Dehydrated pyridine

Procedure Weigh accurately about 0.3 g and dissolve in 50 ml of dehydrated pyridine. Titrate with 0.1N tetrabutylammonium hydroxide, determining the end point potentiometrically and protecting the solution and titrant from atmospheric carbon dioxide throughout the determination. Perform a blank determination and make any necessary correction. Each ml of 0.1N tetrabutylammonium hydroxide is equivalent to 0.03388 g of q4HuCIN204S. 

Karl Fischer reagent. Dissolve 63 g of analytical-reagent grade iodine in 110 ml of dehydrated pyridine in a dry gas wash-bottle (of which the delivery tube is fitted with a screw-clip and the exit tube connected to an efficient drying tube) and weigh the bottle and its contents. Cool in ice-water and pass dry sulphur dioxide into the cold solution, stirring continuously, until the increase in weight is 32 g. Allow the mixture to stand for about thirty minutes and then dilute to 500 ml with dry methanol. When freshly prepared the solution will have a water equivalent of about 5 mg per ml but slowly decomposes. It should be allowed to stand for tw enty-four hours before standardisation. 

Perchloric acid Acetic acid, acetic anhydride, alcohols, antimony compounds, azo pigments, bismuth and its alloys, methanol, carbonaceous materials, carbon tetrachloride, cellulose, dehydrating agents, diethyl ether, glycols and glycolethers, HCl, HI, hypophosphites, ketones, nitric acid, pyridine, steel, sulfoxides, sulfuric acid... 

I60C-Hydroxy Derivatives of Gorticoids and their Acetonides. The preparation of 16a-hydroxy-9a-fluoroprednisolone (48) from the 3,20-bisethylene ketal of hydrocortisone acetate (49) has been reported (73). The latter was dehydrated with thionyl chloride in pyridine to yield the 4,9(11),16-triene (50). The 16,17-unsaturated linkage was selectively hydroxylated with OsO /pyridine to yield the 16a,17a-diol (51), which was converted... 

Reaction with Ammonia. Although the Hquid-phase reaction of acrolein with ammonia produces polymers of Htde interest, the vapor-phase reaction, in the presence of a dehydration catalyst, produces high yields of [ -picoline [108-99-6] and pyridine [110-86-4] n.2L mXio of approximately 2/1. 

Bisa.codyl, 4,4 -(2-PyridyLmethylene)bisphenol diacetate [603-50-9] (Dulcolax) (9) is a white to off-white crystalline powder ia which particles of 50 p.m dia predominate. It is very soluble ia water, freely soluble ia chloroform and alcohol, soluble ia methanol and ben2ene, and slightly soluble ia diethyl ether. Bisacodyl may be prepared from 2-pyridine-carboxaldehyde by condensation with phenol and the aid of a dehydrant such as sulfuric acid. The resulting 4,4 -(pyridyLmethylene)diphenol is esterified by treatment with acetic anhydride and anhydrous sodium acetate. Crystallisation is from ethanol. 

Medroxyprogesterone acetate (74) is stmcturaHy related to and has been prepared from hydroxyprogesterone (39) (Fig. 10). Formation of the bis-ketal accomplishes the protection of the ketones and the required migration of the double bond. Epoxidation with peracetic acid produces a mixture of epoxides (75), with a predominating. Treatment of the a-epoxide with methyl magnesium bromide results in diaxial opening of the epoxide. Deprotection of the ketones provides (76), which is dehydrated to (77) by treatment with dilute sodium hydroxide in pyridine. Upon treatment with gaseous hydrochloric... 

The reactions of primary amines and maleic anhydride yield amic acids that can be dehydrated to imides, polyimides (qv), or isoimides depending on the reaction conditions (35—37). However, these products require multistep processes. Pathways with favorable economics are difficult to achieve. Amines and pyridines decompose maleic anhydride, often ia a violent reaction. Carbon dioxide [124-38-9] is a typical end product for this exothermic reaction (38). 

Oxa2oles react with dienophiles to give pyridines after dehydration or other aromatization reactions (69,70). A commercially important example is the reaction of a 5-aLkoxy-4-methyloxa2ole with 1,4-butenediol to yield pyridoxine (55), which is vitamin... 

These reactions can be cataly2ed by bases, eg, pyridine, or by Lewis acids, eg, 2inc chloride. In the case of asymmetric alcohols, steric control, ie, inversion, racemi2ation, or retention of configuration at the reaction site, can be achieved by the choice of reaction conditions (173,174). Some alcohols dehydrate to olefins when treated with thionyl chloride and pyridine. 

Thus, Mathis et al. [1, 2] investigated oxidation reactions with 4-nitroperbenzoic acid, sodium hypobromite, osmium tetroxide and ruthenium tetroxide. Hamann et al. [3] employed phosphorus oxychloride in pyridine for dehydration. However, this method is accompanied by the disadvantages that the volume applied is increased because reagent has been added and that water is sometimes produced in the reaction and has to be removed before the chromatographic separation. 

