Nicotinic acid production

Hepatic Nicotinic acid hepatotoxicity (including cholestatic jaundice) has occurred. Cases of severe hepatic toxicity, including fulminant hepatic necrosis, have occurred in patients who have substituted sustained-release nicotinic acid products for immediate-release nicotinic acid at equivalent doses. Monitor ALT prior to treatment, every 6 to 12 weeks during the first year, and periodically thereafter (approximately 6-month intervals). 

Population dynamics and stability analyses in the case of commensalism and other interactions are widespread in the literature (e.g., Lee et al., 1976 Miura et al., 1980). A modified approach to commensalistic modeling in the case of yeast growth and nicotinic acid production employed Monod-type functions for species 1 and 3 but the following equation for (Tseng and Phillips, 1981) ... 

The final library consisted of 1320 nicotinic acids of general structure 2 derived from, in part, 36 amines as nucleophiles (2 of which failed), 24 boronic acids, and 5 stannanes. Each MiniKan contained 80 mg of resin, which, with a measured loading of 1.36 mmol/g, was capable of yielding 0.1088 mmol of disubstituted nicotinic acid product. The final product acids were cleaved from the resin with trifluoroacetic acid and isolated as discrete sanq>les. Each sanq>le was analyzed by LCMS and the expected molecular ion was found in >80% of the sanples (92% when failed iiq)uts were eliminated). In selected instances, H NMR analyses were also used to ascertain the success of individual reactions. Members of a 25-membered rehearsal library were hilly characterized the yield and purity of each member of this library are shown in Table 1. 

Not many fine chemicals have a production value exceeding 10 million per year. Less than a do2en achieve production volumes above 10,000 metric tons per year and sales of > 100 million per year. Apart from the pharmaceutical and pesticide fine chemicals these comprise the amino acids (qv), L-lysine and n,T-methionine used as feed additives (see Feeds AND FEED ADDITIVES), and vitamins ascorbic acid and nicotinic acid. 

Pyridine carboxamide [98-92-0] (nicotinamide) (1) and 3-pyridine carboxylic acid [59-67-6] (nicotinic acid) (2) have a rich history and their early significance stems not from their importance as a vitamin but rather as products derived from the oxidation of nicotine. In 1867, Huber prepared nicotinic acid from the potassium dichromate oxidation of nicotine. Many years later, Engler prepared nicotinamide. Workers at the turn of the twentieth century isolated nicotinic acid from several natural sources. In 1894, Su2uki isolated nicotinic acid from rice bran, and in 1912 Funk isolated the same substance from yeast (1). 

Key intermediates in the industrial preparation of both nicotinamide and nicotinic acid are alkyl pyridines (Fig. 1). 2-Meth5l-5-ethylpyridine (6) is prepared in ahquid-phase process from acetaldehyde. Also, a synthesis starting from ethylene has been reported. Alternatively, 3-methylpyridine (7) can be used as starting material for the synthesis of nicotinamide and nicotinic acid and it is derived industrially from acetaldehyde, formaldehyde (qv), and ammonia. Pyridine is the principal product from this route and 3-methylpyridine is obtained as a by-product. Despite this and largely due to the large amount of pyridine produced by this technology, the majority of the 3-methylpyridine feedstock is prepared in this fashion. 

The result of this biosynthesis is that the product is nicotinic acid mononucleotide rather than free nicotinic acid. Ingested nicotinic acid is converted to nicotinic acid mononucleotide which, in turn, is converted to nicotinic acid adenine dinucleotide. Nicotinic acid adenine dinucleotide is then converted to nicotinamide adenine dinucleotide. If excess nicotinic acid is ingested, it is metabolized into a series of detoxification products (Fig. 4). Physiological metabohtes include /V-methylnicotinamide (19) and A/-methyl-6-pyridone-2-carboxamide (24) (1). 

Fig. 4. Detoxification products as the result of digestion of excess nicotinic acid.

Both nicotinic acid and nicotinamide have been used in the enrichment of bread, flour, and other grain-derived products. Animal feed is routinely supplemented with nicotinic acid and nicotinamide. Nicotinamide is also used in multivitamin preparations. Nicotinic acid is rarely used in this appHcation. The amide and carboxyHc acid have been used as a hrightener in electroplating baths and as stabili2er for pigmentation in cured meats. 

Tobacco and its alkaloids have long ceased to have any therapeutic importance, but their extensive use as insecticides and the demand for nicotine for the manufacture of nicotinic acid have stimulated interest in processes of extraction and methods of estimation. On the latter subject there is a voluminous literature, of which critical resumes have been published by various authors.Recent work on this subject has been specially concerned with (1) the development of miero- and semi-miero-methods suitable for estimating nieotine in tobacco smoke and the distribution of nieotine on sprayed garden produce, in treated soils and in tobaeeo leaves,(2) the study of conditions necessary to ensure satisfactory results in using particular processes, " and (3) methods of separation and estimation of nicotine, nomicotine and anabasine in mixtures of these bases. ) In the United States and in Russia considerable interest is being shown in the cultivation of types of tobacco rich in nicotine, in finding new industrial uses for tobacco and its alkaloids, and in possible by-products from tobacco plants such as citric and malic acids, i " Surveys of information on tobacco alkaloids have been published by Jackson, i Marion and Spath and Kuffner. ... 

The reaction products are 2,4-dimethyl-3-acetylpyridine (11) and ethyl ester of 2,4-dimethyl-3-nicotinic acid (12). 

