Chemically synthesized

CH2Br COOH. White crystalline solid, m.p. 50"C, b.p. 208 C. Soluble in water and alcohol. Prepared by the action of dry bromine on dry ethanoic acid in presence of small amounts of red phosphorus. Produces sores upon the skin used in chemical syntheses. See Reformatski reaction. 

Buhro W E, Hickman K M and Trentler T J 1996 Turning down the heat on semiconductor growth—solution chemical syntheses and the solution-liquid-solid mechanism Adv. Mater. 8 685... 

The use of computers for the design of chemical syntheses was first demonstrated by Corey and Wipke in 1969 with their program OCCS [30]. The successor to OCCS, LHASA [31], is generally considered to be the first synthon-based system. Its development is still going on. Currently, three groups are working on LHASA, one at Harvard University, USA [32], one at the University of Leeds, UK [33], and... 

Ethyl acetoacetate is a colourless liquid, d, i 03, slightly soluble in water, but almost insoluble in brine. It has a faint but pleasant odour. It is widely used in chemical syntheses. 

Uses. Butyrolactone is principally consumed by the manufacturers by reaction with methylamine or ammonia to produce A/-meth5d-2-pyrrohdinone [872-50-4] and 2-pyrrohdinone [616-45-5] C H NO, respectively. Considerable amounts are used as a solvent for agricultural chemicals and polymers, in dyeing and printing, and as an intermediate for various chemical syntheses. 

The modem fermentation industries developed from the early era of antibiotics. Over 4000 antibiotics have been discovered since the 1950s. However, only about 100 are produced on a commercial scale and over 40 of these are prepared by a combination of microbial synthesis and chemical modifications. Antibiotics produced by fermentation and used as starting materials in chemical syntheses are given in Table 2. 

Table 2. Antibiotics Used as Starting Materials for Chemical Syntheses ...

Chemically synthesized antimicrobials used in animal and poultry feeds include arsenicals, eg, arsanilic acid [98-50-0] sodium arsanilate [127-85-5] and roxarsone [121-19-7]-, sulfa dmgs, eg, sulfadimethoxine [122-11-2], sulfamethazine [57-68-1], and sulfathiazole [72-14-0]-, carbadox [6804-07-5]-, and nitrofurans, eg, furazoHdone [67 5-8] and nitrofurazone [59-87-0] (see Antibacterial agents, synthetic Antiparasitic agents). 

Anhydrous hydrazine, required for propellant appHcations and some chemical syntheses, is made by breaking the hydrazine—water azeotrope with aniline. The bottom stream from the hydrate column (Fig. 4) is fed along with aniline to the azeotrope column. The overhead aniline—water vapor condenses and phase separates. The lower aniline layer returns to the column as reflux. The water layer, contaminated with a small amount of aniline and hydrazine, flows to a biological treatment pond. The bottoms from the azeotrope column consist of aniline and hydrazine. These are separated in the final hydrazine column to give an anhydrous overhead the aniline from the bottom is recycled to the azeotrope column. 

Enzymatic Method. L-Amino acids can be produced by the enzymatic hydrolysis of chemically synthesized DL-amino acids or derivatives such as esters, hydantoins, carbamates, amides, and acylates (24). The enzyme which hydrolyzes the L-isomer specifically has been found in microbial sources. The resulting L-amino acid is isolated through routine chemical or physical processes. The D-isomer which remains unchanged is racemized chemically or enzymatically and the process is recycled. Conversely, enzymes which act specifically on D-isomers have been found. Thus various D-amino acids have been... 

Enzymatic Process. Chemically synthesized substrates can be converted to the corresponding amino acids by the catalytic action of an enzyme or the microbial cells as an enzyme source, t - Alanine production from L-aspartic acid, L-aspartic acid production from fumaric acid, L-cysteine production from DL-2-aminothiazoline-4-catboxyhc acid, D-phenylglycine (and D-/> -hydtoxyphenylglycine) production from DL-phenyUiydantoin (and DL-/)-hydroxyphenylhydantoin), and L-tryptophan production from indole and DL-serine have been in operation as commercial processes. Some of the other processes shown in Table 10 are at a technical level high enough to be useful for commercial production (24). Representative chemical reactions used ia the enzymatic process are shown ia Figure 6. 

Production figures for the aminophenols are scarce, the compounds usually being classified along with many other aniline derivatives (86). Most production of the technical grade materials (95% purity) occurs on-site as they are chiefly used as intermediate reactants in continuous chemical syntheses. World production of the fine chemicals (99% purity) is probably no more than a few hundred metric tons yearly, at prices of about 45 per kg in 1990. 

M. Mathlouthi and P. Reiser, eds.. Sucrose Properties and Applications, Chapman and Hall, New York, 1995 thorough coverage of properties of sucrose and its apphcations in food systems and chemical syntheses. 

Most current industrial vitamin C production is based on the efficient second synthesis developed by Reichstein and Grbssner in 1934 (15). Various attempts to develop a superior, more economical L-ascorbic acid process have been reported since 1934. These approaches, which have met with htde success, ate summarized in Crawford s comprehensive review (46). Currently, all chemical syntheses of vitamin C involve modifications of the Reichstein and Grbssner approach (Fig. 5). In the first step, D-glucose (4) is catalytically (Ni-catalyst) hydrogenated to D-sorbitol (20). Oxidation to L-sotbose (21) occurs microhiologicaRy with The isolated L-sotbose is reacted with acetone and sulfuric acid to yield 2,3 4,6 diacetone-L-sorbose,... 

