Orthoester

Alkyl halides and sulfonates are the most frequently used alkylating acceptor synthons. The carbonyl group is used as the classical a -synthon. O-Silylated hemithioacetals (T.H. Chan, 1976) and fomic acid orthoesters are examples for less common a -synthons. In most synthetic reactions carbon atoms with a partial positive charge (= positively polarized carbon) are involved. More reactive, "free carbocations as occurring in Friedel-Crafts type alkylations and acylations are of comparably limited synthetic value, because they tend to react non-selectively. 

The most commonly used protected derivatives of aldehydes and ketones are 1,3-dioxolanes and 1,3-oxathiolanes. They are obtained from the carbonyl compounds and 1,2-ethanediol or 2-mercaptoethanol, respectively, in aprotic solvents and in the presence of catalysts, e.g. BF, (L.F. Fieser, 1954 G.E. Wilson, Jr., 1968), and water scavengers, e.g. orthoesters (P. Doyle. 1965). Acid-catalyzed exchange dioxolanation with dioxolanes of low boiling ketones, e.g. acetone, which are distilled during the reaction, can also be applied (H. J. Dauben, Jr., 1954). Selective monoketalization of diketones is often used with good success (C. Mercier, 1973). Even from diketones with two keto groups of very similar reactivity monoketals may be obtained by repeated acid-catalyzed equilibration (W.S. Johnson, 1962 A.G. Hortmann, 1969). Most aldehydes are easily converted into acetals. The ketalization of ketones is more difficult for sterical reasons and often requires long reaction times at elevated temperatures. a, -Unsaturated ketones react more slowly than saturated ketones. 2-Mercaptoethanol is more reactive than 1,2-ethanediol (J. Romo, 1951 C. Djerassi, 1952 G.E. Wilson, Jr., 1968). 

As a class of compounds, nitriles have broad commercial utility that includes their use as solvents, feedstocks, pharmaceuticals, catalysts, and pesticides. The versatile reactivity of organonitnles arises both from the reactivity of the C=N bond, and from the abiHty of the cyano substituent to activate adjacent bonds, especially C—H bonds. Nitriles can be used to prepare amines, amides, amidines, carboxyHc acids and esters, aldehydes, ketones, large-ring cycHc ketones, imines, heterocycles, orthoesters, and other compounds. Some of the more common transformations involve hydrolysis or alcoholysis to produce amides, acids and esters, and hydrogenation to produce amines, which are intermediates for the production of polyurethanes and polyamides. An extensive review on hydrogenation of nitriles has been recendy pubHshed (10). 

Poly(orthoesters) represent the first class of bioerodible polymers designed specifically for dmg deUvery appHcations (52). In vivo degradation of the polyorthoester shown, known as the Al amer degradation, yields 1,4-cydohexanedimethanol and 4-hydroxybutyric acid as hydrolysis products (53). 

Orthoesters. The value of cycHc orthoesters as intermediates for selective acylation of carbohydrates has been demonstrated (73). Treatment of sucrose with trimethylorthoacetate and DMF in the presence of toluene-/)-sulfonic acid followed by acid hydrolysis gave the 6-0-acetylsucrose as the major and the 4-0-acetylsucrose [63648-80-6] as the minor component. The latter compound underwent acetyl migration from C-4 to C-6 when treated with an organic base, such as / fZ-butylamine, in DMF to give sucrose 6-acetate in >90% yield (74). When the kinetic reagent 2,2-dimethoxyethene was used,... 

In order to become useful dmg delivery devices, biodegradable polymers must be formable into desired shapes of appropriate size, have adequate dimensional stability and appropriate strength-loss characteristics, be completely biodegradable, and be sterilizahle (70). The polymers most often studied for biodegradable dmg delivery applications are carboxylic acid derivatives such as polyamides poly(a-hydroxy acids) such as poly(lactic acid) [26100-51-6] and poly(glycolic acid) [26124-68-5], cross-linked polyesters poly(orthoesters) poly anhydrides and poly(alkyl 2-cyanoacrylates). The relative stabiUty of hydrolytically labile linkages ia these polymers (70) is as follows ... 

Orthoesters, RC(OR )2 (1), thioesters, RCSOR ( A) Sulfur compounds Thiols), and carbamates, H2NCOOR, are not covered in this review. 

Orthoesters are trivially named as derivatives of ortho acids such as triethyl orthoformate [122-51 -0] HC(OC2H )2, or named systematically as ethers, 1,1,1-triethoxymethane. 

Acid moieties include formic acid itself, formates and orthoesters, formamide, DMF dimethyl acetal and ethyl diethoxyacetate, acids, acid chlorides and anhydrides, the last including a rare [3,4-oxalate esters, 2-acyl or 2-ethoxycar-bonyl derivatives e.g. 180) are formed. 

