Biochemical compounds oxidation-reduction reactions

Without question, photosynthesis is the most important biochemical process on the Earth. With a few minor exceptions, photosynthesis is the only mechanism by which an external source of energy is harnessed by the living world. As with other energy-yielding processes, photosynthesis involves oxidation-reduction reactions. Water is the source of electrons and protons that reduce C02 to form organic compounds. Chapter 13 is devoted to a discussion of the principles of photosynthetic processes. The relationship between photosynthetic reactions and the structure of chloroplasts and the relevant properties of light are emphasized. 

Nicotinic acid is a B-complex vitamin that is converted to nicotinamide, NAD, and NADP. The latter two compounds are coenzymes and are required tor oxidation/reduction reactions in a variety of biochemical pathways. Additionally, nicotinic acid is metabolized to a number of inactive compounds, including nicotinuric acid and N-methylated derivatives. Normal biochemical regulation and feedback prevent large doses of nicotinic acid from producing excess quantities of NAD and NADP. Thus, small doses of nicotinic acid, such as those used tor dietary supplementation, will be primarily excreted as metabolites, whereas large doses, such as those used tor the treatment of hyperlipoproteinemia, will be primarily excreted unchanged by the kidney (15). 

Chemical reactions between biochemical compounds are enhanced by biological catalysts called enzymes, which consist mostly or entirely of globular proteins. In many cases a cofactor is needed to combine with an otherwise inactive protein to produce the catalytically active enzyme complex. The two distinct varieties of cofactors are coenzymes, which are complex organic molecules, and metal ions. Enzymes catalyze six major classes of reactions 1) Oxidoreductases (oxidation-reduction reactions), 2) Transferases (transfer of functional groups), 3) Hydrolases (hydrolysis reactions), 4) Lyases (addition to double bonds, 5) Isomerases (isomerization reactions) and 6) Ligases (formation of bonds with ATP (adenosine triphosphate) cleavage) [1]. 

Biotransformation refers to changes in xenobiotic compounds as a result of enzyme action. Reactions not mediated by enzymes may also be important. As examples of nonenzymatic transformations, some xenobiotic compounds bond with endogenous biochemical species without an enzyme catalyst, undergo hydrolysis in body fluid media, or undergo oxidation-reduction processes. However, the metabolic phase I and phase II reactions of xenobiotics discussed here are enzymatic. 

It is evident from the scheme shown in Fig. 3.21 that the chemical structures of pesticides are quite diverse they undergo various physico-chemical effects in the environment after application (solar radiation, heat, air, soil, water) as well as being subjected to various metabolic transformations in plants, microorganisms, insect and animals. Common metabolic transformations are schematically surveyed in Table 3.20, which shows that primarily oxidation, hydrogenation, reduction and hydrolytic reactions are concerned. Also among the individual chemical compounds mutual chemical reactions take place. Some examples of photochemical reactions of pesticides in water are presented in Figs 3.22 to 3.26. Biochemical reactions of DDT and DDE are shown in Fig. 3.27. The number of individual chemical species is hence significantly multiplied in the hydrosphere due... 

Oxidation and reduction are fundamental processes in the synthesis of organic and inorganic compounds. Some oxidation and reduction reactions are difficult to control in macro-scale batch reactors and in such cases microflow reactors serve as powerful tools for accomplishing the reactions in a highly controlled manner. This is especially true for many oxidation reactions because of their exothermic nature. It should also be noted that the danger of unexpected explosions can be avoided by the use of microflow reactors because of the small volume and highly efficient heat transfer ability of microflow systems. This chapter provides an overview of oxidation and reduction reactions using chemical, electrochemical and biochemical methods in microflow reactors. 

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