Your search keyword '"Dehuai, Chen"' showing total 4 results

1. Design and performances of prototype laser amplifiers for technical-integration-line facility

Author

Wanguo Zheng, Liangfu Guo, Xiaomin Zhang, Shaobo He, Donghui Lin, Jun Tang, Haiwu Yu, Dehuai Chen, Yizheng Li, Xiaofeng Wei, Yong Liu, Jiang Xuejun, Chengcheng Wang, and Hai Zhou

Subjects

Optical amplifier, Materials science, Aperture, business.industry, Amplifier, General Engineering, chemistry.chemical_element, Fusion power, Laser, Neodymium, Atomic and Molecular Physics, and Optics, Line (electrical engineering), law.invention, Optics, chemistry, law, business, Efficient energy use

Abstract

We present work on the design and physical performances for a large-aperture multisegment amplifier, which is an engineering prototype amplifier for our technical-integration-line facility. The amplifier consists of 4×2 apertures with each clear aperture about 300×300 mm. Each amplifier module consists of eight laser slabs, arranged four high, two wide, and one long, and twenty high-pulse power flashlamps with an input electric energy of about 23 kJ per lamp. These twenty flashlamps are arranged in a 6-8-6 scheme. The central eight flashlamps will irradiate their energy to the laser slabs in two directions to increase the pumping transfer efficiency. Experimental results indicated that the energy stored in the upper laser level is about 0.24 J/cm 3 , which corresponds to an energy storage efficiency of about 3.0%. Finally, with an 1.053-μm laser probe we obtained a small-signal gain coefficient of 5.0% cm –1 .

Published

2003

2. Raman spectroscopy of oxidized and reduced nicotinamide adenine dinucleotides

Author

Kwok To Yue, Dehuai Chen, Paula Nelson, Charlotte L. Martin, Robert Callender, and Donald L. Sloan

Subjects

biology, Nicotinamide, Chemistry, Molecular Conformation, Nicotinamide adenine dinucleotide, NAD, Spectrum Analysis, Raman, Photochemistry, Biochemistry, Redox, Cofactor, Structure-Activity Relationship, chemistry.chemical_compound, symbols.namesake, Crystallography, Ribose, symbols, biology.protein, Molecule, NAD+ kinase, Raman spectroscopy, Oxidation-Reduction

Abstract

We have measured the Raman spectra of oxidized nicotinamide adenine dinucleotide, NAD+, and its reduced form, NADH, as well as a series of fragments and analogues of NAD+ and NADH. In addition, we have studied the effects of pH as well as deuteration of the exchangeable protons on the Raman spectra of these molecules. In comparing the positions and intensities of the peaks in the fragment and analogue spectra with those of NADH and NAD+, we find that it is useful to consider these large molecules as consisting of component parts, namely, adenine, two ribose groups, two phosphate groups, and nicotinamide, for the purpose of assigning their spectral features. The Raman bands of NADH and NAD+ are found generally to arise from molecular motions in one or another of these molecular moieties, although some peaks are not quite so easily identified in this way. This type of assignment is the first step in a detailed understanding of the Raman spectra of NAD+ and NADH. This is needed to understand the binding properties of NADH and NAD+ acting as coenzymes with the NAD-linked dehydrogenases as deduced recently by using Raman spectroscopy.

Published

1986

3. Molecular properties of p-(dimethylamino)benzaldehyde bound to liver alcohol dehydrogenase: a Raman spectroscopic study

Author

Charlotte Martin, Robert Callender, Dehuai Chen, Donald Sloan, Robert Vandersteen, Kee Woo Rhee, Kwok To Yue, and Johan Lugtenburg

Subjects

chemistry.chemical_classification, Stereochemistry, Alcohol Dehydrogenase, Nicotinamide adenine dinucleotide, NAD, Spectrum Analysis, Raman, Biochemistry, Aldehyde, Benzaldehyde, Isotopic labeling, chemistry.chemical_compound, Crystallography, Liver, chemistry, Benzaldehydes, Animals, Molecule, Horses, Lewis acids and bases, Methylene, Oxidation-Reduction, Ternary complex, Protein Binding

