Design guidelines for perovskite/silicon 2-terminal tandem solar cells: an optical study.

Perovskite/silicon 2-terminal tandem cells have made significant advances towards >25% efficiency. Despite this, there is limited understanding of how the optical properties of the materials affect the optical losses within the tandem cell. Using an accurate optical model, we investigate, identify and propose solutions to the optical loss mechanisms inherent in a typical perovskite/silicon 2-terminal tandem cell. The results highlight, firstly, the requirement for low absorption in all layers above the perovskite film, and secondly, the importance of the proper choice of refractive index and thickness of charge transport layers of the perovskite cell, in order to minimize reflection at the interfaces formed by these layers. We demonstrate that the proper choice of these parameters is based on, and can be guided by, basic optics principles which serve as design guidelines. With careful selection of charge transport materials, optimization of the perovskite absorber thickness and the introduction of light trapping within the silicon cell, a matched current of over 20 mA/cm2 can be realized, enabling efficiencies greater than 30% using currently available cell processing methods and materials.

Dichloroacetate induces tumor-specific radiosensitivity in vitro but attenuates radiation-induced tumor growth delay in vivo.

BACKGROUND: Inhibition of pyruvate dehydrogenase kinase (PDK) by dichloroacetate (DCA) can shift tumor cell metabolism from anaerobic glycolysis to glucose oxidation, with activation of mitochondrial activity and chemotherapy-dependent apoptosis. In radiotherapy, DCA could thus potentially enhance the frequently moderate apoptotic response of cancer cells that results from their mitochondrial dysfunction. The aim of this study was to investigate tumor-specific radiosensitization by DCA in vitro and in a human tumor xenograft mouse model in vivo. MATERIALS AND METHODS: The interaction of DCA with photon beam radiation was investigated in the human tumor cell lines WIDR (colorectal) and LN18 (glioma), as well as in the human normal tissue cell lines HUVEC (endothelial), MRC5 (lung fibroblasts) and TK6 (lymphoblastoid). Apoptosis induction in vitro was assessed by DAPI staining and sub-G1 flow cytometry; cell survival was quantified by clonogenic assay. The effect of DCA in vivo was investigated in WIDR xenograft tumors growing subcutaneously on BALB/c-nu/nu mice, with and without fractionated irradiation. Histological examination included TUNEL and Ki67 staining for apoptosis and proliferation, respectively, as well as pinomidazole labeling for hypoxia. RESULTS: DCA treatment led to decreased clonogenic survival and increased specific apoptosis rates in tumor cell lines (LN18, WIDR) but not in normal tissue cells (HUVEC, MRC5, TK6). However, this significant tumor-specific radiosensitization by DCA in vitro was not reflected by the situation in vivo: The growth suppression of WIDR xenograft tumors after irradiation was reduced upon additional DCA treatment (reflected by Ki67 expression levels), although early tumor cell apoptosis rates were significantly increased by DCA. This apparently paradoxical effect was accompanied by a marked DCA-dependent induction of hypoxia in tumor-tissue. CONCLUSION: DCA induced tumor-specific radiosensitization in vitro but not in vivo. DCA also induced development of hypoxia in tumor tissue in vivo. Further investigations relating to the interplay between tumor cell metabolism and tumor microenvironment are necessary to explain the limited success of metabolic targeting in radiotherapy.

Suberoylanilide hydroxamic acid affects γH2AX expression in osteosarcoma, atypical teratoid rhabdoid tumor and normal tissue cell lines after irradiation.

PURPOSE: Osteosarcoma and atypical teratoid rhabdoid tumors are tumor entities with varying response to common standard therapy protocols. Histone acetylation affects chromatin structure and gene expression which are considered to influence radiation sensitivity. The aim of this study was to investigate the effect of the combination therapy with the histone deacetylase inhibitor suberoylanilide hydroxamic acid (SAHA) and irradiation on atypical teratoid rhabdoid tumors and osteosarcoma compared to normal tissue cell lines. METHODS: Clonogenic assay was used to determine cell survival. DNA double-strand breaks (DSB) were examined by pulsed-field electrophoresis (PFGE) as well as by γH2AX immunostaining involving flow cytometry, fluorescence microscopy, and immunoblot analysis. RESULTS: SAHA lead to an increased radiosensitivity in tumor but not in normal tissue cell lines. γH2AX expression as an indicator for DSB was significantly increased when SAHA was applied 24 h before irradiation to the sarcoma cell cultures. In contrast, γH2AX expression in the normal tissue cell lines was significantly reduced when irradiation was combined with SAHA. Analysis of initial DNA fragmentation and fragment rejoining by PFGE, however, did not reveal differences in response to the SAHA pretreatment for either cell type. CONCLUSION: SAHA increases radiosensitivity in tumor but not normal tissue cell lines. The increased H2AX phosphorylation status of the SAHA-treated tumor cells post irradiation likely reflects its delayed dephosphorylation within the DNA damage signal decay rather than chromatin acetylation-dependent differences in the overall efficacy of DSB induction and rejoining. The results support the hypothesis that combining SAHA with irradiation may provide a promising strategy in the treatment of solid tumors.

