165,617 research outputs found
A. Kleinman, P. Kunstadter, E. Rüssel Alexander, J. L. Gale, eds., Medicine in Chinese Cultures : Comparative Studies of Health Care in Chinese and Other Societies
Choy Kwei Meng. A. Kleinman, P. Kunstadter, E. Rüssel Alexander, J. L. Gale, eds., Medicine in Chinese Cultures : Comparative Studies of Health Care in Chinese and Other Societies. In: L'Homme, 1979, tome 19 n°2. pp. 116-121
Taxonomic revision of the Australian species of Australatya Chace 1983 (Crustacea, Decapoda, Atyidae), and the description of a new species
Choy, Satish, Page, Timothy J., Mos, Benjamin (2019): Taxonomic revision of the Australian species of Australatya Chace 1983 (Crustacea, Decapoda, Atyidae), and the description of a new species. Zootaxa 4711 (2): 366-378, DOI: https://doi.org/10.11646/zootaxa.4711.2.
Regulation and drug resistance mechanisms of mammalian ribonucleotide reductase, and the significance to DNA synthesis
PT: J; CR: ALBERT DA, 1987, J CELL PHYSIOL, V130, P262 ASHIHARA T, 1979, METHOD ENZYMOL, V58, P248 BOLIN RW, 1982, CANCER, V50, P1683 CARLSON J, 1984, P NATL ACAD SCI USA, V81, P4294 CARTER GL, 1989, CANCER COMMUN, V1, P13 CHOY BK, 1988, CANCER RES, V48, P2029 CHOY BK, 1989, BIOCHEM BIOPH RES CO, V162, P1417 COCKING JM, 1987, SOMAT CELL MOLEC GEN, V13, P221 COWAN KH, 1986, MOL PHARMACOL, V30, P69 DICK JE, 1984, MECH AGEING DEV, V26, P37 DONOVAN PB, 1984, AM J HEMATOL, V17, P329 DRYSDALE JW, 1988, PROG NUCLEIC ACID RE, V35, P127 ENGSTROM Y, 1984, EMBO J, V3, P863 ERIKSSON S, 1981, J BIOL CHEM, V256, P9436 FOX RM, 1989, INT ENCY PHARM THER, V128, P113 HANKE PD, 1983, J BACTERIOL, V156, P1192 HARDS RG, 1984, ARCH BIOCHEM BIOPHYS, V231, P9 HOPPER S, 1972, J BIOL CHEM, V247, P3336 HURTA RAR, 1990, BIOCHEM BIOPH RES CO, V167, P258 HURTA RAR, 1990, IN PRESS BIOCH BIOPH LEWIS WH, 1974, BIOCHEM BIOPH RES CO, V60, P926 LEWIS WH, 1978, J CELL PHYSL, V97, P73 LEWIS WH, 1978, J CELL PHYSL, V97, P87 LEWIS WH, 1979, SOMATIC CELL GENET, V5, P83 LYNCH JB, 1989, J BIOL CHEM, V264, P8091 MCCLARTY GA, 1986, CANCER RES, V46, P4516 MCCLARTY GA, 1986, SOMAT CELL MOLEC GEN, V12, P121 MCCLARTY GA, 1987, BIOCHEM BIOPH RES CO, V145, P1276 MCCLARTY GA, 1987, BIOCHEMISTRY-US, V26, P8004 MCCLARTY GA, 1988, BIOCHEM BIOPH RES CO, V154, P975 MCCLARTY GA, 1988, BIOCHEMISTRY-US, V27, P7524 MCCLARTY GA, 1990, J BIOL CHEM, V265, P7539 MCCONLOGUE L, 1986, MOL CELL BIOL, V6, P2865 MCDONALD CJ, 1981, PHARMACOL THERAPEUT, V14, P1 PIVER MS, 1983, AM J OBSTET GYNECOL, V147, P803 RICHARD P, 1988, ANNU REV BIOCHEM, V57, P349 RITTBERG DAH, 1989, BIOCHEM CELL BIOL, V67, P352 SRINIVASAN PR, 1987, J BIOL CHEM, V262, P12871 TAGGER AY, 1987, BIOCH CELL BIOL, V65, P925 TAGGER AY, 1988, INT J CANCER, V42, P760 THEIL EC, 1987, ANNU REV BIOCHEM, V56, P289 THELANDER L, 1980, J BIOL CHEM, V255, P7426 THELANDER L, 1986, MOL CELL BIOL, V6, P3433 THELANDER M, 1985, J BIOL CHEM, V260, P2737 THOMAS CE, 1986, J BIOL CHEM, V261, P13064 TILL JE, 1973, FED PROC, V32, P29 TONIN PN, 1987, CYTOGENET CELL GENET, V45, P102 TONIN PN, 1989, ONCOGENE, V4, P1117 ULLMAN B, 1979, P NATL ACAD SCI USA, V76, P1074 VEALE D, 1988, BRIT J CANCER, V58, P70 WEBER G, 1983, CANCER RES, V43, P3466 WECKBECKER G, 1988, J NATL CANCER I, V80, P491 WEINBERG G, 1981, P NATL ACAD SCI USA, V78, P2447 WILLIAMS SR, 1987, J BIOL CHEM, V262, P2332 WRIGHT JA, 1974, J CELL PHYSIOL, V83, P437 WRIGHT JA, 1980, CAN J GENET CYTOL, V22, P443 WRIGHT JA, 1981, ADV ENZYME REGUL, V19, P105 WRIGHT JA, 1987, SOMAT CELL MOLEC GEN, V13, P155 WRIGHT JA, 1989, DRUG RESISTANCE MAMM, V1, P15 WRIGHT JA, 1989, INT ENCY PHARM THERA, V128, P89 YANGFENG TL, 1987, GENOMICS, V1, P77; NR: 61; TC: 75; J9: BIOCHEM CELL BIOL; PG: 8; GA: EM994Source type: Electronic(1
