Isoluminol

Chemiluminescent Immunoassay. Chemiluminescence is the emission of visible light resulting from a chemical reaction. The majority of such reactions are oxidations, using oxygen or peroxides, and among the first chemicals studied for chemiluminescence were luminol (5-amino-2,3-dihydro-l,4-phthalazinedione [521-31-3]) and its derivatives (see Luminescent materials, chemiluminescence). Luminol or isoluminol can be directly linked to antibodies and used in a system with peroxidase to detect specific antigens. One of the first appHcations of this approach was for the detection of biotin (31). 

Luminol (Phthalhydrazide). Chemiluminescence from luminol [521-31-3] (3-aminophthalhydrazide) (29), isoluminol [3682-14-2] (4-aminophthalhydrazide), and analogues has been studied extensively (104—106). 

ImmunO lSS iy. Chemiluminescence compounds (eg, acridinium esters and sulfonamides, isoluminol), luciferases (eg, firefly, marine bacterial, Benilla and Varela luciferase), photoproteins (eg, aequorin, Benilld), and components of bioluminescence reactions have been tested as replacements for radioactive labels in both competitive and sandwich-type immunoassays. Acridinium ester labels are used extensively in routine clinical immunoassay analysis designed to detect a wide range of hormones, cancer markers, specific antibodies, specific proteins, and therapeutic dmgs. An acridinium ester label produces a flash of light when it reacts with an alkaline solution of hydrogen peroxide. The detection limit for the label is 0.5 amol. 

Figure 4 Chemical structure of (A) luminol (5-amino-2,3- dihydro-l,4-phthalazinedi-one) and (B) isoluminol.

The unsubstituted phthalic acid hydrazide and several nonaromatic cyclic hydrazides such as maleic acid hydrazide or succinic acid hydrazide are either nonchemiluminescent or show extremely weak CL. However, the 6-amino isomer of luminol, which is called isoluminol, is chemiluminescent to about the same extent as is luminol. Isoluminol has been used in many chemiluminescent studies, and because the amino group is less sterically hindered than that of luminol, it is probably derivatized for chemiluminescent labeling far more often than is luminol (Fig. 3). 

Amino acids Microperoxidase-catalyzed Isoluminol- H202 Borate buffer (pH 9.3)... 

ABEI, M(4-ami nobutyl )-Methylisolu mi nol BSA, bovine serum albumin CL, chemiluminescence DNPO, tas-(2,4-dinitrophenyl)oxalate ECL, electrogenerated chemiluminescence EMMA, electrophoretically mediated microanalysis EY, eosine Y FR, lluorescamine HRP, horseradish peroxidase ILITC, isoluminol isothiocyanate LOD, limit of detection RITC, rhodamine B isothiocyanate TCPO, Mv-(2,4,6-trichlorophenyl)oxalate TEA, triethylamine TRITC, tetramethylrhodamine isothiocyanate. 

Obviously, the main purpose for the introduction of CL detection coupled to CE separations is inherent to the development and improvement of sensitive and uncomplicated devices to achieve a decrease of the band broadening caused by turbulence at the column end, together with the attractive separation efficiency of CE setups. With this purpose in mind, Zhao et al. [83] designed a postcolumn reactor for CL detection in the capillary electrophoretic separation of isoluminol thiocarbamyl derivatives of amino acids, because, like other isothiocyanates, isoluminol isothiocyanate has potential applications in the protein-sequencing area. 

The elimination of turbulent mixing in the flow chamber and the short residence time of the reaction mixture in the detection chamber provided a high separation efficiency of 100,000 theoretical plates for labeled amino acids, obtaining good resolution in comparison with previous CL detectors [79, 82], For the isoluminol thiocarbamyl derivative of valine, a detection limit of 500 amol was reported however, it was not possible to separate all 20 isoluminol-deriva-tized amino acids. 

The CLD methods for HPLC using isoluminol (190) with microperoxidase catalysis, for determination of lipid hydroperoxides in clinical fluids, have been reviewed. Determination of phospholipids hydroperoxides by luminol (124) CL has been reviewed . A fast RP-HPLC method (retention times 1 to 2 min) for determination of hydroperoxides and other peroxide compounds includes UVD, which is not always effective, and CLD, attained on injection of luminol (124), the CL reagent (Scheme 3), hemin (75a), a catalyst, and NaOH to raise the pH of the solution. A FLD cell may act as CLD cell if the excitation source is turned off. The selectivity of CLD is of advantage over UVD in industrial analysis thus, for example, UVD of a sample from a phenol production line based on cumene oxidation (equation 13) shows peaks for cumyl hydroperoxide (27), unreacted cumene, cumyl alcohol and acetophenone, whereas CLD shows only the 27 peak. The... 

A procedure for determination of lipid hydroperoxides in human plasma is based on kinetic measurement of the CL of luminol (124) with hemin (75a) catalysis . CLD of microperoxidase-catalyzed oxidation of luminol (124) or isoluminol (190) was applied to detection and determination of amino acid hydroperoxides after exposure to UV and y-irradiation A method for determination of hydroperoxides in the phospholipids of cultured cells uses isoluminol (190) and microperoxidase as catalyst " . Simultaneous determination of phosphatidylcholine hydroperoxides and cholesteryl ester hydroperoxides in human serum is carried out by quantitative extraction of the lipids, HPLC separation by column switching and CLD using isoluminol (190) with microperoxidase catalysis . ... 

Isolimonene, artemisinin synthesis, 277 Isoluminol, lipid hydroperoxide determination, 680, 681 Isomerization aUyhc alcohols, 789-90 y-chlordene, 728... 

ABEI, N-(4-aminobutyl)-N-ethyl isoluminol CLIA, chemiluminescence immunoassay SPE, solid-phase extraction MSPD, matrix solid-phase dispersion RP, reversed phase. 

Amino acids TCP0-H202-Dansyl chloride Borate buffer (pH 8.9) Microperoxidase-catalyzed Isoluminol- H202 Borate buffer (pH 9.3) Postcolumn CL detector 1.2 fmol (for L-arginine) 78... 

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