In vitro sensitivity of malignant melanoma cells lines to photon and heavy ion radiation.

BACKGROUND: The role of radiotherapy in malignant melanoma is still in discussion due to its relative resistance to radiation. In various literature, heavy ions show a higher relative biological effectiveness than photons. The aim of this work is to evaluate the radiotherapeutical effect from photons as well as heavy ions on malignant melanoma cells and to indicate the possible radiosensitivity based on its proliferation-inhibitory effect. METHODS: Two different cell lines of malignant melanoma, WM115 (primary tumor) and WM266-4 (metastatic site, skin) were used in this in vitro study. The cells were treated with photons or heavy ions (C12 and O16 ions). Cell-proliferation assay using hemocytometer was used for the quantitative and qualitative evaluation of cell growth. Furthermore, flow cytometry was also used to analyze the cell cycle distribution. RESULTS: Heavy ions compared to photons and between the two heavy ion modalities, O16 ions showed an improved suppression of cell growth in both cell lines. Furthermore, a G2/M arrest was detected in both cell lines after all radiotherapy modalities - with the arrest increasing with the dose applied. CONCLUSION: Heavy ions showed a greater inhibitory effect on cell proliferation compared to photons and an increased G2/M arrest. Therefore, C12 and O16 heavy ions might overcome the relative radioresistance of malignant melanoma to photons. Further research is warranted.

Carbon ion and proton beam irradiation of a normal human TK6 lymphoblastoid cell line within a magnetic field of 1.0 tesla.

BACKGROUND: Considering the increasing simultaneous application of magnetic resonance imaging (MRI) for more precise photon radiotherapy, it will be likely for particle radiotherapy to adopt MRI for future image guiding. It will then be imperative to evaluate the potential biological effects of a magnetic field (MF) on particle irradiation. This study explores such effects on the highly radiosensitive TK6 lymphoblastoid human cell line. METHODS: The following three parameters were measured after irradiation with either carbon ion or proton beams using spread out Bragg peaks and applying different doses within a perpendicular 1.0 T MF: (1) cell survival fraction (14 days postirradiation), (2) treatment-specific apoptosis, which was determined through the measurement of population in the sub-G1 phase, and (3) cell cycle progression by means of flow cytometry. These were compared to the same parameters measured without an MF. RESULTS: The clonogenic assay in both treatment groups showed almost identical survival curves with overlapping error bars. The calculated α values with and without an MF were 2.18 (σ=0.245) and 2.17 (σ=0.234) for carbon ions and 1.08 (σ=0.138) and 1.13 (σ=0.0679) for protons, respectively. Similarly, the treatment-specific apoptosis and cell cycle progression showed almost identical curves with overlapping error bars. A two-sample, unpooled t-test analysis was implemented for comparison of all mean values and showed p-values >0.05. CONCLUSION: No statistically significant difference in biological response of the TK6 cells was observed when they were irradiated using spreadout Bragg peaks within a perpendicular 1.0 T MF as compared to those, which received the same dose without the MF. This should serve as another supporting piece of evidence toward the implementation of MRI in particle radiotherapy, though further research is necessary.

The influence of a magnetic field on photon beam radiotherapy in a normal human TK6 lymphoblastoid cell line.

