Imidazole chemiluminescence

ICSC (International Chemical Safety Cards), 747, 749, 753-5 IgB (gamma-globulin), 655 Illumination, deterioration evaluation, 656 Imidazole chemiluminescence, 647 peroxy oxalates, 1189, 1190, 1256-7, 1259-61, 1263, 1265... 

REPETITIVE ASSAY FOR ENHANCED DETECTION OF IMMOBILIZED HORSERADISH PEROXIDASE BY IMIDAZOLE CHEMILUMINESCENCE... 

Nozfiki O, Kawamoto H. Determination of hydrogen peroxide by micro-flow injection-horseradish peroxidase catalyzed "imidazole chemiluminescence". In Stanley PE, Kricka LJ. eds. Bioluminescence Chemiluminescence- Progress Current Applications. Singapore World Scientific, 2002 335-8. 

DETERMINATION OF PYROGALLOL BY IMIDAZOLE CHEMILUMINESCENCE ENHANCED WITH HYDROGEN PEROXIDE... 

Determination of pyrogallol. Pyrogallol was assayed by HRP catalyzed imidazole chemiluminescence coupled to the micro-flow injection system at room temperature. Pyrogallol specimens (50 pL) were injected using an autosampler (AS-950, JASCO, Tokyo, Japan) every five min into a stream of water (100 uL/min) using a HPLC pump (PU-980, JASCO), and the other mobile phase (imidazole 100 mmol/L in the Tricine buffer 50 mmol/L, pH 9.3) was delivered at 100 pL/min. The light emitted from the reactor tube was detected with a... 

Fig. 2. Influence of concentration of H202on enhancement of detection of pyrogallol by imidazole chemiluminescence.

Nozaki O, Munesue M, Kawamoto H. Determination of serum glucose by horseradish peroxidase-catalysed imidazole chemiluminescence coupled to a micro-flow-injection system. Luminescence. 2007 22 401-6. 

Most peroxyoxalate chemiluminescent reactions are catalyzed by bases and the reaction rate, chemiluminescent intensity, and chemiluminescent lifetime can be varied by selection of the base and its concentration. Weak bases such as sodium saUcylate or imidazole are generally preferred (94). 

Figure 11. Time-dependent emission for aqueous acetonitrile chemiluminescence of TCPO-H2O2-imidazole system measured at 430 nm.

Me Capra in particular proposed n> that the chemiluminescence reactions of a large number of organic compounds had this concerted dioxetane decomposition step as key reaction in the production of electronically excited products, namely acridinium salts 25,26,27) indolylperoxides 28>, activated oxalic esters 29>, diphenyl carbene 30>, tetrakis-dimethylamino-ethylene 31 32>, lucigenin 33>, and substituted imidazoles 23>. 

In Latia bioluminescence the ketone 121 was detected as product. Similarly, the chemiluminescence of imidazol-pyridinones 125 represents a model for Cypridina bioluminescence 181>. 

Following the disclosure of the outstanding catalytic ability of imidazole compared to other bases, the catalysis of the POCL reaction by imidazole was studied in more detail [163], and it was concluded that the POCL reaction mechanism included the concurrent catalysis by two imidazole molecules, by what was described as general-base and nucleophilic pathways, respectively. The mechanism for this was suggested to be a base catalysis of imidazole catalysis by imidazole itself as previously reported for imidazole-catalyzed reaction of esters [164, 165], Despite this, it was not until the introduction [151] of 1,1 -oxalyldiimidazole (ODI) as a chemiluminescence reagent, and the postulation of its intermediate appearance in the imidazole-catalysed POCL reaction, that the... 

Di-(2-pyridyl)-lff-imidazol-2-yl] phenylboronic acid, chemiluminescence reagent enhancer, 5 845... 

Since its discovery by Chandross and to this day, peroxy-oxalate chemiluminescence has been controversial because of its enormous complexity in view of the many alternative steps involved in this process. The principal mechanistic feature of the peroxy-oxalate chemiluminescence pertains to the base-catalyzed (commonly imidazole) reaction of an activated aryl oxalate with hydrogen peroxide in the presence of a chemiluminescent activator, usually a highly fluorescent aromatic hydrocarbon with a low oxidation potential . A variety of putative high-energy peroxide intermediates have been proposed for the generation of the excited states . In the context of the present chapter, it is of import to mention that recent work provides experimental evidence for the intervention of the 1,2-dioxetanedione 18 (Scheme 11) as the high-energy species responsible for the chemiexcitation. Furthermore, clear-cut experimental data favor the CIEEL mechanism as a rationalization of the peroxy-oxalate chemiluminescence . 