[Report to Chief J. E. Curry, by an unknown author #1]
Report to Chief J. E. Curry, by an unknown author. The report contains a list of officers who gave depositions to the United States Attorney
[Report to Chief J. E. Curry, by an unknown author #2]
Report to Chief J. E. Curry, by an unknown author. The report contains a list of officers who gave depositions to the United States Attorney
New concept to break the intrinsic properties of organic semiconductors for optical sensing applications
The space charge limit (SCL) effect is a universal phenomenon in semiconductor devices involving light emitting diodes, solar cells, and photodetectors. Typically, the SCL will exist in the condition of (1)
unbalanced hole and electron mobility; (2) thick active layer; (3) high light intensity or dense photocarriers (electrons and holes) generation; and (4) moderate reverse bias. Through the study of plasmonic organic solar cells, we will show metallic nanostructures go beyond their optical functions to
control recombination, transport, and collection of photocarriers generated from active organic materials. Through spatially redistributing light absorption at the active layer, the proposed plasmonic-electrical concept is fundamentally different from the hot carrier effect where photocarriers are generated from metallic nanostructures. The new plasmonic-electrical effect not only lays a physical foundation but also upgrades electrical properties for semiconductor devices [1]. We will also design different device
structures to investigate and demonstrated how plasmonic-electrical [2] and plasmonic-optical [3] effects can be used to enhance device performances such as improving the light absorption of solar cells, increasing emission efficiency of light emitting devices, reducing dark current and enhancing
sensitivity of photodetector as well as intensifying the surface enhanced Raman scattering for biosensor applications. Besides the optical (plasmonic) resonances from metal nanostructure, we will also use metal nanostructures to demonstrate electrical resonance which can be used for bistable and
memory devices [4]. Consequently, exploiting both plasmonic-optical and plasmonic-electrical effects via metallic nanostructures will open up a more flexible and integrated way to design high-performance optoelectronic nanodevices.
[1] W.E.I. Sha, X. Li, W.C.H. Choy, Scientific Reports, vol. 4, p. 6236 (10pp), 2014.
[2] F.X. Xie, W.C.H. Choy, W.E.I. Sha, D. Zhang, S. Zhang, X. Li, C.W. Leung, J. Hou, Energy Environ. Sci., vol. 6, pp.3372 – 3379, 2013; D. Zhang, W.C.H. Choy, F. Xie, W.E.I. Sha, X. Li, B. Ding, K. Zhang, F. Huang, and Y. Cao, Adv. Funct. Mat., vol. 23, pp.4255–4261, 2013; D.D.S. Fung, L. Qiao, W.C.H. Choy, C.C.D. Wang, W.E.I. Sha, F. Xie, and S. He, J. Mater. Chem., vol. 21, pp. 16349
– 16356, 2011.
[3] X.H. Li, W.C. H. Choy, X. Ren, D. Zhang, H.F. Lu, Adv. Funct. Mat. DOI: 10.1002/adfm.201303384; X.H.Li, W.C.H.Choy, H.F. Lu, W.E.I. Sha, and H. P. Ho, Adv. Funct. Mat., vol.23, pp.2728–2735, 2013; X.H. Li, W. C.H. Choy, L Huo, F.X. Xie, W.E.I. Sha, B. Ding, X. Guo, Y. Li, J. Hou, J. You, Y. Yang, Adv. Mater. vol. 24, pp.3046-3052, 2012; X.H. Li, W. E.I. Sha, W.C.H. Choy, D.D.S. Fung, F. X. Xie, J. of Phys. Chem. C, vol. 116, pp.7200-7206, 2012; C.C.D. Wang, W. C. H. Choy, C. Duan, D.D.S. Fung, W.E.I. Sha, F.X. Xie, F. Huang, and Y. Cao, J. Mater. Chem., vol. 22, pp.1206–1211, 2012.