BACKGROUND: The implementation of magnetic resonance imaging (MRI) guided radiotherapy (RT) continues to increase. Very limited in-vitro data on the interaction of ionizing radiation and magnetic fields (MF) have been published. In these experiments we focused on the radiation response in a MF of the TK6 human lymphoblastoid cells which are known to be highly radiosensitive due to efficient radiation-induced apoptosis. METHODS: Clonogenicity was determined 12-14 days after irradiation with 1-4 Gy 6 MV photons with or without a 1.0 Tesla MF. Furthermore, alterations in cell cycle distribution and rates of radiation induced apoptosis (FACS analysis of cells with sub-G1 DNA content) were analyzed. RESULTS: Clonogenic survival showed an exponential dose-dependence, and the radiation sensitivity parameter (α = 1.57/Gy) was in accordance with earlier reports. Upon comparing the clonogenic survival between the two groups, identical results within error bars were obtained. The survival fractions at 2 Gy were 9% (without MF) and 8.5% (with MF), respectively. CONCLUSION: A 1.0 Tesla MF does not affect the clonogenicity of TK6 cells irradiated with 1-4 Gy 6MV photons. This supports the use of MRI guided RT, however ongoing research on the interaction of MF and radiotherapy is warranted.

Radiosensitizing potential of gemcitabine (2',2'-difluoro-2'-deoxycytidine) within the cell cycle in vitro.

PURPOSE: Gemcitabine (2',2'-difluorodeoxycytidine; dFdCyd) is a new deoxycitidine analog which exhibits substantial activity against solid tumors and radiosensitizing properties in vitro. To examine cell cycle-specific effects of a combined treatment with gemcitabine and radiation, the in vitro clonogenic survival of two different cell lines was measured for cells from log-phase culture, G1 and S-phase cells. METHODS AND MATERIALS: Chinese hamster (V79) and human colon carcinoma (Widr) cells were exposed to different radiation doses and for different points of time relative to gemcitabine treatment (2 h). Experiments were also carried out with different cell-cycle populations obtained after mitotic selection (V79) or after serum stimulation of plateau-phase cells (Widr). The resulting survival curves were analyzed according to the LQ model, and mean inactivation doses (MID) and the cell cycle-specific enhancement ratios (ER) were calculated from the survival curve parameters. RESULTS: Effectiveness of combined treatment of log-phase cells was greatest when cells were irradiated at the end of the gemcitabine exposure [ER: 1.28 (V79), 1.24 (Widr)]. For later times after the removal of the drug, radiosensitization declined, approaching independent toxicity. From the time course of interactive-type damage decay half-life values of 75 min (V79) and 92 min (Widr) were derived. Gemcitabine did not radiosensitize G1 Widr cells or V79 cells from the G1/S border, but substantial radiosensitization was observed for the S-phase cell preparations [ER: 1.45 (V79-lateS), 1.57 (Widr)]. CONCLUSIONS: Treatment of cells with gemcitabine immediately before irradiation eliminates, or at least greatly reduces, the variation in radiosensitivity during the cell cycle that is manifested by radioresistance during S phase. This reversal of S-phase radioresistance could imply that gemcitabine interferes with the potentially lethal damage repair/fixation pathway. Other approaches have been taken to overcome S-phase radioresistance, such as hyperthermia or densely ionizing radiation, and combined treatments with dFdCyd could prove of value to complement such efforts.

Increased dose-rate effect in V79-multicellular aggregates (spheroids). Relation to initial DNA lesions and repair.

Survival of exponentially growing V79 monolayer cells was measured after irradiation at low dose-rate (up to 1.1 Gy/h) and at high dose-rate (2.5 Gy/min) and compared to corresponding survival data of V79 spheroid cells. The so-called contact effect, the increased radioresistance of cells irradiated in spheroids, was expressed to a greater extent with low dose-rate exposure. Lesion fixation by hypertonic treatment was more pronounced in spheroid versus monolayer cells and abolished the contact effect. The reduced radiosensitivity of V79 spheroid cells could not be related to a reduced number of initial DNA lesions or a higher capacity to rejoin DNA breaks (measured by neutral elution). These findings suggest that the ratio of lesion repair to fixation/misrepair may differ between cells from spheroids and monolayer culture thus influencing the response of cells to dose-rate changes differentially.

In vitro radiosensitivity of primary human fibroblasts. Lack of correlation with acute radiation toxicity in patients with head and neck cancer.