The main features of the chemiluminescence mechanism are exemplarily illustrated in Scheme 11 for the reaction of bis(2,4,6-trichlorophenyl)oxalate (TCPO) with hydrogen peroxide in the presence of imidazole (IMI-H) as base catalyst and the chemiluminescent activators (ACT) anthracene, 9,10-diphenylanthracene, 2,5-diphenyloxazole, perylene and rubrene. In this mechanism, the replacement of the phenolic substituents in TCPO by IMI-H constitutes the slow step, whereas the nucleophilic attack of hydrogen peroxide on the intermediary l,l -oxalyl diimidazole (ODI) is fast. This rate difference is manifested by a two-exponential behavior of the chemiluminescence kinetics. The observed dependence of the chemiexcitation yield on the electrochemical characteristics of the activator has been rationalized in terms of the intermolecular CIEEL mechanism (Scheme 12), in which the free-energy balance for the electron back-transfer (BET) determines whether the singlet-excited activator, the species responsible for the light emission, is formed ... 

An indirect method has been used to determine relative rate constants for the excitation step in peroxyoxalate CL from the imidazole (IM-H)-catalyzed reaction of bis(2,4,6-trichlorophenyl) oxalate (TCPO) with hydrogen peroxide in the presence of various ACTs . In this case, the HEI is formed in slow reaction steps and its interaction with the ACT is not observed kinetically. However, application of the steady-state approximation to the reduced kinetic scheme for this transformation (Scheme 6) leads to a linear relationship of l/direct measure of the rate constant of the excitation step. 

On the basis of the results discussed above, it is possible to propose a detailed mechanistic scheme for the occurrence of the chemiluminescent reaction of oxalic esters and hydrogen peroxide in the presence of imidazole as base and an ACT (Scheme 40). The oxalic ester (exemplified with TCPO) reacts in the rate-determining step with imidazole, catalyzed by... 

Stevani and coworkers prepared and characterized a peracid intermediate, 4-chloro-pheny 1-0,0-hydrogen monoperoxalate (57) and found that no chemiluminescence was observed in the presence of activators (i.e. rubrene, perylene and DPA) and the absence of a base. Based on this result, the authors excluded 57 and similar peracid derivatives as HEI in the peroxyoxalate system. Moreover, 57 only emits light in the presence of an activator and a base with pK > 6, suggesting that a slow chemical transformation must still occur prior to the chemiexcitation step. Kinetic experiments with 57, using mainly imidazole, but also in the presence of other bases such as potassium 4-chlorophenolate, f-butoxide and l,8-bis(dimethylamino)naphthalene , showed that imidazole can act competitively as base and nucleophilic catalyst (Scheme 41). At low imidazole concentrations, base catalysis is the main pathway (steps 1 and 2) however, increasing the base concentration causes nucleophilic attack of imidazole catalyzed by imidazole to become the main pathway (steps la and 2a). Contrary to the proposal of Hohman and coworkers , the... 

The peroxyoxalate system is the only intermolecular chemiluminescent reaction presumably involving the (71EEL sequence (Scheme 44), which shows high singlet excitation yields (4>s), as confirmed independently by several authors Moreover, Stevani and coworkers reported a correlation between the singlet quantum yields, extrapolated to infinite activator concentrations (4> ), and the free energy involved in back electron-transfer (AG bet), as well as between the catalytic electron-transfer/deactivation rate constants ratio, ln( cAx( i3), and E j2° (see Section V). A linear correlation of ln( cAx( i3) and E /2° was obtained for the peroxyoxalate reaction with TCPO and H2O2 catalyzed by imidazole and for the imidazole-catalyzed reaction of 57, both in the presence of five activators commonly used in CIEEL studies (anthracene, DPA, PPO, perylene and rubrene). A further confirmation of the validity of the CIEEL mechanism in the excitation step of... 

Imidazole, l,2,5-trimethyl-4-nitro-mass spectra, 5, 359 Imidazole, 1-trimethylsilyl-reactions, 5, 454 with acid chlorides, 5, 391 Imidazole, 1-trimethylstannyl-reactions, 5, 454 Imidazole, 2,4,5-trinitro-reactions, 5, 98 synthesis, 5, 395 Imidazole, 1,2,4-triphenyl-UV spectra, 5, 356 Imidazole, 1,2,5-triphenyl-UV spectra, 5, 356 Imidazole, 2,4,5-triphenyl-chemiluminescence, 5, 381, 406 irradiation, 5, 433 oxidation, 5, 376, 406 photochemical addition reactions, 5, 421 synthesis, 5, 467, 483 UV spectra, 5, 356, 357 Imidazole, 1-trityl-rearrangement, 5, 377 Imidazole, vinyl-Michael addition, 5, 437 polymers, 1, 281 Imidazole, 1-vinyl-reactions, 5, 450 thermal rearrangement, 5, 450 Imidazole, 2-vinyl-oxidation, 5, 437 Imidazole, l-(D-xylofuranosyl)-synthesis, 5, 491 277-Imidazole, 2,2-dialkyl-rearrangement, 5, 422 277-Imidazole, 4,5-dicyano-2,2-dimethyl-synthesis, 5, 472... 

Imai et al. studied the catalytic effect of imidazole and other bases on the peroxyoxalate chemiluminescence reaction for HPLC [49]. The peak height of dipyridamole obtained using the eluent containing buffers was largest at pH 7, a few times less at pH 6 and pH 5, 100 times less at pH 4,... 

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