If homolytic reaction conditions (heat and nonpolar solvents) can be avoided and if the reaction is conducted in the presence of a weak base, lead tetraacetate is an efficient oxidant for the conversion of primary and secondary alcohols to aldehydes and ketones. The yield of product is in many cases better than that obtained by oxidation with chromium trioxide. The reaction in pyridine is moderately slow the intial red pyridine complex turns to a yellow solution as the reaction progresses, the color change thus serving as an indicator. The method is surprisingly mild and free of side reactions. Thus 17a-ethinyl-17jS-hydroxy steroids are not attacked and 5a-hydroxy-3-ket-ones are not dehydrated. 

One of the most widely used systems for dehydration is the combination of phosphorous oxychloride and pyridine. This reagent is apparently incompatible with the A" -3-keto system/ probably due to formation of a phosphorylated enol. It is, however, more selective than thionyl chloride-pyridine since 17a-alcohols are not dehydrated ... 

A iD-Corticoids have been important intermediates since it was shown ° that substitution at C-9 enhances anti-inflammatory activity. These olefins are usually obtained from 11a- or 11)5-alcohols, and consequently several refined methods have been devised for effecting this dehydration. It is desirable that such methods be compatible with the presence of A" -3-ketone and 17-hydroxy functions. The first direct procedure for which high yields were claimed was described in a patent issued to Upjohn. According to this method, the alcohol (11a or )5) is treated first with A-bromoacetamide in pyridine, then with sulfur dioxide. Recently it has been claimed " that the A-haloamide/sulfur dioxide method gives results superior to other methods, although the methanesulfonyl chloride/sulfur dioxide procedure (see below) apparently was not compared (see also ref. 94). 

Methylchlorosulfite has been used to dehydrate lljS-alcohols ° the best conditions use THF-pyridine at low temperatures. By-products include 11 )5-methylsulfite and A -olefin. ° ... 

It has generally been assumed that phosphorous oxychloride-pyridine dehydrations, the elimination of sulfonates, and other base catalyzed eliminations (see below) proceed by an E2 mechanism (see e.g. ref. 214, 215, 216). Concerted base catalyzed eliminations in acyclic systems follow the Saytzelf orientation rule i.e., proceed toward the most substituted carbon), as do eliminations (see ref 214). However, the best geometrical arrangement of the four centers involved in 2 eliminations is anti-coplanar and in the cyclohexane system only the tran -diaxial situation provides this. 

When, in the phosphorous oxychloride-pyridine dehydration of an alcohol these rules conflict, the stereoelectronic factor determines the direction of elimination ... 

Thionyl chloride behaves in some circumstances as though it dehydrates by tran -diaxial elimination, as described for phosphorous oxychloride. For example, the 5a-alcohol (102) undergoes anti-Saytzelf elimination to give the A" -olefin. In this particular example, phosphorous oxychloride-pyridine does not work, and acetic anhydride-sulfuric acid gives the A -isomer (ref. 185, p. 199). 

Acetonides are quite stable to base, and to oxidation, dehydration and acylation reactions carried out in pyridine. They are cleaved by acid hydrolysis. The 17,21-acetonides of 17a,21-dihydroxy-20-keto steroids and related acetals are split by very mild acid conditions. ... 

The reaction can be carried out in any inert solvent, but using a base such as pyridine has an additional advantage in the subsequent dehydration step... 

Dehydration of 17a-hydroxy-20-ketopregnanes can be accomplished by phosphorus oxychloride/pyridine treatment at room temperature for 4 or more days ... 

Sorm" " found that when cholesterol acetate (67) is oxidized by chromic acid in acetic acid-water at 55°, crystalline keto seco-acid (69) is obtained in 25-30 % yield from the mother liquors after removal of successive crops of 7-ketocholesterol acetate (68). Reaction of keto acid (69) with benzoyl chloride in pyridine gives a dehydration product, shown" to be the )5-lactone... 

Tnfluoromethyl homoallyl alcohols also dehydrate easily with phosphorus oxychloride-pyridine complex, but it is very difficult to remove water from their saturated analogues by the same method [82] (equation 52)... 

The reaction of diketosulfides with 1,2-dicarbonyl compounds other than glyoxal is often not efficient for the direct preparation of thiophenes. For example, the reaction of diketothiophene 24 and benzil or biacetyl reportedly gave only glycols as products. The elimination of water from the P-hydroxy ketones was not as efficient as in the case of the glyoxal series. Fortunately, the mixture of diastereomers of compounds 25 and 26 could be converted to their corresponding thiophenes by an additional dehydration step with thionyl chloride and pyridine. 

A thioamide of isonicotinic acid has also shown tuberculostatic activity in the clinic. The additional substitution on the pyridine ring precludes its preparation from simple starting materials. Reaction of ethyl methyl ketone with ethyl oxalate leads to the ester-diketone, 12 (shown as its enol). Condensation of this with cyanoacetamide gives the substituted pyridone, 13, which contains both the ethyl and carboxyl groups in the desired position. The nitrile group is then excised by means of decarboxylative hydrolysis. Treatment of the pyridone (14) with phosphorus oxychloride converts that compound (after exposure to ethanol to take the acid chloride to the ester) to the chloro-pyridine, 15. The halogen is then removed by catalytic reduction (16). The ester at the 4 position is converted to the desired functionality by successive conversion to the amide (17), dehydration to the nitrile (18), and finally addition of hydrogen sulfide. There is thus obtained ethionamide (19)... 

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