Dimethylformamide hydrolysis

Hydrolysis of TEOS in various solvents is such that for a particular system increases directiy with the concentration of H" or H O" in acidic media and with the concentration of OH in basic media. The dominant factor in controlling the hydrolysis rate is pH (21). However, the nature of the acid plays an important role, so that a small addition of HCl induces a 1500-fold increase in whereas acetic acid has Httie effect. Hydrolysis is also temperature-dependent. The reaction rate increases 10-fold when the temperature is varied from 20 to 45°C. Nmr experiments show that varies in different solvents as foUows acetonitrile > methanol > dimethylformamide > dioxane > formamide, where the k in acetonitrile is about 20 times larger than the k in formamide. The nature of the alkoxy groups on the siHcon atom also influences the rate constant. The longer and the bulkier the alkoxide group, the lower the (3). 

Solubility. Poly(vinyl alcohol) is only soluble in highly polar solvents, such as water, dimethyl sulfoxide, acetamide, glycols, and dimethylformamide. The solubiUty in water is a function of degree of polymerization (DP) and hydrolysis (Fig. 4). Fully hydrolyzed poly(vinyl alcohol) is only completely soluble in hot to boiling water. However, once in solution, it remains soluble even at room temperature. Partially hydrolyzed grades are soluble at room temperature, although grades with a hydrolysis of 70—80% are only soluble at water temperatures of 10—40°C. Above 40°C, the solution first becomes cloudy (cloud point), followed by precipitation of poly(vinyl alcohol). 

Sometimes reduction of a ketone by NaBH4 is accompanied by hydrolysis of an ester elsewhere in the molecule. Norymberski found that a 20-keto-21-acetoxy compound with NaBH4 in methanol at 0° for 1 hour gives the 20/ ,21-diol. 50 % aqueous dimethylformamide has been used as the solvent in an attempt to prevent acetate hydrolysis, but sometimes under these conditions the 21-acetoxy group migrates to the 20-position. The rearrangement is favored by addition of the 20-acetate as seeds or by addition of... 

The interaction of (10) with vinylmagnesiiim chloride yields, after hydrolysis of the ketal group, 46% of the 3a-vinyl-l7-ketone (11b) and 7% of the 3j5-vinyl-17-ketone (12b). Ethynylation of (10) with potassium acetylide in dimethylformamide or with acetylene and potassium t-amyloxide in t-amyl alcohol-ether gives only the 3a-ethynyl derivative (11c) in 63% and 74% yields, respectively. ... 

Sodium nitrite in dimethylformamide acts as a nucleophile and reacts with perfluoropropene to generate a perfluoroalkyl nitrite anion The intermediate carbanion undergoes intramolecular nitrosation with loss of carbonyl difluoride to give tnfluoroacetic acid upon hydrolysis [5] (equation 6)... 

Alkaline hydrolysis in a solvent (dimethylformamide, dimethylsulphoxide or dimethyl-acetamide) containing sodium hydroxide has been investigated [164]- Fabric geometry [165] and the degree of heat setting of the polyester also influence the results. As the temperature of heat setting was increased, the accelerating effect of dodecylbenzyldimethylammonium chloride decreased [166]. Basic-dyeable polyester is particularly sensitive to alkaline hydrolysis [167]. In some cases, saponification has been used to produce special effects such as a leather-like finish [168]. 

The antibiotic 2-methylfervenulone (310) was synthesized most conveniently by treatment of 338 with dimethyiformamide-phosphorus oxychloride to afford 339, followed by acid hydrolysis to give fervenulone 340. Subsequent alkylation with methyl iodide in dimethylformamide gave 310 (78JOC469). Reaction of 339 with sodium benzyloxide gave the benzyloxy derivative 344, which on catalytic reduction with palladium-charcoal provided 340. 

Selective reaction at the ci.s-2,3-diol grouping of unprotected D-ribonucleosides has occasionally been observed. Treatment of D-ribonucleosides with tris(tetramethylammonium) trimetaphosphate in M sodium hydroxide for 4 days at room temperature led to a mixture of nucleoside 2 - and 3 -phosphates in yields of >70% no 5 -phosphate was detected.213 Reaction of ethyl (trichloromethyl)phos-phonate with nucleosides in N,N-dimethylformamide containing triethylamine, followed by basic hydrolysis of the reaction product, yielded 2 (3 )-phosphates in variable yields.214 The participation of the cis-diol grouping in the reaction was suggested by the failure of thymidine or 2, 3 -0-isopropylideneuridine to undergo reaction. 

Dimethylaminoethane-2-ol (20) is a compound that, by virtue of its nucleophilic center (Me2NH+C2H40), is employed to convert protected segments bound to supports as benzyl esters into acids by transesterification into dimethylaminoethyl esters [C(=0)0C2H4NMe2] that are hydrolyzable by a dimethylformamide-water (1 1) mixture. Compound 20 readily forms esters from acid chlorides. The hydrolysis and esterification are facilitated by anchimeric assistance by the adjacent nitrogen atom (see Section 2.10). The amino alcohol also reacts with dichloromethane. 

The synthesis of the basic skeleton of 1-benzylisoquinoline alkaloids has been reported by Uff et al. 15) starting from isoquinoline and benzyl chloride (Scheme 5). The preparation of Reissert compound iV-benzyl-l-cyano-l,2-di-hydroisoquinoline (4) was performed in a dichloromethane-water two-phase system with potassium cyanide and benzoyl chloride in about 64-69% yield. The deprotonation of 4 with sodium hydride in dimethylformamide solution, the subsequent alkylation with benzyl chloride, and the final alkaline hydrolysis could be performed as a one-pot reaction sequence to supply 1-benzylisoquinoline (25) in an overall yield of 75-84%. 

Solvent Effects. The conversion of dihydroanthracene could be increased by adding water to the pyridine solvent (Table III). An 86% conversion to anthraquinone was obtained when 95% aqueous pyridine was used as the solvent. Furthermore, methanol could be substituted for the water with equivalent results. Other solvents were tried in place of pyridine (Table IV). The data indicate that 95% aqueous pyridine gave the best yields, although aniline gave nearly similar results. When acetonitrile and dimethylformamide were used, the large amounts of unreacted starting material indicate that these solvents may have deactivated the base by undergoing a hydrolysis reaction. 

The reaction of 23 with 2, 5 -di-0-trityluridine was studied63 in N,N-dimethylformamide at 25°, and in hot benzene. In the former solvent, the major product was l-(3-deoxy-3-iodo-2,5-di-0-trityl-/3-D-xylofuranosyl)uracil in addition, there was some selective hydrolysis of the 5 -0-trityl substituent. In benzene,64 there was also an inversion... 

The reaction of halogenotriphenylphosphonium halides (triphenyl-phosphine dihalides) with alcohols is a useful method for the synthesis of alkyl halides (see Section II,2b p. 239). It has been found88 that (alkoxymethylene)dimethyliminium halides are formed in the reactions of these reagents with alcohols in N,N-dimethylformamide a possible mechanism is shown. Hydrolysis of the (alkoxymethylene)-dimethyliminium halide intermediate affords a formic ester, whereas... 

The structure of compounds 45, 47, and 49 was ascertained42 by methylation with methyl iodide in N.N-dimethylformamide in the presence of barium oxide.48 In each experiment, the corresponding l,l-bis(acetamido)-l-deoxy-octa-0-methylaldobiitol was obtained on acid hydrolysis, this afforded two methylated monosaccharides, whose structures confirmed the acyclic formulas proposed. 

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