The chemical syntheses of l,24(R),25-trihydroxy-vitamiQ [56142-94-0] and l,24(3),25-trihydroxy-vitamiQ D [56142-95-1] were reported (131,132) ki 1975. The chemical synthesis of 25,26-dihydroxy-vitamin [29261 -12-9] has also been described, and it has been determined that the biologically occurring epimer is 25(R),26-dihydroxy-vitamin (117,133—135). The 23,25-dihydroxy-24-oxo metabohte has been isolated (136) as well. 1 a-Hydroxycalcitroic acid (l-hydroxy-24-nor-9,10-secochola-5,7-10(19)-ttien-23-oic acid) [71204-89-2], 25-hydroxy-26,23-lactone vitamin [71203-34-6],... 

The discovery that vitamin D metaboUtes play a much larger biochemical role than just maintaining calcium homeostasis has stimulated a number of groups around the world to develop more economical chemical syntheses for the vitamin D metaboUtes and analogues, which might be useful ki studykig and treating D -related diseases and conditions. Many of these methods are reviewed ki References 139 and 140. 

Modification of the Proline Fragment. Besides the 4 -ethyl analogue of lincomycin, co-produced in fermentations of S. lincolnensis (48), other 4 -alkyl analogues were chemically synthesized. A peak of activity is reached with the trans-4 and hexyl analogues (11), the cis-epimers (12) possessing about one-half of the activity of the trans-. Equivalent activities are shown by A/-ethyl hncosarninides, but larger A/-alkyl substituents show decreased activity (86). 

Aristeromycin. Aristeromycin (36), the first carbocyhc analogue of adenosine, was isolated from the culture filtrates of S. citricolor as part of a search for inhibitors of bacterial leaf blight (1—4). A herbicidaHy active hypoxanthine analogue of (36), coaristeromycin, has also been isolated (108). Several chemical syntheses of (36) have appeared (1—4,109). It inhibits Aanthomonas OTjc e and Eyricularia bacterial leaf blight, blast disease of rice plants, and... 

I eplanocins. Neplanocins A—D and E (37—41) are carbocycHc nucleoside antibiotic products oi Ampullariella regularis (1,4) that are stmcturaHy related to (36) in that they contain either a cyclopentene or epoxy cyclopentane ring (121,122). The chemical syntheses of (37—41) and the 3-deazaneplanocins have been reported (123—126). Compound (37), which is converted to its 5 -triphosphate, has potent antitumor and antiviral activities (127—129). It strongly inhibits SAM in ceUs and vimses (128—131) and is converted to the 3 -keto derivative by A-adenosyUiomocysteine hydrolase (132,133). 

Chemically Synthesized Powders. Chemical synthesis provides a means of produciag powders for manufacturiag advanced ceramics. Disadvantages of chemically synthesized raw materials are expense and difficulties ia scale-up and availabihty. Additionally, ultrafine particle-size powders produced by chemical synthesis pose some unresolved processiag problems ia the areas of handling and mixing. 

Chemically synthesized materials also often undergo some form of beneficiation. Beneficiation processes for chemically synthesized ceramics are sometimes iacorporated ia the forming process such as ia aerosol decompositioa, where solveat evaporatioa and salt decomposition occur sequentially ia a single operatioa. 

Mono cylDiols. Enzymatic synthesis of chiral monoacyl diols can be carried out either by direct enzymatic acylation of prochiral diols or by hydrolysis of chemically synthesized dicarboxylates. 

This chapter lists some representative examples of biochemicals and their origins, a brief indication of key techniques used in their purification, and literature references where further details may be found. Simpler low molecular weight compounds, particularly those that may have been prepared by chemical syntheses, e.g. acetic acid, glycine, will be found in Chapter 4. Only a small number of enzymes and proteins are included because of space limitations. The purification of some of the ones that have been included has been described only briefly. The reader is referred to comprehensive texts such as the Methods Enzymol (Academic Press) series which currently runs to more than 344 volumes and The Enzymes (3rd Edn, Academic Press) which runs to 22 volumes for methods of preparation and purification of proteins and enzymes. Leading referenees on proteins will be found in Advances in Protein Chemistry (59 volumes. Academic Press) and on enzymes will be found in Advances in Enzymology (72 volumes, then became Advances in Enzymology and Related Area of Molecular Biology, J Wiley Sons). The Annual Review of Biochemistry (Annual Review Inc. Patio Alto California) also is an excellent source of key references to the up-to-date information on known and new natural compounds, from small molecules, e.g. enzyme cofactors to proteins and nucleic acids. 

Olefins are the basic building blocks for many chemical syntheses. These unsaturated materials enter into polymers, rubbers, and plastics, and react to form a wide variety of chemical compounds such as alcohols, amines, chlorides and oxides. 

Antibiotic A specific type of chemical substance that is administered to fight infections usually caused by bacteria, in humans or animals. Many antibiotics are produced by microorganisms some are chemically synthesized. 

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