Quinone-enhanced sonochemical production of nitric oxide from s-nitrosoglutathione

被引:3
作者
Alegria, Antonio E. [1 ]
Dejesus-Andino, Francisco J. [1 ]
Sanchez-Cruz, Pedro [1 ]
机构
[1] Univ Puerto Rico, Dept Chem, CUH Stn, Humacao, PR 00791 USA
来源
ULTRASONICS SONOCHEMISTRY | 2009年 / 16卷 / 01期
关键词
Sonochemical reduction; Sonochemistry; Quinones; Superoxide; Nitrosothiol; Nitric oxide; SATURATED AQUEOUS-SOLUTIONS; FREE-RADICAL FORMATION; XANTHINE-OXIDASE; ASCORBIC-ACID; ULTRASOUND; NITROSOTHIOLS; NO; GLUTATHIONE; REDUCTION; DECOMPOSITION;
D O I
10.1016/j.ultsonch.2008.05.009
中图分类号
O42 [声学];
学科分类号
070206 ; 082403 ;
摘要
Sonolysis at 75 kHz of argon- and air-saturated aqueous solutions at pH 7.4 containing s-nitrosogluthathione (GSNO) enhances the production rate of nitric oxide (NO). The quinones, anthraquinone-2-sulfonate (AQ2S) and anthraquinone-2,7-disulfonate (AQ27S) further enhance the NO production over that produced in quinone-depleted sonicated solutions. In contrast, the hydrophobic quinones juglone (JQ) and 1,4-naphthoquinone (NQ) inhibit ultrasound-induced No detection as compared to quinone-depleted solutions. Larger sonolytical decomposition of the hydrophobic quinones NQ and JQ, as compared to AQ2S and AQ27S, is detected which correlates with a larger production of pyrolysis-derived carbon-centered radicals. Reaction of those radicals with NO could explain NQ and JQ inhibition. This work suggests that sulfonated quinones could be used to enhance NO release from GSNO in tissues undergoing ultrasound irradiation. (C) 2008 Elsevier B.V. All rights reserved.
引用
收藏
页码:190 / 196
页数:7
相关论文
共 66 条
[11]   REACTIVITY OF NITRIC-OXIDE WITH SIMPLE SHORT-LIVED RADICALS IN AQUEOUS-SOLUTIONS [J].
CZAPSKI, G ;
HOLCMAN, J ;
BIELSKI, BHJ .
JOURNAL OF THE AMERICAN CHEMICAL SOCIETY, 1994, 116 (25) :11465-11469
[12]  
Dasgupta TP, 2002, METHOD ENZYMOL, V359, P219
[13]   DYNAMIC FREQUENCY SHIFTS AND EFFECTS OF MOLECULAR MOTIONS IN ELECTRON SPIN RESONANCE SPECTRA OF DINITROBENZENE ANION RADICALS [J].
FABER, RJ ;
FRAENKEL, GK .
JOURNAL OF CHEMICAL PHYSICS, 1967, 47 (07) :2462-&
[14]   Mechanisms of nitric oxide-related antimicrobial activity [J].
Fang, FC .
JOURNAL OF CLINICAL INVESTIGATION, 1997, 99 (12) :2818-2825
[15]  
FRICKE H., 1966, RAD DOSIMETRY, VII., P167
[16]   CONVERSION OF NITRIC-OXIDE INTO A NITROXIDE RADICAL USING 2,3-DIMETHYLBUTADIENE AND 2,5-DIMETHYLHEXADIENE [J].
GABR, IM ;
RAI, US ;
SYMONS, MCR .
JOURNAL OF THE CHEMICAL SOCIETY-CHEMICAL COMMUNICATIONS, 1993, (13) :1099-1100
[17]   ANALYSIS OF NITRATE, NITRITE, AND [N-15]-LABELED NITRATE IN BIOLOGICAL-FLUIDS [J].
GREEN, LC ;
WAGNER, DA ;
GLOGOWSKI, J ;
SKIPPER, PL ;
WISHNOK, JS ;
TANNENBAUM, SR .
ANALYTICAL BIOCHEMISTRY, 1982, 126 (01) :131-138
[18]   The role of NAD(P)H oxidoreductase (DT-diaphorase) in the bioactivation of quinone-containing antitumor agents: A review [J].
Gutierrez, PL .
FREE RADICAL BIOLOGY AND MEDICINE, 2000, 29 (3-4) :263-275
[19]   POTENTIATION OF CHEMOTHERAPY BY LOW-LEVEL ULTRASOUND [J].
HARRISON, GH ;
BALCERKUBICZEK, EK ;
EDDY, HA .
INTERNATIONAL JOURNAL OF RADIATION BIOLOGY, 1991, 59 (06) :1453-1466
[20]   SCAVENGING OF OH RADICALS PRODUCED IN THE SONOLYSIS OF WATER [J].
HENGLEIN, A ;
KORMANN, C .
INTERNATIONAL JOURNAL OF RADIATION BIOLOGY, 1985, 48 (02) :251-258
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