Isopropenyl acetate reaction with acetals

Isopropenyl acetate [108-22-5] which forms upon reaction of acetone [67-64-1] with anhydride, rearranges to acetylacetone [123-54-6] in the presence of BF3 (19) ... 

With aldehydes, primary alcohols readily form acetals, RCH(OR )2. Acetone also forms acetals (often called ketals), (CH2)2C(OR)2, in an exothermic reaction, but the equiUbrium concentration is small at ambient temperature. However, the methyl acetal of acetone, 2,2-dimethoxypropane [77-76-9] was once made commercially by reaction with methanol at low temperature for use as a gasoline additive (5). Isopropenyl methyl ether [116-11-OJ, useful as a hydroxyl blocking agent in urethane and epoxy polymer chemistry (6), is obtained in good yield by thermal pyrolysis of 2,2-dimethoxypropane. With other primary, secondary, and tertiary alcohols, the equiUbrium is progressively less favorable to the formation of ketals, in that order. However, acetals of acetone with other primary and secondary alcohols, and of other ketones, can be made from 2,2-dimethoxypropane by transacetalation procedures (7,8). Because they hydroly2e extensively, ketals of primary and especially secondary alcohols are effective water scavengers. 

Ketones with labile hydrogen atoms undergo enol acetylation on reaction with ketene. Strong acid catalysis is required. If acetone is used, isoptopenyl acetate [108-22-5] (10) is formed (82—85). Isopropenyl acetate is the starting material for the production of 2,4-pentanedione (acetylacetone) [123-54-6] (11). 

A -Dien-3-ol esters e.g., acetates) have greater utility as reaction intermediates than as protecting groups. They are prepared from A" -3-ketones by reaction with the acetic anhydride"" or by exchange with isopropenyl acetate. 

Enol esterification with acetyl chloride-acetic anhydride gives the A -trien-3-acetate, but reaction with isopropenyl acetate or with hot acetic anhydride-pyridine gives A " -trien-3-acetates. " Since A"" -3-ketones react with Girard reagents, these linear dienones can be separated from A ""-3-ketones. ... 

Unsubstituted 20-ketones readily form enol acetates. Reaction with isopropenyl acetate yields the kinetic A -isomer (86, R = CH3CO) which is equilibrated to the A -enol acetate (85, R = CH3CO) on exposure to acetic anhydride-/7-toluenesulfonic acid. Treatment of the 20-ketone according to the latter conditions gives the A -enol acetate directly. 

A -20-Dien-20-ol acetates are prepared by acid-catalyzed reaction with isopropenyl acetate.A -20-Semicarbazones can be prepared in the usual manner. ... 

The dimethyl acetal (94) is readily prepared from the 22-aldehyde (93) by direct reaction with methanol in the presence of hydrogen chloride. Ena-mines (95) are formed without a catalyst even with the poorly reactive piperidine and morpholine.Enol acetates (96) are prepared by refluxing with acetic anhydride-sodium acetate or by exchange with isopropenyl acetate in pyridine.Reaction with acetic anhydride catalyzed by boron trifluoride-etherate or perchloric acid gives the aldehyde diacetate. 

A series of benzimidazole and benzimidazolone derivatives from the Janssen laboratories has provided an unusually large number of biologically active compounds, particularly in the area of the central nervous system. Reaction of imidazolone itself with isopropenyl acetate leads to the singly protected imidazolone derivative 51. Alkylation of this with 3-chloro-l-bromopropane affords the functionalized derivative Use of this... 

Cyclic 1,3-diacetoxy-l,3-dienes can be generated in situ from cyclic 1,3-diketones under the influence of isopropenyl acetate. The dienes then undergo Diels-Alder reactions with maleic anhydride giving as products 1-acetoxybicycloalkane dicarboxylic anhydride derivatives (10). The procedure is also successful with cyclic 1,2- and 1,4-diketones as well as cyclic a,j3-unsaturated ketones. The products, after hydrolysis to... 