[4] T.H. Zheng, W.C.H. Choy, and Y.X. Sun, vol. 19, pp.2648-2653, 2009; T.H. Zheng, W.C.H. Choy, and Y.X. Sun, Appl. Phys. Lett, vol. 94, 123303 (pp.3), 2009.published_or_final_versio
Amplification of the genes for both components of ribonucleotide reductase in hydroxyurea resistant mammalian cells
PT: J; CR: ASHIHARA J, 1979, METHOD ENZYMOL, V58, P259 BIN N, 1976, NUCLEIC ACIDS RES, V3, P2303 BOLIN RW, 1982, CANCER, V50, P1683 CHIRGWIN JM, 1979, BIOCHEMISTRY-US, V18, P5294 CHOY BK, 1988, CANCER RES, V48, P2029 CHOY BK, 1989, BIOCHEM BIOPH RES CO, V162, P1417 COCKING JM, 1987, SOMAT CELL MOLEC GEN, V13, P221 DONOVAN PB, 1984, AM J HEMATOL, V17, P329 ELFORD HL, 1989, INT ENCY PHARM THERA, V128, P217 ENGSTROM PF, 1984, AM J CLIN ONCOL-CANC, V7, P313 GRASLUND A, 1982, J BIOL CHEM, V257, P5711 HARDS RG, 1981, J CELL PHYSIOL, V106, P309 HOPPER S, 1972, J BIOL CHEM, V247, P3336 JACKSON RC, 1989, INT ENCY PHARM THERA, V128, P89 LEWIS WH, 1983, MOL CELL BIOL, V3, P1053 MCCLARTY GA, 1986, SOMAT CELL MOLEC GEN, V12, P121 MCCLARTY GA, 1987, BIOCHEMISTRY-US, V26, P8004 MCDONALD CJ, 1981, PHARMACOL THERAPEUT, V14, P1 MOORE EC, 1989, INT ENCY PHARM THERA, V128, P165 PIVER MS, 1983, AM J OBSTET GYNECOL, V147, P803 SCHIMKE RT, 1988, J BIOL CHEM, V263, P5989 STARK GR, 1986, CANCER SURV, V5, P1 STARK GR, 1989, CELL, V57, P901 STEEPER JR, 1970, ANAL BIOCHEM, V34, P123 TAGGER AY, 1987, BIOCH CELL BIOL, V65, P925 THELANDER L, 1980, J BIOL CHEM, V255, P7426 THELANDER L, 1986, MOL CELL BIOL, V6, P3433 THELANDER M, 1985, J BIOL CHEM, V260, P2737 VEALE D, 1988, BRIT J CANCER, V58, P70 WRIGHT JA, 1987, SOMAT CELL MOLEC GEN, V13, P155 WRIGHT JA, 1989, DRUG RESISTANCE MAMM, V1, P15 WRIGHT JA, 1989, INT ENCY PHARM THERA, V128, P89; NR: 32; TC: 19; J9: BIOCHEM BIOPHYS RES COMMUN; PG: 7; GA: CQ503Source type: Electronic(1
The physiology of senescence in detached pak choy leaves (Brassica rapa var. chinensis) during storage at different temperatures
We have studied the postharvest behavior of detached leaves from pak choy (Brassica rapa var. chinensis), an Asian leafy vegetable commonly used in salad and stir-fry mixes. Color, ethylene production, soluble sugars, starch and proteins were measured during storage of leaves at 2 °C, 10 °C and 20 °C. The main limiting factor on storage life was yellowing at 10 °C and 20 °C and physiological damage in the form of wilting at 2 °C. At 20 °C, ethylene evolution occurs concurrently with yellowing with a rapid decline in sugar concentration immediately prior to yellowing. As temperature was lowered, both ethylene production and sugar decline slowed or became negligible. The rate of soluble sugar decline (in particular, glucose) appears mainly responsible for the regulation of yellowing in detached pak choy leaves with a minimal role for ethylene. Refrigeration of detached pak choy leaves appears to be an ideal technique for the extension of storage life due to the slowing of the rate of sugar decline, which appears to be a key determinant of leaf yellowing.Amanda J. Able, Lung Sing Wong, Amikha Prasad and Timothy J. O’Harehttp://www.elsevier.com/wps/find/journaldescription.cws_home/503313/description#descriptio
Estimating detection rates and probabilities
Quantitative Approaches Frith Jarrad, Samantha Low-Choy, Kerrie Mengersen ...
CAB International 2015. Biosecurity Surveillance: Quantitative Approaches (eds
1 Introduction to Biosecurity Surveillance: Quantitative Approaches
Murder on the mountain: author talk with Peter J. Wosh
Author talk by Peter J. Wosh on May 5th, 2022, on his book, "Murder on the Mountain: crime, passion, and punishment in gilded age New Jersey.
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