis in animal models. The purpose of this study was to examine whether resveratrol can sensitise cancer cells to X-irradiation. The human cancer cell lines examined were HELA (cervix carcinoma), K-562 (chronic myeloid leukemia) and IM-9 (multiple myeloma). The assays that were performed following X-irradiation (doses from 0 to 8 Gy) and/or incubation in the presence of resveratrol (concentrations ranging from 0 to 200 microM), were the following: trypan blue exclusion test to determine cell viability, cell morphology after May-Grunwald Giemsa staining, DNA profile analysis by flow cytometry to assess cell cycle distribution and the presence of the sub-G1 peak. The cell lines showed different radiation sensitivity (IM-9, high radiation sensitivity, K-562, intermediate radiation sensitivity and HELA, low radiation sensitivity) as seen by the X-irradiation dose related inhibition of cell growth and induction of apoptosis. The addition of resveratrol alone to the cell cultures induced apoptosis and inhibited cell growth from 50 (IM-9), 100 (EOL-1) or 200 microM (HELA) resveratrol concentrations. Concomitant treatment of the cells with either resveratrol and X-irradiation induced a synergical effect at the highest dose of 200 microM. These results show that resveratrol can act as a potential radiation sensitiser at high concentrations. Further studies need to address the toxicity of resveratrol on normal cells.

Developmental abnormalities induced by X-irradiation in p53 deficient mice.

In order to assess the influence of p53 inactivation on radiation-induced developmental effects, male mice heterozygous for the wild-type p53 allele (mimicking the human Li-Fraumeni syndrome) were crossed with C57BL females, and their heterozygous p53+/- progeny were mated with each other to obtain p53+/-, p53-/- and p53+/+ embryos. Pregnant females were X-irradiated with 0.5 Gy on days 1 (pre-implantation period), 8 or 11 (organogenesis period) of gestation. Dissection of the pregnant females occurred on day 19 of gestation. The p53 genotype of the foetuses was determined by PCR from small pieces of soft tissues. Exencephaly was the only external malformation found in the control group. It affected essentially p53-/- female foetuses. A number of p53+/- and p53+/- control foetuses also showed dwarfism, or underdevelopment. In the group irradiated on day 1, the frequency of abnormal foetuses was, paradoxically, lower than that found in the control group. As in that group, exencephaly and dwarfism constituted the only anomalies that were found. Exencephaly affected only homozygous p53-/- females, while dwarfism concerned either p53-/- or p53+/- foetuses, with a majority of females. Irradiation on day 8 of gestation induced a significant increase in the frequency of abnormal foetuses, compared to the control group. Various malformations were observed in addition to exencephaly, including gastroschisis, polydactyly, cephalic oedema and cleft palate. All malformed foetuses were either homozygous p53-/- or heterozygous p53+/- while most affected foetuses were females, as was the case for dwarf individuals. Irradiation on day 11 did not cause an increase in the frequency of abnormal foetuses, in comparison with the controls. However, a large spectrum of external malformations was again noticed, as in the group irradiated on day 8. All affected foetuses were homozygous p53-/- and there were slightly more abnormal females than males (3 out of 5). No dwarfs were found in this group. Overall, these results confirm the importance of the p53 tumour-suppressor protein for normal embryonic development. They clearly show that homozygous p53-/- (or heterozygous p53+/- to a lesser extent) foetuses are more at risk for radiation-induction of external malformations during the organogenesis period, and that the risk of developing such malformations is much higher for females than for males. In contrast to results published very recently by others, we found that malformed foetuses resulting from an X-irradiation with a low-dose during the highly sensitive period of gastrulation are able to survive to birth.

Simulated microgravity decreases apoptosis in fetal fibroblasts.

Space travel is a major challenge for human beings. Especially, the mechanisms through which space conditions might alter animal development have been questioned for a long time. The two major physical stress factors that are of relevance in this context are space radiation and weightlessness. While it has been extensively shown that high doses of ionizing radiation induce deleterious effects on embryonic development, so far, little is known about the potential harmful effects of radiation in combination with microgravity on the developing organism. In the present study, we investigated the effects of simulated microgravity on irradiated STO mouse fetal fibroblast cells using a random positioning machine (RPM). Radiation-induced cell cycle changes were not affected when cells were subjected to simulated microgravity for 24 h. Moreover, no morphological differences were observed in irradiated samples exposed to simulated microgravity compared to cells that were exclusively irradiated. However, microgravity simulation significantly decreased the level of apoptosis at all doses as measured by caspase-3 activity and it prevented cells from undergoing radiation-induced size increase up to 1 Gy.

X-irradiation induces cell death in fetal fibroblasts.

The impact of ionizing radiation on developing organisms has been widely studied for risk assessment purposes. Even though efforts have been made to decrease received doses to as low as reasonably achievable, the possibility of accidental exposure has to be considered as well. Mammalian gestation is usually divided into three periods. Radiation exposure during the 'pre-implantation period' may essentially result in embryonic mortality while exposure during the 'organogenesis period' may characteristically lead to malformations. In humans, the 'fetal period' is one of particular sensitivity to radiation induction of mental retardation, especially if the exposure occurs between weeks 8-15 of gestation. It is also admitted that prenatal irradiation may increase the risk of leukemia and childhood cancer, with an equal risk over the whole pregnancy. The aim of this study was to investigate the effects of moderate to high doses of X-irradiation on mouse skin fetal fibroblasts, one of the cell types subjected to the highest dose of radiation. Exposure of the cells to X-rays led to a rapid and significant increase in γ-H2AX foci, indicative of high levels of DNA double strand breaks. High doses (>2 Gy) also led to a pronounced G2-arrest and a decrease in the number of cells in the S phase, which was followed after 24 h by a decrease in cell survival and an increase in the level of apoptosis and necrosis. This study shows that mouse fetal skin fibroblasts are sensitive to high doses of X-irradiation. Furthermore, we report a better repair for higher doses than lower, which seems to indicate that little DNA damage is not necessarily repaired immediately. However, more sensitive approaches are necessary to identify the risk associated with low doses of radiation.

The X-ray induced G2 arrest in mouse eggs: a maternal effect involving a lack of polypeptide phosphorylation.

In some strains of mice, eggs when X irradiated during the pronuclear stage, undergo a mitotic block in the G2 phase of the first cell cycle and cleave when the second division takes place in controls. The importance of this effect varies considerably with the strain and depends exclusively on the maternal genotype. In previous work, two-dimensional electrophoresis showed that eggs blocked at the one-cell stage after irradiation, undergo the same modifications in polypeptide synthesis as two-cell controls of the same age, except at the time of normal first mitosis, where three polypeptide sets of 30, 35 and 45 kDa appear only in cleaving controls. In the present study, we have found phosphorylations in dividing controls, on polypeptides of 30, 35 and 45 kDa. These phosphorylations are not seen in blocked irradiated eggs.