BACKGROUND AND PURPOSE: There is a considerable hope among clinicians and radiobiologists to detect genetically radiosensitive patients prior to radiotherapy. A predictive assay would enable adjustment of the total irradiation dose to the individual at a constant risk of normal tissue complications. In this prospective study, the clonogenic survival assay for primary human fibroblasts to determine radiosensitivity in vitro was evaluated and then correlated with clinically observed acute radiation reactions. MATERIALS AND METHODS: One hundred twenty-five independent survival experiments with primary fibroblasts derived from 63 biopsies from 55 cancer and non-cancer patients were performed. RESULTS: A wide variation of cell survival between biopsies was detected. Statistical analysis revealed a highly significantly larger interindividual than intraindividual variation of SF2 values. However, a considerable scatter of SF2 values in repeated experiments was observed in individual cases. Age, gender, disease status (cancer patient, non-cancer patient) and origin of fibroblasts (skin, periodontal tissue) were demonstrated not to be statistically significant confounding factors on the intrinsic radiosensitivity in vitro. In a prospective study, no correlation of the SF2 and acute reactions in 25 patients with head and neck cancer treated with a primary accelerated radiochemotherapy was detected. CONCLUSION: Our data show that the clonogenic assay is able to distinguish between intrinsic radiosensitivities of primary human fibroblasts if a statistical approach is used but does not predict acute radiation toxicity.

Differential effects of dose rate and superfractionation on survival and cell cycle of V79 cells from spheroid and monolayer culture.

Recent developments concerning brachytherapy suggest conditions for an equivalence between the common continuous low dose rate (CLDR) exposure and pulsed irradiation regimens (PDR), provided that total dose is administered in the same overall time. The respective theoretical considerations have been based solely on the phenomenon of sublethal damage recovery. The present study, therefore, aimed to assess a possible influence of growth state/cell cycle progression when CLDR and different super fractionation protocols are compared. The respective experiments were performed with V79 cells that can be grown as a rapidly proliferating monolayer culture or as small spheroids (without hypoxia) where most of the cells are out of cycle. Differential changes in cell cycle distribution occurring during the compared exposure schemes and their impact on cell survival were expected to be expressed most clearly with this model system because of the short G1 phase. Cell irradiations were performed with brachytherapy sources either continuously (137Cs) or with high dose rate pulses (192Ir) at different (1 h and 4 h) pulse repetitions whereby the overall dose rate was kept constant to approximately 1 Gy/h. Cell survival curves were generated by sampling cells at different exposure times or number of pulses, respectively. For spheroid cells an unequivocal decrease of effectivity was demonstrated with decreasing dose per pulse, and the dose effect relation obtained with hourly pulses of 1 Gy was indistinguishable from the CLDR response. For monolayer cells, on the contrary, the scheme of hourly pulses was significantly more effective than the CLDR irradiation. As measured by flow cytometry, this different behaviour could be attributed to the accumulation of cycling cells in the radiosensitive G2/M phase (G2 block) during protracted exposure which was drastically more pronounced for the pulsed scheme compared to the CLDR condition. The observed principle phenomenon of a block to cell cycle progression from high dose rate pulses (at low overall dose rate) may be less expressed in (human) cells having a long G1 period, but if applicable to a clinical situation, an increase of acute effectiveness of a superfractionated brachytherapy protocol has to be considered.

Combined effects of ionizing radiation and 4-hydroperoxyfosfamide in vitro.

BACKGROUND AND PURPOSE: Combined radiochemotherapy has gained increasing interest in clinical applications. The effects of combined exposure of ionizing radiation and 4-hydroperoxyifosfamide (4HOOIF) on cell survival were investigated in vitro. MATERIALS AND METHODS: Clonogenic survival of log phase V79, Caski (squamous carcinoma), Widr (colon carcinoma) and MRI-221 cells (human melanoma) was determined after combined exposure to 4HOOIF and radiation. Measurement of cell survival for different cell cycle phases was performed after mitotic shake-off (V79) or appropriate intervals after serum stimulation of plateau phase cells (Widr). Control of cell cycle distribution was performed using flow cytometry. RESULTS: In all cell lines tested, a combined exposure resulted in cell killing that was greater than for independent action. While this type of radiosensitization was of minor magnitude for log-phase cells or cells in G1 substantial radiosensitization was detected for S-phase cells with enhancement ratios (calculated from the respective mean inactivation doses) of up to 1.5. CONCLUSIONS: The results demonstrate the interaction of 4HOOIF and radiation-induced cell damage with marked cell cycle specificity. Since the largest combination effect was observed for the most radioresistant S-phase cells, damage interaction could be mediated by an interference of 4HOOIF with the repair/fixation pathway of radiation-induced potentially lethal damage.