The reaction of 20 g (0.177 mole) of 1,3-cyclohexanedione (Chapter 5, Section II) with 21.8 g (0.22 mole) of maleic anhydride and 0.1 g of/j-toluenesulfonic acid in 150 ml of isopropenyl acetate is conducted as described above to give about 70% of the recrystallized product, mp 156-159°. 

With a less reactive olefin such as isopropenyl acetate, diazoketone 86 gives only a low yield of cyclopropane 90 a-acyl enol ether 92, resulting from an intramolecular rearrangement of the ketocarbenoid, becomes the favored reaction product. If 91... 

Saunders et al. reported the DKR system for secondary alcohols using Cp lr complexes bearing a NHC ligand as racemization catalysts [47]. As shown in Scheme 5.15, the reaction of racemic 1-phenylethanol with isopropenyl acetate in the presence of catalyst 22 (0.1mol% Ir) and Novozyme 435 at 70 °C for 8h gave... 

In conjunction with the establishment of the cyanohydrin DCL, the DCR process was subsequently addressed. Thus, selected lipases and a suitable acyl donor [isopropenyl acetate (34)] were applied to the system (Scheme 6.7). This selective enzymatic resolution of the DCL provided cyanoacetate product (35) as the major product at the reaction conditions used, thus demonstrating the efficiency of the concept. 

N-Acetvlneuraminic Acid Aldolase. A new procedure has also been developed for the synthesis of 9-0-acetyl-N-acetylneuraminic acid using the aldolase catalyzed reaction methodology. This compound is an unusual sialic acid found in a number of tumor cells and influenza virus C glycoproteins (4 ). The aldol acceptor, 6-0-acetyl-D-mannosamine was prepared in 70% isolated yield from isopropenyl acetate and N-acetyl-D-mannosamine catalyzed by protease N from Bacillus subtilis (from Amano). The 6-0-acetyl hexose was previously prepared by a complicated chemical procedure (42.) The target molecule was obtained in 90% yield via the condensation of the 6-0-acetyl sugar and pyruvate catalyzed by NANA aldolase (Figure 6). With similar procedures applied to KDO, 2-deoxy-NANA and 2-deoxy-2-fluoro-NANA were prepared from NANA. 

DKR of secondary alcohol is achieved by coupling enzyme-catalyzed resolution with metal-catalyzed racemization. For efficient DKR, these catalyhc reactions must be compatible with each other. In the case of DKR of secondary alcohol with the lipase-ruthenium combinahon, the use of a proper acyl donor (required for enzymatic reaction) is parhcularly crucial because metal catalyst can react with the acyl donor or its deacylated form. Popular vinyl acetate is incompatible with all the ruthenium complexes, while isopropenyl acetate can be used with most monomeric ruthenium complexes. p-Chlorophenyl acetate (PCPA) is the best acyl donor for use with dimeric ruthenium complex 1. On the other hand, reaction temperature is another crucial factor. Many enzymes lose their activities at elevated temperatures. Thus, the racemizahon catalyst should show good catalytic efficiency at room temperature to be combined with these enzymes. One representative example is subtilisin. This enzyme rapidly loses catalytic activities at elevated temperatures and gradually even at ambient temperature. It therefore is compatible with the racemization catalysts 6-9, showing good activities at ambient temperature. In case the racemization catalyst requires an elevated temperature, CALB is the best counterpart. 

We synthesized 8 by the one-step reaction of [Ph4(Tl -C4CO)]Ru(CO)3 with benzyl chloride. In contrast to previous alcohol racemization catalysts, 8 was stable in the air during racemization [30]. The racemization was performed even under 1 atm of molecular oxygen. Thus, alcohol DKR was for the first time possible with 8 in the air at room temperature (R)-l-phenylethyl acetate (99% yield, greater than 99%e.e.) was obtained from 1-phenylethanol by using 4mol% of 8, CALB and isopropenyl acetate in the presence of potassium phosphate (Scheme 1.22). This catalyst system was effective for both benzylic and aliphatic alcohols. The synthetic method for 8 was applied to the preparation of a polymer-bound derivative (9). Hydroxymethyl polystyrene was reacted with 4-(chloromethyl)benzoyl chloride to... 