Condensation of ethyl acetoacetate with phenyl hydrazine gives the pyrazolone, 58. Methylation by means of methyl iodide affords the prototype of this series, antipyrine (59). Reaction of that compound with nitrous acid gives the product of substitution at the only available position, the nitroso derivative (60) reduction affords another antiinflammatory agent, aminopyrine (61). Reductive alkylation of 61 with acetone in the presence of hydrogen and platinum gives isopyrine (62). Acylation of 61 with the acid chloride from nicotinic acid affords nifenazone (63). Acylation of 61 with 2-chloropropionyl chloride gives the amide, 64 displacement of the halogen with dimethylamine leads to aminopropylon (65). ... 

Aluminum nicotinate is prepared by dissolving nicotinic acid in hot water and adding a slurry of aluminum hydroxide to it. A slight excess of aluminum hydroxide is used in order that the final product would be free of nicotinic acid. The precipitate is collected on a filter and dried. The final product contains a mixture of aluminum nicotinate and a small but acceptable amount of aluminum hydroxide. 

To a solution of 93.8 g of the monoglycol ester in 500 ml of benzene, there are added 55 g of nicotinic acid chloride and 25 g of trimethylemine dissolved in 200 ml of benzene. The solution is stirred gently at a temperature of 60°C for two hours. After this time, the solution is cooled and washed successively with water, dilute hydrochloric acid, dilute ammonia and water until neutrality, it is dried over anhydrous sodium sulfate, and the sol vent Is evaporated under vacuum In this wey llOg of glycol 2-(p-chlorophenoxy)-2-methylpropionate nico-tlnate Is prepared, which represents a yield of 84%. The product is a sllghly yellow oil having a refraction index of no = 1.5422 and which is distilled with decomposition et 214°C at a pressure of 0.3 mm. 

Nicotinic acid supplied by Matheson, Coleman and Bell yielded a colorless anhydride tr.s.P. grade material gave a slightly buff-colored product. 

Neutron-to-proton ratio, 29-30 Newton, 457,635 Newton, Isaac, 136 Nickel hydroxide, 78 Nicotinic acid, 364-365 NIMBY syndrome, 526 Nitric acid acid rain and, 400 acid strength of, 567 commercial use, 76 copper penny dissolving in, 570 production, 570-571... 

Gauthier JJ, SC Rittenberg (1971) The metabolism of nicotinic acid II. 2,5-dihydroxypyridine oxidation, product formation, and oxygen 18 incorporation. J Biol Chem 246 3743-3748. 

Another example of a biocatalytic transformation ousting a chemical one, in a rather simple reaction, is provided by the Lonza nitotinamide process (Fig. 2.34) (Heveling, 1996). In the final step a nitrile hydratase, produced by whole cells of Rh. rhodoccrous, catalyses the hydrolysis of 3-cyano-pyridine to give nitotinamide in very high purity. In contrast, the conventional chemical hydrolysis afforded a product contaminated with nicotinic acid. 

Chapter 10 is devoted to the preparation and purification of hydrophilic vitamins (C, Bj, Bj, Bg, B[2, nicotinic acid and nicotinamide, pantothenic acid, biotin, and folic acid) in pharmaceutical preparations, food products, and biological samples. 

Niacin should be instituted at the lowest dose and gradually titrated to a maximum dose of 2 grams daily for ER and SR products and no more than 5 grams daily for IR products. FDA-approved niacin products are preferred because of product consistency. Moreover, niacin products labeled as no flush don t contain nicotinic acid and therefore have no therapeutic role in the treatment of lipid disorders.28 The time until maximum effect on lipids for niacins is generally 3 to 5 weeks. 

The group C counterirritants methyl nicotinate and histamine dihydrochloride produce vasodilation.24 Methyl nicotinate is a nicotinic acid derivative that produces prostaglandin-mediated vasodilation.46 NSAIDs and aspirin block the production of prostaglandins and decrease methyl nicotinate-induced vasodilation. Application over a large area has been reported to cause systemic symptoms and syncope, possibly due to vasodilation and a decrease in blood pressure.47 Patients should be educated to apply only scant amounts to the affected area to avoid this effect. 

Trigonelline is present in green coffee (1 %),15 but it is rapidly decomposed on roasting so that only about 0.1% trigonelline is present in a deeply roasted coffee.161 The products of trigonelline breakdown are evident in roasted coffee and include nicotinic acid and its methylester, pyridine, and p-picoline (Figure 17).3... 

The water-soluble vitamins generally function as cofactors for metabolism enzymes such as those involved in the production of energy from carbohydrates and fats. Their members consist of vitamin C and vitamin B complex which include thiamine, riboflavin (vitamin B2), nicotinic acid, pyridoxine, pantothenic acid, folic acid, cobalamin (vitamin B12), inositol, and biotin. A number of recent publications have demonstrated that vitamin carriers can transport various types of water-soluble vitamins, but the carrier-mediated systems seem negligible for the membrane transport of fat-soluble vitamins such as vitamin A, D, E, and K. 

The answer is b. (Hardman, pp 890-891.) Nicotinic acid in large doses stimulates the production of prostaglandins as shown by an increase in blood level. The flush may be prevented by the prior administration of aspirin, which is known to block synthesis of prostaglandins... 

Benzoylpyridine can be obtained by this procedure from iso-nicotinic acid in yields of 87-90%. This product is recrystallized from hexane, m.p. 72-73°. 

The biosynthesis and metabolism of nicotinic acid in disease has received little attention metabolic studies deal mainly with normal animals and man (01, R5). After a tryptophan load dose, the main catabolites in the urine are nicotinuric acid, N1-methylnicotinamide, nicotinamide, quinolinic acid, kynurenine, 6-pyridone, anthranilic acid, and 3-hydroxyanthranilic acid. These excretory products were estimated... 

---