David Chen

Collaborative Brokerage, Generative Creativity, and Creative Success:

Analyzing data on utility patents from 1975 to 2002 in the careers of 35,400 collaborative inventors, this study examines the influence of brokered versus cohesive collaborative social structures on an individuals creativity. We test the hypothesis that brokerage—direct ties to collaborators who themselves do not have direct ties to each other—leads to greater collaborative creativity. We then test interaction hypotheses on the marginal benefits of cohesion, when collaborators have independent ties between themselves that do not include the individual. We identify the moderators of brokerage and argue for contingent benefits, based on the interaction of structure with the attributes, career experiences, and extended networks of individuals and their collaborators. Using a social definition of creative success, we also trace the development of creative ideas from their generation through future use by others. We test the hypothesis that brokered ideas are less likely to be used in future creative efforts. The results illustrate how collaborative brokerage can aid in the generation of an idea but then hamper its diffusion and use by others.

Response of X-ray-sensitive CHO mutant cells (xrs-6c) to radiation. II. Relationship between cell survival and the induction of chromosomal damage with low doses of α particles

The induction of cytotoxicity, chromosomal aberrations, and sister chromatid exchanges (SCEs) was measured in CHO K-1c cells and in isogenic X-ray-sensitive mutant xrs-6c cells that had been irradiated with X rays and alpha particles in isoleucine-deficient alpha-minimal essential medium in G1 phase of the cell cycle. There was a noticeable shoulder region on the survival curve for CHO K-1c cells irradiated with very low doses of alpha particles, whereas this feature was absent for xrs-6c cells with alpha-particle doses as low as 0.5 cGy. Higher frequencies of chromatid-type aberrations were induced in G1-phase xrs-6c cells than in G1-phase CHO K-1c cells by both gamma- and alpha-particle irradiation. Induction of nonlethal chromosomal aberrations was observed following exposure to 2-6 cGy of alpha particles, doses yielding 97-100% cell survival. Irradiation with 0.5 cGy of alpha particles induced SCE; nearly 60% of irradiated cells contained significantly increased levels of SCE. However, only 3% of the nuclei of cells exposed to 0.5 cGy of alpha-particle radiation were actually traversed by an alpha particle. The observation that a large fraction of cells apparently survive exposure to very low doses of alpha-particle radiation with persistent genetic damage manifested by both chromosomal aberrations and SCEs may have important implications for the carcinogenic hazards of high-LET radiation.

Response of X-ray-sensitive CHO mutant cells to γ radiation. I: Effects of low dose rates and the process of repair of potentially lethal damage in G1 phase

X-ray-sensitive CHO mutants (xrs-5 and xrs-6) were exposed to isoleucine-deficient (IL-) medium for 24-36 h to accumulate G1-phase cells. Cells exposed to IL- medium for up to 5 days did not show significant changes in plating efficiency when returned to normal medium. Nearly confluent cultures of IL- -treated cells were irradiated with either 60Co gamma rays (75 cGy/min) or 137Cs gamma rays (2.7, 6.0, or 15.3 cGy/h). A significant reduction (approximately 2.5-fold) in the radiation sensitivity of the parental CHO K-1 cells was observed for chronic low-dose-rate radiation exposure compared to the results obtained for acute high-dose-rate exposure. However, no noticeable differences were observed in the survival curves of either xrs-5 or xrs-6 cells when low-dose-rate and acute exposures were compared. CHO K-1 cells exhibited potentially lethal damage repair while held in IL- medium after gamma irradiation, whereas no repair was observed in either of the radiation-sensitive mutant lines examined at similar survival levels.

Acetylsalicyclate administered during simulated ischemia reduces the recovery of neuronal function in the in vitro rabbit retina.

Aspirin is widely used as an analgesic, in the secondary prevention of stroke, and has recently been suggested to be a putative neuroprotective agent, yet whether it acts directly on the central nervous system (CNS) is not yet clarified. We therefore examined the effect of lysine acetylsalicylate (L-ASA, 4-2000 microM) on neuronal function under normal conditions and following 1 h of ischemia using the in vitro rabbit retina preparation. L-ASA inhibited the light-evoked compound action potentials, but not the electroretinogram, in a concentration-dependent manner. In addition, L-ASA (2000 microM, but not 4, 40 or 200 microM) administered during ischemia, reduced the recovery of neuronal function compared to control (untreated) retinas. L-ASA therefore inhibits CNS neurotransmission, but not phototransduction, in a concentration-dependent manner. In addition, high concentration L-ASA impairs the recovery of neuronal function following an ischemic episode.

Nitric oxide produced during ischemia improves functional recovery in the rabbit retina.

We examined the effect of modulating endogenous nitric oxide (NO) production on the recovery of neuronal function from temporary ischemia using a preparation in which blood flow is not a factor. Inhibition of nitric oxide synthase (NOS) during ischemia with L-NA (100 m mol −1) resulted in worse functional recovery compared to D-NA (100 μmoll −1)-treated in control retinas (p < 0.01). In contrast, addition of L-Arg (1000 μmol −1) during ischemia, resulted in a concentration-dependent functional improvement (p < 0.05). These results show that inhibition of constitutive NOS is detrimental, whilst the enhancement of endogenous NO production improves the recovery of neuronal function during a period of temporary ischemia in the isolated retina, (an in vitro avascular model of the CNS). Thus, independent of its effects on the vasculature, NO production during temporary ischemia protects neurons from irreversible function damage.

Differing responses of Nijmegen breakage syndrome and ataxia telangiectasia cells to ionizing radiation

Abstract Little, J. B., Nagasawa, H., Dahlberg, W. K., Zdzienicka, M. Z., Burma, S. and Chen, D. J. Differing Responses of Nijmegen Breakage Syndrome and Ataxia Telangiectasia Cells to Ionizing Radiation. Radiat. Res. 158, 319–326 (2002). Nijmegen breakage syndrome (NBS) is a rare autosomal recessive disorder. Originally thought to be a variant of ataxia telangiectasia (AT), the cellular phenotype of NBS has been described as almost indistinguishable from that of AT. Since the gene involved in NBS has been cloned and its functions studied, we sought to further characterize its cellular phenotype by examining the response of density-inhibited, confluent cultures of human diploid fibroblasts to irradiation in the G0/G1 phase of the cell cycle. Both NBS and AT cells were markedly sensitive to the cytotoxic effects of radiation. NBS cells, however, were proficient in recovery from potentially lethal damage and exhibited a pronounced radiation-induced G1-phase arrest. Irradiated AT cells showed no potentially lethal damage and no G1-phase arrest. Both cell types were hypersensitive to the induction of chromosomal aberrations, whereas the distribution of aberrations in irradiated NBS cells was similar to that of normal controls, AT cells showed a high frequency of chromatid-type aberrations. TP53 and CDKN1A (also known as p21Waf1) expression was attenuated in irradiated NBS cells, but maximal induction occurred 2 h postirradiation, as was observed in normal controls. The similarities and differences in cellular phenotype between irradiated NBS and AT cells are discussed in terms of the functional properties of the signaling pathways downstream of AT involving the NBS1 and TP53 proteins.