Many such activated acyl derivatives have been developed, and the field has been reviewed [7-9]. The most commonly used irreversible acyl donors are various types of vinyl esters. During the acylation of the enzyme, vinyl alcohols are liberated, which rapidly tautomerize to non-nucleophilic carbonyl compounds (Scheme 4.5). The acyl-enzyme then reacts with the racemic nucleophile (e.g., an alcohol or amine). Many vinyl esters and isopropenyl acetate are commercially available, and others can be made from vinyl and isopropenyl acetate by Lewis acid- or palladium-catalyzed reactions with acids [10-12] or from transition metal-catalyzed additions to acetylenes [13-15]. If ethoxyacetylene is used in such reactions, R1 in the resulting acyl donor will be OEt (Scheme 4.5), and hence the end product from the acyl donor leaving group will be the innocuous ethyl acetate [16]. Other frequently used acylation agents that act as more or less irreversible acyl donors are the easily prepared 2,2,2-trifluoro- and 2,2,2-trichloro-ethyl esters [17-23]. Less frequently used are oxime esters and cyanomethyl ester [7]. S-ethyl thioesters such as the thiooctanoate has also been used, and here the ethanethiol formed is allowed to evaporate to displace the equilibrium [24, 25]. Some anhydrides can also serve as irreversible acyl donors. 

Treatment of 3-pentanone with isopropenyl acetate is reported to give 3-acetoxy-2-pentene. The product isolated from the reaction has the 11 NMR spectrum shown in Figure 11.28. 

Hydroxyhexanal undergoes a Claisen reaction with isopropenyl acetate in the presence of iV-chlorosuccinimide and tin(ll) chloride as catalyst to afford 2-acetonyloxepane. In the case of 6-hydroxy-2-pentylhexanal, 2-acetonyl-3-pentyloxepane is obtained with 95% diastereoselectivity (Equation 30) <1994CC1123>. 

In order to reduce the time needed to perform a complete kinetic resolution Lindner et al53 reported the use of the allylic alcohol 30 in enantiomerically enriched form rather than a racemic mixture in kinetic resolution. Thus, the kinetic resolution of 30 was performed starting from the enantiomerically enriched alcohol (R) or (S)-30 (45%) ee obtained by the ruthenium-catalyzed asymmetric reduction of 32 with the aim to reach 100 % ee in a consecutive approach. Several lipases were screened in resolving the enantiomerically enriched 30 either in the enantioselective transesterification of (<5)-30 (45% ee) using isopropenyl acetate as an acyl donor in toluene in non-aqueous medium or in the enantioselective hydrolysis of the corresponding acetate (R)-31, (45% ee) using a phosphate buffer (pH = 6) in aqueous medium. An E value of 300 was observed and the reaction was terminated after 3 h yielding (<5)-30 > 99% ee and the ester (R)-31 was recovered with 86% ee determined by capillary GC after 50 % conversion. 

To the solution of 5.35 g (28 mmol) [3-(lH-benzimidazol-2-yl)propyl]methylamine in 12.5 mL toluene was added by syringe 12.5 mL (11.42 g, 114 mmol) isopropenyl acetate. The reaction mixture was heated to reflux temperature, and stirred at that temperature for 1.75 hours, with reaction completion monitored by thin-layer chromatography (silica gel, eluting with 70% ethyl acetate/30% methanol). The product, N-[3-(lH-benzimidazol-2-yl)propyl]-N-methylacetamide, was obtained in quantitative yield. 

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