Lactate dehydrogenase determination

The absorbance change (AM) at 340 nm can be used to determine the amount of pymvate remaining. The lactate dehydrogenase [9001-60-9] catalyzed reaction can also be used in the reverse direction to measure lactate. The reaction takes place in a buffer of pH 9—10 that neutralizes Hberated H". ... 

In addition to enzyme activity, the concentration of an nonelectroactive substrate can be determined electrochemically by this technique. By keeping the substrate (analyte) the limiting reagent, the amount of product produced is directly related to the initial concentration of substrate. Either kinetic or equilibrium measurements can be used. Typically an enzyme which produces NADH is used because NADH is readily detected electrochemically. Lactate has been detected using lactate dehydrogenase, and ethanol and methanol detected using alcohol dehydrogenase... 

Many dehydrogenase enzymes catalyze oxidation/reduction reactions with the aid of nicotinamide cofactors. The electrochemical oxidation of nicotinamide adeniiw dinucleotide, NADH, has been studied in depthThe direct oxidation of NADH has been used to determine concentration of ethanol i s-isv, i62) lactate 157,160,162,163) pyTuvate 1 ), glucose-6-phosphate lactate dehydrogenase 159,161) alanine The direct oxidation often entails such complications as electrode surface pretreatment, interferences due to electrode operation at very positive potentials, and electrode fouling due to adsorption. Subsequent reaction of the NADH with peroxidase allows quantitation via the well established Clark electrode. 

The concentration of hydroxypyruvate was determined by spectrophotometry at 340 nm. A 20 pL aliquot from the reaction mixture was introduced into 1 mL of triethanolamine buffer (0.1 m) at pH 7.6 containing 20 /rL of NADH solution in water (14 mm, 0.28 /imol) and 2 units of L-lactate dehydrogenase. The absorbance due to NADH is proportional to the concentration of hydroxypyruvate. 

Determination of the level of cytosolic enzymes such as aspartate transaminase, alanine transaminase, and lactate dehydrogenase is part of standard biochemical liver function tests to measure hepatocellular necrosis [2, 101]. Cytosolic enzymes are not subject to genetic variations inherent in microsomal enzyme production. Liver cytosolic enzymes metabolize several molecules, of which galactose and amino acids are typical examples, used for hepatic function tests. 

The now classical example is lactate dehydrogenase. Sil-verstein and Boyer were the first to determine the rates of exchange between cognate pairs of reactants ie., lactate and pyruvate as well as NAD and NADH). Convenient [NADH]/[NAD ] and [pyruvate]/[lactate] ratios were chosen such that when combined they satisfied the apparent equilibrium constant for the LDH reaction. These investigators first established that each exchange rate was directly proportional to the duration of exchange and likewise directly proportional to enzyme concentration. As an additional control, they also demonstrated the equality of the pyruvate lactate exchange... 

Amplification of the sensitivity of substrate or co-en me recycling is especially efficient in thermometric analysis since all the reactions involved frequently contribute to increasing the overall temperature change. One case in point is the determination of lactate or pyruvate by substrate recycling using co-immobilized lactate oxidase and lactate dehydrogenase [160]. 

RGURE 7 An oxidation-reduction reaction. Shown here is the oxidation of lactate to pyruvate. In this dehydrogenation, two electrons and two hydrogen ions (the equivalent of two hydrogen atoms) are removed from C-2 of lactate, an alcohol, to form pyruvate, a ketone. In cells the reaction is catalyzed by lactate dehydrogenase and the electrons are transferred to a cofactor called nicotinamide adenine dinucleotide. This reaction is fully reversible pyruvate can be reduced by electrons from the cofactor. In Chapter 13 we discuss the factors that determine the direction of a reaction. 

Reasons for the presence of enzymes in the plasma Enzymes can normally be found in the plasma either because they were specifically secreted to fulfill a function in the blood, or because they were released by dead or damaged cells. Many diseases that cause tissue damage result in an increased release of intracellular enzymes into the plasma. The activities of many of these enzymes (for example, creatine kinase, lactate dehydrogenase, and alanine aminotransferase) are routinely determined for diagnostic purposes in diseases of the heart, liver, skeletal muscle, and other tissues. 

Most NAD+- or NADP+- dependent dehydrogenases are dimers or trimers of 20- to 40-kDa subunits. Among them are some of the first enzymes for which complete structures were determined by X-ray diffraction methods. The structure of the 329-residue per subunit muscle (M4) isoenzyme of lactate dehydrogenases (see Chapter 11) from the dogfish was determined to 0.25 nm resolution by Rossmann and associates in 1971.2 1 More recently, structures have been determined for mammaliam muscle and heart type (H4) isoenzymes,5 for the testicular (C4) isoenzyme from the... 

A key structural and mechanistic feature of lactate and malate dehydrogenases is the active site loop, residues 98-110 of the lactate enzyme, which was seen in the crystal structure to close over the reagents in the ternary complex.49,50 The loop has two functions it carries Arg-109, which helps to stabilize the transition state during hydride transfer and contacts around 101-103 are the main determinants of specificity. Tryptophan residues were placed in various parts of lactate dehydrogenase to monitor conformational changes during catalysis.54,59,60 Loop closure is the slowest of the motions. 

Raman spectroscopy can offer a number of advantages over traditional cell or tissue analysis techniques used in the field of TE (Table 18.1). Commonly used analytical techniques in TE include the determination of a specific enzyme activity (e.g. lactate dehydrogenase, alkaline phosphatase), the expression of genes (e.g. real-time reverse transcriptase polymerase chain reaction) or proteins (e.g. immunohistochemistry, immunocytochemistry, flow cytometry) relevant to cell behaviour and tissue formation. These techniques require invasive processing steps (enzyme treatment, chemical fixation and/or the use of colorimetric or fluorescent labels) which consequently render these techniques unsuitable for studying live cell culture systems in vitro. Raman spectroscopy can, however, be performed directly on cells/tissue constructs without labels, contrast agents or other sample preparation techniques. 

The methodology normally used for the determination of dead cell concentrations is the dye exclusion method (Freshney, 1994), although this is not adequate in cases in which cellular lysis is significant. In these situations, other methodologies must be adopted to determine the amount of lysed cells, such as, for example, the measure of the lactate dehydrogenase concentration (LDH) in the culture medium (Freshney, 1994 Miller and Reddy, 1998). 

Generally, low molecular mass permeation enhancers can be divided into transcellular and paracellular permeation enhancers. On the one hand the potential of permeation enhancers to open the paracellular route of uptake can be determined by the reduction in the transepithelial electrical resistance (TEER) (enhancement potential = EP). On the other hand the potential of permeation enhancers to open the transcellular route of uptake can be determined by the lactate dehydrogenase (LDH) assay (LDH potential = LP). The parameter K = (EP—LP)/EP represents the relative contribution of the paracellular pathway. Consequently, a K value of 0 means predominantly transcellular and a K value of 1 means predominantly paracellular. Based on this classification system Whitehead and Mitragotri classified over 50 low molecular mass permeation enhancers showing that most of them are paracellular and only a few of them are transcellular permeation enhancers (2008). 

---