Acute and late toxicity, tumour control and intrinsic radiosensitivity of primary fibroblasts in vitro of patients with advanced head and neck cancer after concomitant boost radiochemotherapy.

BACKGROUND AND PURPOSE: The existence of hereditary factors influencing the cellular response to ionising radiation has led to the hypothesis that the inter-patient variability of clinical radiation reactions may, at least in part, be attributable to an individual, or intrinsic, radiosensitivity. Considerable effort has been spent in the development of test systems that would determine individual radiosensitivity before or early during radiotherapy to possibly predict treatment outcome, but the results are still conflicting. The present explorative study was therefore aimed at the detection of associations between acute and late radiation effects, tumour control and in vitro radiosensitivity of primary normal tissue fibroblasts. PATIENTS AND METHODS: Sixty-eight patients with squamous cell carcinoma of the head and neck (93% UICC stage IV) were treated with a simultaneous concomitant boost radiochemotherapy with Carboplatin as part of a prospective non-randomised multicenter study at the University of Heidelberg. Primary fibroblasts were obtained from skin biopsies prior to treatment from 25 unselected patients of this study and the SF2 was determined using the colony forming assay and high dose-rate irradiation. The median follow-up was 21 months (range 2.5-81 months). RESULTS: The locoregional control rate at three years was 32%. No significant association between acute (mucosa reaction grade 1 or 2 vs. grade 3 and 4), late radiation effects (subcutaneous fibrosis, osteonecrosis, larynx oedema), locoregional tumour control and SF2 of primary fibroblasts was found using Cox proportional hazards regression analysis, log-rank test and Mann-Whitney U-test. Although a steep dose-response relationship was observed for the radiation-induced severe larynx oedema, Cox proportional hazards regression analysis could not fully explain the occurrence of severe radiation-induced larynx oedema with the dose to the larynx (P = 0.09). In the subgroup of twenty-five patients, where the SF2 was determined, bivariate analysis revealed about the same non-significant influence of the dose to the larynx on the larynx oedema (P = 0.1) and no influence of the SF2 (P = 0.5). CONCLUSIONS: In our study of patients with advanced cancer of the head and neck, neither the normal fibroblast SF2 nor the severity of acute radiation effects were able to predict late radiation effects or locoregional tumour control.

Protein synthesis in irradiated cells. I. Ultraviolet radiation.

Excision-deficient haploid yeast cells (Saccharomyces cerevisiae) were exposed to 254-nm UV radiation and protein synthesis inhibition was measured for a large number of different proteins resolved by two-dimensional gel electrophoresis. The derived UV-radiation sensitivities exhibited an overall increase with protein molar mass. Quantitatively, this behavior is compatible with a well known mechanism of transcription inactivation--termination of RNA chains at UV-radiation-induced pyrimidine dimers--if the respective target sizes are inferred from protein molar mass. The observed deviations from the predicted response suggest that (i) UV-radiation damage may also interfere with recognition/binding of RNA polymerase to regulatory sequences and (ii) the frequency of photolesions for a specific protein encoding gene may differ markedly from the mean induction rate for the total yeast genome.

Induction of telomerase activity by irradiation in human lymphoblasts.

Neuhof, D., Ruess, A., Wenz, F. and Weber, K. J. Induction of Telomerase Activity by Irradiation in Human Lymphoblasts. Radiat. Res. 155, 693-697 (2001). Telomerase activity is a radiation-inducible function, which suggests a role of this enzyme in DNA damage processing. Since the tumor suppressor TP53 plays a central role in the regulation of the cellular response to DNA damage, our study explored the ability of ionizing radiation to change telomerase activity and telomere length in two closely related human lymphoblast cell lines with different TP53 status. TK6 cells (wild-type TP53) and WTK1 cells (mutated TP53) were exposed to different doses of X rays, and telomerase activity was measured by PCR ELISA at different times after irradiation. A dose-dependent increase in telomerase activity was observed. One hour after irradiation with 4 Gy, TK6 and WTK1 cells showed an approximately 2.5-fold increase; for lower doses (0.1 to 1 Gy), telomerase induction was seen only in TK6 cells. Telomerase induction was observed by 0.5 h after irradiation, with a further increase up to 24 h. Irradiated TK6 and WTK1 cells had longer telomeres (+1.3 kb) than unirradiated cells 14 days after exposure. Our data demonstrate a dose-dependent induction of telomerase activity and lengthening of telomeres by ionizing radiation in human lymphoblasts. Induction of telomerase activity by radiation does not generally appear to be controlled by the TP53-dependent DNA damage response pathway. However, for low doses, induction of telomerase requires wild-type TP53.

