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Specific Detection Methods 1 Activation Reactions

Jork, H. Funk, W. Fischer, W. Wimmer, H. Specific Detection Methods. In Thin-Layer Chromatography agents and Detection Methods, Physical and ChemicaB Detection Methods Activation Reactions, Reagents Se-J quences. Reagents II VCH Weinheim, Germany, 1994q Vol. lb, 11-140. I,... [Pg.1117]

This volume is divided into two parts which encompass about the same amount of material as Volume 1 a. Thus Part I begins with specific detection methods including the known photochemical, thermochemical and electrochemical activation methods. Here microchemical reactions are described that are carried out without the use of reagents. Detection involves the use of light, heat and electric current. [Pg.3]

The discussion above was concerned with the effects of solution conditions on enzyme activity, hence reaction velocity. Equally important for the purpose of assay design is the influence of specific solution conditions on the detection method being used. This latter topic is beyond the scope of the present text. Nevertheless, this is an important issue for screening scientists whose job is often to balance the needs of biochemical rigor and assay practicality in development of an HTS assay. An... [Pg.93]

Fig. 3. Comparison of different enzyme-linked immuno sorbent assay (ELISA) methods adapted for immuno-polymerase chain reaction (IPCR). Dependent on the purification grade of the sample to be analyzed and the availability of specific and functionalized antibodies, several typical ELISA protocols were adapted to IPCR. In the direct approach (A), the pure antigen is immobilized to the microplate surface and subsequently detected by a labeled specific antibody. If no labeled antibody is available (e.g., because of unpurified ascites fluid containing the antibody or loss in activity following labeling), a standardized labeled secondary species-specific antibody is used for detection of the primary antigen-specific antibody (B). For the detection of the antigen from matrices such as serum, plasma, tissue homogenate, and so on, a capture antibody immobilized to the microplate surface was used either in a direct (C) or indirect (D) sandwich approach, with the latter one additionally including a secondary species-specific detection antibody. For different methods of coupling antibody and DNA, abbreviated by in this figure, compare Fig. 2. Note that protein A chimeras (Fig. 2A) are not compatible with capture antibodies (Fig. 3C, D). Fig. 3. Comparison of different enzyme-linked immuno sorbent assay (ELISA) methods adapted for immuno-polymerase chain reaction (IPCR). Dependent on the purification grade of the sample to be analyzed and the availability of specific and functionalized antibodies, several typical ELISA protocols were adapted to IPCR. In the direct approach (A), the pure antigen is immobilized to the microplate surface and subsequently detected by a labeled specific antibody. If no labeled antibody is available (e.g., because of unpurified ascites fluid containing the antibody or loss in activity following labeling), a standardized labeled secondary species-specific antibody is used for detection of the primary antigen-specific antibody (B). For the detection of the antigen from matrices such as serum, plasma, tissue homogenate, and so on, a capture antibody immobilized to the microplate surface was used either in a direct (C) or indirect (D) sandwich approach, with the latter one additionally including a secondary species-specific detection antibody. For different methods of coupling antibody and DNA, abbreviated by in this figure, compare Fig. 2. Note that protein A chimeras (Fig. 2A) are not compatible with capture antibodies (Fig. 3C, D).
In 2000, Nohta et al. described a method for the determination of biologically active polyamines by intramolecular excimer-forming derivatization with 4-(l-Pjo ene)butyric acid N-hydroxysuccinimide ester (PSE) [34], By this method, dipyrene-labeled putrescine, cadaverine, spermidine, and spermine could be separated by reversed-phase liquid chromatography and specifically detected by the excimer fluorescence at 475 nm with excitation at 345 nm. The excimer fluorescence-emission wavelength is far different from that of the monomer fluorescence-emission wavelength (375 nm) derived from the excess PSE reagent, the hydrolysate product (4-(l-pyrene)butyric acid), and other monopyrene-labeled derivatives. In real biological samples, various monopyrene-labeled derivatives are formed by reaction with PSE and severely interfere with the determination of polyamines. [Pg.140]

Generally, few limitations for these systems have been explored in the literature, including damaging of the sensor by any factor that will affect the enzymatic activity or other reactions used in the method and the inability to recognize the inhibitor using such cholinesterase-based sensor. Therefore, in addition to cholinesterase-based sensors, many other sensors and methods have been developed and used to delect anti-ChEs in the past, each with its own advantages and disadvantages (reviewed by Kim et al., 2011). Anti-ChE detection methods thus should be tailored to the specific anti-ChEs and the requirements from the sensor. [Pg.772]

The detection of reactions mediated by specific IgE to agents triggering anaphylaxis may be achieved by means of serological methods serum-specific IgE, or by means of cellular tests which determine the release of basophil mediators (leukotrienes and histamine) or by means of the analysis of basophil expression markers, a technique known as the basophil activation test (BAT). [Pg.128]

Monitoring enzyme catalyzed reactions by voltammetry and amperometry is an extremely active area of bioelectrochemical interest. Whereas liquid chromatography provides selectivity, the use of enzymes to generate electroactive products provides specificity to electroanalytical techniques. In essence, enzymes are used as a derivatiz-ing agent to convert a nonelectroactive species into an electroactive species. Alternatively, electrochemistry has been used as a sensitive method to follow enzymatic reactions and to determine enzyme activity. Enzyme-linked immunoassays with electrochemical detection have been reported to provide even greater specificity and sensitivity than other enzyme linked electrochemical techniques. [Pg.28]

Although following similar nuclear reaction schemes, nuclear analytical methods (NAMs) comprise bulk analysing capability (neutron and photon activation analysis, NAA and PAA, respectively), as well as detection power in near-surface regions of solids (ion-beam analysis, IB A). NAMs aiming at the determination of elements are based on the interaction of nuclear particles with atomic nuclei. They are nuclide specific in most cases. As the electronic shell of the atom does not participate in the principal physical process, the chemical bonding status of the element is of no relevance. The general scheme of a nuclear interaction is ... [Pg.662]

Another approach has been to immobilize proteins within arrays of microfabricated polyacrylamide gel pads (Arenkov et al., 2000). Nanoliters of protein solutions are transferred to 100 x 100 x 20-pM gel pads and assayed with antibodies that are labeled with a fluorescent tag. Antigen imbedded in the gel pads can be detected with high sensitivity and specificity (Arenkov et al., 2000). Furthermore, enzymes such as alkaline phosphatase can be immobilized in the gel pads and enzymatic activity is readily detected upon the addition of an indicator substrate. The main advantage of the use of the threedimensional gel pad for fixation of proteins is the large capacity for immobilized molecules. In addition, the pads in the array are separated from one another by a hydrophobic surface. Thus, each pad behaves as a small test tube for assay of protein-protein interactions and enzymatic reactions (Arenkov et al., 2000). The disadvantage of the method is the need to microfabricate the array of gel pads in that microfabrication is... [Pg.96]


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Activation methods

Active detection

Detection methods

Method specificity

Reaction detection

Reaction methods

Reaction specificity

Specific activation

Specific activity

Specification activity

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