Immobilized chromatography

A form of chromatography in which the stationary phase is immobilized on a flat surface. 

Immunoaffinity chromatography utilizes the high specificity of antigen—antibody interactions to achieve a separation. The procedure typically involves the binding, to a soHd phase, of a mouse monoclonal antibody which reacts either directly with the protein to be purified or with a closely associated protein which itself binds the product protein. The former approach has been appHed in the preparation of Factor VIII (43) and Factor IX (61) concentrates. The latter method has been used in the preparation of Factor VIII (42) by immobilization of a monoclonal antibody to von WiHebrand factor [109319-16-6] (62), a protein to which Factor VIII binds noncovalenfly. Further purification is necessary downstream of the immunoaffinity step to remove... 

Immobilization. The abiUty of cyclodextrins to form inclusion complexes selectively with a wide variety of guest molecules or ions is well known (1,2) (see INCLUSION COMPOUNDS). Cyclodextrins immobilized on appropriate supports are used in high performance Hquid chromatography (hplc) to separate optical isomers. Immobilization of cyclodextrin on a soHd support offers several advantages over use as a mobile-phase modifier. For example, as a mobile-phase additive, P-cyclodextrin has a relatively low solubiUty. The cost of y- or a-cyclodextrin is high. Furthermore, when employed in thin-layer chromatography (tic) and hplc, cyclodextrin mobile phases usually produce relatively poor efficiencies. 

In recent years the solid-phase hydrosilylation reaction was successfully employed for synthesis of hydrolytically stable surface chemical compounds with Si-C bonds. Of special interest is application of this method for attachment of functional olefins, in particular of acrolein and some chiral ligands. Such matrices can be used for subsequent immobilization of a wide range of amine-containing organic reagents and in chiral chromatography. 

The enantioselective determination of 2,2, 3,3, 4,6 -hexachlorobiphenyl in milk was performed by Glausch et al. (21). These authors used an achiral column for an initial separation, followed by separation of the eluent fraction on a chiral column. Fat was separated from the milk by centrifugation, mixed with sodium sulfate, washed with petroleum ether and filtered. The solvent was evaporated and the sample was purified by gel permeation chromatography (GPC) and silica gel adsorption chromatography. Achiral GC was performed on DB-5 and OV-1701 columns, while the chiral GC was performed on immobilized Chirasil-Dex. 

Holzman, T. F., and Baldwin, T. O. (1982). Isolation of bacterial luciferases by affinity chromatography on 2,2-diphenylpropylamine-Sepharose phosphate-mediated binding to immobilized substrate analogue. Biochemistry 21 6194-6201. 

Active derivatives of forskolin include 7-deacetyl-forskolin (EC5o 20(llM), 6-acetyl-7-deacetyl-forskolin (EC5o 40(llIVI), 7-deacetyl-7-0-hemisuccinyl-forskolin (EC50 50(llIVI). The last of these has been used as an immobilized affinity chromatography ligand for the purification of adenylyl cyclases from tissues. 

The fact that adenosine and its derivatives are azo coupling components is used for immobilizing nicotinamide-adenine nucleotide (NAD+) for affinity chromatography purposes. In 12.58 NAD+ is bonded to a matrix through an azo bond. Compound 12.58 is used for the purification of dehydrogenase enzymes (Hocking and Harris, 1973). 

Affinity chromatography A form of chromatography in which separation is achieved by utilizing highly specific biochemical interactions, such as steric-or charge-related conditions, between me analyte and a molecule immobilized on a column. It is different from most forms of chromatography in mat analytes do not continuously elute from me column - only mose mat interact wim me stationary phase are retained and mus separated from omer components of me mixture under investigation. These immobilized materials are eluted from me column after all omer materials have been removed. 

An environmental protocol has been developed to assess the significance of newly discovered hazardous substances that might enter soil, water, and the food chain. Using established laboratory procedures and C-labeled 2,3,7,8-tetra-chlorodibenzo-p-dioxin (TCDD), gas chromatography, and mass spectrometry, we determined mobility of TCDD by soil TLC in five soils, rate and amount of plant uptake in oats and soybeans, photodecomposition rate and nature of the products, persistence in two soils at 1,10, and 100 ppm, and metabolism rate in soils. We found that TCDD is immobile in soils, not readily taken up by plants, subject to photodecomposition, persistent in soils, and slowly degraded in soils to polar metabolites. Subsequent studies revealed that the environmental contamination by TCDD is extremely small and not detectable in biological samples. 

The ELP expression system was compared to the conventional oligohistidme fusion, which is traditionally applied for purification by immobilized metal affinity chromatography (IMAC). Both techniques were shown to have a similar yield of the recombinant protein. The temperature-triggered approach offers a fast and inexpensive nonchromatographic separation with the possibility for larger scale purification. Although the ELP expression system may not be applicable to all types of recombinant proteins, numerous examples have already been shown [40]. 

Chromatography on immobilized reactive dyes (1-4 ml) was performed in 10 mM ammonium acetate buffer (pH 4 or 5) and elution followed with a linear 0-1 M NaCl gradient in the same buffer. 

Enzyme linked electrochemical techniques can be carried out in two basic manners. In the first approach the enzyme is immobilized at the electrode. A second approach is to use a hydrodynamic technique, such as flow injection analysis (FIAEC) or liquid chromatography (LCEC), with the enzyme reaction being either off-line or on-line in a reactor prior to the amperometric detector. Hydrodynamic techniques provide a convenient and efficient method for transporting and mixing the substrate and enzyme, subsequent transport of product to the electrode, and rapid sample turnaround. The kinetics of the enzyme system can also be readily studied using hydrodynamic techniques. Immobilizing the enzyme at the electrode provides a simple system which is amenable to in vivo analysis. 

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