Heavy ion effects on yeast: inhibition of ribosomal RNA synthesis.

Diploid wild-type yeast cells were exposed to beams of heavy ions covering a wide range of linear energy transfer (LET) (43-13,700 keV/microns). Synthesis of ribosomal RNA (rRNA) was assessed as a functional measure of damage produced by particle radiation. An exponential decrease of relative rRNA synthesis with particle fluence was demonstrated in all cases. The inactivation cross sections derived were found to increase with LET over the entire range of LET studied. The corresponding values for relative biological effectiveness were slightly less than unity. Maximum cross sections measured were close to 1 micron 2, implying that some larger structure within the yeast nucleus (e.g., the nucleolus) might represent the target for an impairment of synthetic activity by very heavy ions rather than the genes coding for rRNA. Where tested, an oxygen effect for rRNA synthesis could not be demonstrated.

Measurement of hypoxia using the comet assay correlates with preirradiation microelectrode pO2 histography in R3327-AT rodent tumors.

Polarographic determination of tumor oxygenation by Eppendorf histography is currently under investigation as a possible predictor of radiotherapy outcome. Alternatively, the alkaline comet assay has been proposed as a radiobiological approach for the detection of hypoxia in clinical tumor samples. Direct comparisons of these methods are scarce. One earlier study with different murine tumors could not establish a correlation, whereas a weak correlation was reported for a variety of human tumors. Considering the different end points and spatial resolution of the two methods, a direct comparison for a single tumor entity appeared desirable. Anaplastic R3327-AT Dunning prostate tumors were grown on Copenhagen rats to volumes of 1-6 cm(3). Eppendorf histography (100-200 readings in 5 parallel tracks) for 8 different tumors revealed various degrees of oxygenation, with median pO(2) values ranging from 1.1 to 23 mmHg. Within 5 min after an acute exposure to 8 Gy (60)Co gamma rays, tumors were excised from killed animals and rapidly cooled to limit repair, and a single cell suspension was prepared for use with the comet assay. The resulting comet moment distributions did not exhibit two subpopulations (one hypoxic and the other aerobic), and a hypoxic fraction could not be calculated. Instead, the average comet moment distribution was taken as a parameter of overall strand break induction. Corresponding experiments with tumor cells grown in vitro allowed us to derive the relationship between the oxygen enhancement ratio (OER) for the average comet moment and oxygen partial pressure (Howard-Flanders and Alper formula). The validity of this relationship was inferred for cells exposed in situ, and the convolution of a pO(2) distribution with the formula of Howard-Flanders and Alper yielded an array of expected OER values for each tumor. The average expected OER correlated well with the average comet moment (r = 0.89, P < 0.01), and the in situ comet moment distributions could be predicted from the Eppendorf data when 50% repair was taken into account, assuming a 5-min damage half-life. The findings confirm the potential of interstitial polarography to reflect radiobiologically relevant intracellular oxygenation, but also underscore the confounding influence of differences in repair that may occur when cells are prepared from irradiated tissues for use with the comet assay.

Lethality of heavy ion-induced DNA double-strand breaks in mammalian cells.

Cell killing and the production of DNA double-strand breaks (dsbs) were measured in parallel for V79 cells and a human tumour cell line (Caski) following exposure to radiations of differing linear energy transfer (LET) including accelerated heavy ions. Dsb induction was assessed by neutral filter elution (pH 7.4) and elution from agarose plugs in pulsed-field electrophoresis. The elution data were consistent with linear lesion induction and allowed to derive dsb yields or production cross-sections (sigma dsb), respectively. Both cell lines as well as the two elution approaches gave comparable results. sigma dsb was found to rise up to the heaviest ions used (LET = 11,500 keV/microns) but relative biological effectiveness was always smaller than unity. Slopes of the exponential survival curves (final slope with 60Co-radiation) were normalized to the respective dsb yields and allowed to calculate the relative lethality per induced dsb. This parameter increased with LET up to about 300 keV/microns followed by a steep decline for the very heavy ions. The extent of dsb rejoining was concomitantly reduced with ionization density.