With l,3-dimethyl-2,l-benzisoxazolium salts, however, considerable reactivity has been reported. Condensation occurs readily with aldehydes, ketones, orthoesters and diazonium salts to yield styryl, cyanine and azo compounds, respectively (78JOC1233). In the presence of triethylamine, dimerization was observed, and the reactions of the cation were considered to involve the intermediacy of the anhydro base (77JOC3929). 

Selective protection of 1,2- and m-l,3-diols can be achieved by formation of acetonides, acetals or orthoesters. Further selectivity is possible in special cases (e.g., acetonide formation). With 17a,20,21-triols, the 20,21-acetonide is obtained exclusively. 16a,17a,21-Trihydroxy-20-lcetopregnanes (20) react selectively with acetone to give 16,17-acetonides (21). 

Selective removal of the hydroxyl protecting groups included in this review is generally difficult to achieve and of little practical importance. Selective hydrolysis of cyclic orthoesters to give monoesters merits attention for its practical interest. 

Orthoesters are stable to base, although nucleophilic attack may occur under drastic conditions. Orthoformates are split by acids to free diols, whereas controlled acid hydrolysis leads to monoformates. " Higher orthoesters are usually split by mineral or organic acids to give monoesters. 

Orthoesters (e.g., methyl orthoacetate) have also been prepared by acid-catalyzed exchange with trimethyl orthoesters, from 16a,17a-dihydroxy-pregnanes with or without a 21-hydroxyl substituent. 

Three possible mechanisms for the Serini reaction were originally suggested. These proceed via (a) a A -enol acetate, (b) a A -epoxide, or (c) a cyclic orthoester ... 

While these results support the ionic orthoester mechanism, it was originally suggested that an oxygen radical may participate since it was claimed that the reaction proceeds in the presence of dibenzoyl peroxide instead of zinc, and that the presence of hydroquinone or exclusion of oxygen completely inhibits the reaction. Later work, however, could not confirm the previously observed influence of hydroquinone or oxygen. 

Deep fluorinalion of alkanes, ethers, acid fmlides, esters, alkyl chlorides, most ketones, ketals, orthoesters, and combinations of these functional groups produces principally the perfluonnated analogues (Table 2) Chlorine substituents (or chloro groups) usually survive fluorination... 

Aromatic thio orthoesters are successfully converted into trifluoromethyl arenes by treatment with a pyridinium polyhydrogen fluoride-A -halo imide reagent. The reactions are conducted at -30 to -20 °C, and the nature of A-halo imide is critical both 1,3-dibromo-5,5-dimethylhydantoin and A-bromosuccin-imide give similar yields of trifluoromethyl compounds [5] (equation 7)... 

Another approach to the l-oxo-l,2-dihydro-j8-carboline system is that due to King and Stiller. When 2-ethoxy carbonyl-3-formyl-indole is condensed with hippuric acid the azlactone 162 is formed, which, with 10% methanolic potassium hydroxide, gives a mixture of the orthoester 163 and the potassium salt 164. 

Ketene di(2-melhoxyethyl) acetal has been obtained by the present method with the use of diethylene glycol dimethyl ether as solvent.3 Other methods for the preparation of ketene acetals include the dehydrohalogenation of a halo acetal with potassium t-butoxide 4 and the reaction of an a-bromo orthoester with metallic sodium.5... 

Imidazo[l,2-c/][l,2,4]triazines 488 were prepared (78USP4096257) from the reaction of 2-imidazocarboxylic acid hydrazide 487 with orthoesters. They inhibited cyclic-AMP phosphodiesterase in the mouse skin phosphodiesterase test and had antiasthina. 

Imidazo[l,5-t/)[l, 2,4]triazin-l(2//)-ones 504 were prepared (78-USP4115572 79JHC277 88USP4743586) by the cyclization of hydrazide 503 with triethyl orthoesters. l,2,3,4-Tetrahydro-2,4,4-trimethyl-8-nitroimidazo[ 1,5-t/J[ 1,2,4]triazin-1 -one 506 was isolated as a byproduct during the course of purification of hydrazide 505, whose structure was determined (91MI4) by crystal structure analysis. They had antiasthmatic... 

Cyclization of the hydrazone derivatives of 4-benzoyl[ 1,2,3]triazole 695 by reaction with one carbon inserting agent such as an orthoester, an aldehyde, a ketone, or a phosgene afforded triazolotriazine 696 or 697 (88JHC743). The newly created C—N bond displays particular sensitivity due to the electron-attracting effect of the triazole ring (Scheme 147). 

---