Abstract

We have studied the binding nature of an aromatic aldehyde to the catalytic site of liver alcohol dehydrogenase from horse (LADH) using preresonance Raman spectroscopy. The compound p-(dimethylamino)benzaldehyde (DABA) is converted to the corresponding alcohol in the presence of nicotinamide adenine dinucleotide (NADH) and a catalytic amount of enzyme at neutral pH. A stable ternary complex of LADH/NADH/DABA can be formed if enzyme and coenzyme are in excess at high pH [Jagodzinski, P. W., Funk, G. F., & Peticolas, W. L. (1982) Biochemistry 21, 2193-2202]. We have obtained the preresonance Raman spectrum of bound DABA by subtracting the contribution of the binary complex of LADH/NADH from the spectrum of this stable ternary complex. In order to understand the normal mode patterns of DABA, four isotopically labeled DABA derivatives were synthesized and their Raman spectra, in solution and in the ternary complex, were measured. Three of these compounds contain substitutions in the functionally important aldehyde moiety: (i) In one such substitution, the aldehydic hydrogen atom was replaced by a deuterium; (ii) in another, this hydrogen atom was replaced by deuterium, and the aldehydic carbon atom was replaced by 13C; and (iii) in the third derivative, only the carbon atom was replaced by 13C. The fourth derivative has had the two hydrogen atoms at the 3- and 5-positions of the DABA ring replaced by deuterium atoms. We find that many of the spectral modes are fairly extended, involving both stretching and bending motions of the entire molecule, although a few modes are quite localized. We find that the normal mode structure of DABA changes considerably when it binds to LADH/NADH. As a model for the bound DABA, we have examined the zinc complexes of DABA (and all four isotopically labeled samples) in anhydrous diethyl ether and methylene chloride. A striking correspondence between the Raman spectra of the enzyme-bound DABA and DABA-Zn complexes in solution is found, which extends to all the isotopically labeled derivatives. This suggests that one of the major roles of LADH in the binding of DABA is to provide a divalent zinc ion to form a first-sphere Lewis acid complex. The data also suggest other interactions between enzyme-bound DABA with its protein surroundings and with the coenzyme NADH are quite minor. An estimate of the carbonyl bond character of bound DABA had been made on the basis of the response of Raman bands to isotopic labeling and on trends observed in spectra of DABA in solvents of various polarities.(ABSTRACT TRUNCATED AT 400 WORDS)

Published

1988

4. Classical Raman spectroscopic studies of NADH and NAD+ bound to liver alcohol dehydrogenase by difference techniques

Author

Dehuai Chen, Kwok To Yue, Charlotte Martin, Kee Woo Rhee, Donald Sloan, and Robert Callender

Subjects

Adenosine Diphosphate Ribose, biology, Nicotinamide, Stereochemistry, Alcohol Dehydrogenase, Active site, Nicotinamide adenine dinucleotide, Deuterium, NAD, Spectrum Analysis, Raman, Biochemistry, Cofactor, chemistry.chemical_compound, Kinetics, chemistry, Liver, Ribose, biology.protein, Coenzyme binding, NAD+ kinase, Oxidation-Reduction, Alcohol dehydrogenase, Protein Binding

Abstract

We report the Raman spectra of reduced and oxidized nicotinamide adenine dinucleotide (NADH and NAD+, respectively) and adenosine 5'-diphosphate ribose (ADPR) when bound to the coenzyme site of liver alcohol dehydrogenase (LADH). The bound NADH spectrum is calculated by taking the classical Raman difference spectrum of the binary complex, LADH/NADH, with that of LADH. We have investigated how the bound NADH spectrum is affected when the ternary complexes with inhibitors are formed with dimethyl sulfoxide (Me2SO) or isobutyramide (IBA), i.e., LADH/NADH/Me2SO or LADH/NADH/IBA. Similarly, the difference spectra of LADH/NAD+/pyrazole or LADH/ADPR with LADH are calculated. The magnitude of these difference spectra is on the order of a few percent of the protein Raman spectrum. We report and discuss the experimental configuration and control procedures we use in reliably calculating such small difference signals. These sensitive difference techniques could be applied to a large number of problems where the classical Raman spectrum of a "small" molecule, like adenine, bound to the active site of a protein is of interest. The spectrum of bound ADPR allows an assignment of the bands of the bound NADH and NAD+ spectra to normal coordinates located primarily on either the nicotinamide or the adenine moiety. By comparing the spectra of the bound coenzymes with model compound data and through the use of deuterated compounds, we confirm and characterize how the adenine moiety is involved in coenzyme binding and discuss the validity of the suggestion that the adenine ring is protonated upon binding. The nicotinamide moiety of NADH shows significant molecular changes upon binding.(ABSTRACT TRUNCATED AT 250 WORDS)

Published

1987