Measurement of biological effects of high-energy carbon ions at low doses using a semi-automated cell detection system.

PURPOSE: To study the effects of low-dose, high-LET irradiation in order to detect possible deviations from a linear-quadratic dose dependence. MATERIALS AND METHODS: Experiments using charged particle irradiation were performed, in particular in the low-dose range from 0 to 2 Gy, and compared with experiments using photon radiation. The survival of V79 cells was studied by means of a semi-automated system, which allowed the detection and relocation of positions of individual cells at regular intervals. It consists of an inverted microscope equipped with a computerized stage control and image processing system. With such a technique, the precision of the survival assay is increased by avoiding the stochastic uncertainties of the conventional dilution assay. Furthermore, by means of daily observations, the system allows a detailed study of the growth kinetics of individual cells up to approximately 1 week after irradiation. RESULTS AND CONCLUSION: Up to now, high-LET experiments have been performed using mainly 100 MeV/u carbon ions (LET: 28 keV/microm). A significant hypersensitivity at low doses (0.1 Gy) has been detected for these ions. It is the first report of such a pronounced effect for charged particle irradiation. Although hypersensitivity after carbon ion irradiation apparently is in contrast to other data reported for peak pion irradiation at similar LET values, the difference might possibly be due to differences in the track structure of the particles.

Trans-dominant inhibition of poly(ADP-ribosyl)ation leads to decreased recovery from ionizing radiation-induced cell killing.

Poly(ADP-ribosyl)ation is a post-translational modification of nuclear proteins catalysed by poly(ADP-ribose)polymerase (PARP). PARP is strongly activated by DNA strand breaks and is thought to be involved in DNA repair, and various chemical agents that inhibit poly(ADP-ribosyl)ation have radiosensitizing properties. An alternative, highly specific (trans-dominant) inhibition of PARP function has been made possible with a molecular genetic approach where CO60 hamster cells were transfected with the PARP DNA-binding domain (DBD) under the control of a Dexamethasone (Dex)-inducible promoter. Stable transfectants were incubated with or without Dex and the impact of poly(ADP-ribosyl)ation on cellular radiation response (clonogenic survival) was measured following irradiation at high or low dose-rate or when potentially lethal damage (PLD) recovery was allowed. For acute exposures the radiosensitizing effect of PARP inhibition could be confirmed and a large enhancement ratio (calculated from the respective mean inactivation doses) of 2.2 was found for plateau phase cells. Both cellular recovery phenomena (dose-rate sparing and PLD) were decreased in the presence of Dex, and particularly PLD-recovery was nearly completely abolished due to the inhibition of poly(ADP-ribosyl)ation. The latter finding strongly suggests an involvement of PARP in the repair of DNA double-strand breakage.

Sensitivity of neutral filter elution but not PFGE can be modified by non-dsb chromatin damage.

Hamster V79 fibroblast cells and human squamous carcinoma cells (Caski) were exposed to 60Co radiation and DNA double-strand break (dsb) induction was analysed by DNA elution at neutral pH from polycarbonate filter or out of an agarose matrix in pulsed-field electrophoresis (PFGE). While dsb yields were equal for the two cell lines (using 125-iodine calibration) a reduced responsiveness of filter elution was found for V79 versus Caski cells. This difference could be abolished when additional single-strand breaks (ssb) were introduced by an incubation at 10(-4) M H2O2 for up to 40 min that itself did not give a response in neutral elution. No such lack of specificity for the detection of dsb was seen in electrophoretic elution where also the influence of peroxide incubation was absent. The presumed potential of ssb to modify dsb detection was paralleled by the kinetics of dsb rejoining: a pronounced transient increase of DNA elution from filters was observed for V79 cells (less prominent with Caski cells) at 15-40 which is thought to reflect the occurrence of secondary ssb from incisions during base damage repair. Rejoining measured by PFGE did not show this behaviour. The results suggest that ssb may aid decondensation of the chromatin during lysis of cells required for an efficient release of dsb fragments when supported on filters, but which depends on cell type and is less critical in electrophoretic elution out of an agarose matrix. This involvement of ssb in the neutral filter elution assay appears to be contrary to published data obtained with different experimental systems. The finding of an increase of DNA elution from filters due to hyperthermia at 45 degrees C is also taken to indicate an involvement of non-dsb chromatin damage in the response of filter elution at neutral pH with V79 but not with Caski cells.