Hydrolysis substituent effect

Hydrolysis reactions involving tetrahedral intermediates are subject to steric and electronic effects. Electron-withdrawing substituents faciUtate, but electron-donating and bulky substituents retard basic hydrolysis. Steric effects in acid-cataly2ed hydrolysis are similar to those in base-cataly2ed hydrolysis, but electronic effects are much less important in acid-cataly2ed reactions. Higher temperatures also accelerate the reaction. 

This would disperse the positive charge over several atoms and diminish the sensitivity of the reaction to substituent effects. The p values that are observed are consistent with this interpretation. Whereas p is —3.25 for acetal hydrolysis, it is only —1.9 for hemiacetal hydrolysis. ... 

As in the case of hydrolysis, there has been a good deal of study of substituent effects. 

A comparison of the kinetics of hydrolysis and isotopic exchange of amides A and B was carried out. Some of the data are given below. An interesting observation is that there is more C=0 exchange for A than for B. From this observation, and other data given, develop a stepwise mechanism for the hydrolysis of each amide and a qualitative comparison of the substituent effects on the various steps. 

In the manner outlined, a few attempts have been made to apply the Hammett equation to the transmission of substituent effects in the pyridine series. In the alkaline hydrolysis of 5-substituted ethyl picolinates (5-R-2-COOEt) in 85% ethanol at 25, 35, and 45°, the reaction constants are about 60% as large as those in the corresponding benzene series the overall fit to the Hammett equation, however, is at best fair, since out of four points (R = Et, H, I, Ac) one (Ac) deviates widely. 

The rate acceleration imposed by 0-cyclodextrin was explained in terms of a microsolvent effect 6> The inclusion of the substrate within the hydrophobic cavity of cyclodextrin simulates the changes in solvation which accompany the transfer of the substrate from water to an organic solvent. Uekama et al.109) have analyzed the substituent effect on the alkaline hydrolysis of 7-substituted coumarins (4) in the... 

The most frequently encountered hydrolysis reaction in drug instability is that of the ester, but curtain esters can be stable for many years when properly formulated. Substituents can have a dramatic effect on reaction rates. For example, the tert-butyl ester of acetic acid is about 120 times more stable than the methyl ester, which, in turn, is approximately 60 times more stable than the vinyl analog [16]. Structure-reactivity relationships are dealt with in the discipline of physical organic chemistry. Substituent groups may exert electronic (inductive and resonance), steric, and/or hydrogen-bonding effects that can drastically affect the stability of compounds. A detailed treatment of substituent effects can be found in a review by Hansch et al. [17] and in the classical reference text by Hammett [18]. 

Introduction of 3,5-dimethyl and 4-substituent on the Phebox skeleton revealed a weak substituent effect on the degree of asymmetric induction (Scheme 15) [28,29]. When trimethylsilyl acrylate was used as enolate source, the (3-hydroxy carboxylic acid was obtained directly upon mild acid hydrolysis. In the production of carboxylic acid 49, an enantiomeric excess of 96% ee was attained using the NC -substituted Phebox-Rh catalyst. 

Furthermore, the addition of dichlorocarbene to ene-ynes proved to be remarkably sensitive to substituent effects. Trans-1,4-diphenyl butenyne gave only the cyclopropenone 17 via hydrolysis of dichlorocyclopropene 16, however, 2-methyl-pentene-l-yne-3 favored the formation of the dichlorocyclopropane 18 with only traces of products resulting from addition to the triple bond ... 

These micellar charge effects also seem to be present for reactions at heteroatoms. For example, in the spontaneous hydrolysis of a series of benzenesulfonyl chlorides (12), values of k+/k for reactions in CTAC1 and SDS increase from 0.85 for X = OMe to 22 for X = NOz, suggesting that there is a substituent effect upon the relative extents of bond-making and breaking (Bunton et al., 1985). 

Aromatic substituent effects due to phosphorus groups have been studied for a number of reactions.47 Thus ester hydrolysis and fluoride-displacement rates, for (56) and (57) respectively, are enhanced by phosphorus substituents (X = O or ), while the rate of hydrolysis of the halide (58) is enhanced for X = , but slowed for X = O.47 A perturbation M.O. analysis of these observations has been presented.48... 

In the following paragraphs, we will discuss the substituent effects that influence the rate of hydrolysis of the /3-lactam bond in acidic and alkaline solutions. 

We begin the discussion with one of the major sites of structural variation, namely at C(6) in penicillins and at C(7) in cephalosporins (Table 5.4,A). Electron-withdrawing substituents at C(6) in penicillins and at C(7) in cephalosporins increase the rate of base-catalyzed hydrolysis [76]. The same substituent effect has been observed for monobactams [93] [94],... 

M. Narisada, T. Yoshida, M. Ohtani, K. Ezumi, M. Takasuka, Synthesis and Substituent Effects on Antibacterial Activity, Alkaline Hydrolysis Rates, and Infrared Absorption Frequencies of Some Cephem Analogues Related to Latamoxef (Moxalactam) , J. Med. Chem. 1983, 26, 1577-1582. 

M. Narisada, J. Nishikawa, F. Watanabe, Y. Terui, Synthesis and 3 -Substituent Effects of Some 7a-Methoxy-l-oxacephems on Antibacterial Activity and Alkaline Hydrolysis Rates , J. Med. Chem. 1987, 30, 514-522. 

The acid-catalysed hydrolysis of the acylal, 1-phenoxyethyl propionate (13), has been studied using the PM3 method in the gas phase. The kinetics and mechanism of the hydrolysis of tetrahydro-2-furyl and tetrahydropyran-2-yl alkanoates (14) in water and water-20% ethanol have been reported. In acidic and neutral media, kinetics, activation parameters, isotope-exchange studies, substituent effects, solvent effects and the lack of buffer catalysis pointed clearly to an Aai-1 mechanism with formation of the tetrahydro-2-furyl or tetrahydropyran-2-yl carbocation as the rate-limiting step (Scheme 1). There is no evidence of a base-promoted Bac2 mechanism up to pH 12. ... 

Craze and Kirby (1974) have recently proposed that hydrolysis of methoxymethoxybenzoic acids proceeds with intramolecular general acid catalysis with little proton transfer from the carboxyl group and aleurge amount of bond breaking in the transition state. This suggestion was, however, based solely on substituent effects and a graphical analysis using the extended 4-parameter Hammett Equation (see Section 2). 

Weeks and Crane (1973) have recently studied acid-catalysed hydrolysis of 3-methoxyphthalide in aqueous sulfuric acid. Values of AS (—3"1 e.u.), Ah/ d (0 51) and a linear plot of log obsd vs. —Hq with a slope of 0-96 were consist2mt with an A-1 mechanism. A cyclic carbonium ion intermediate was proposed on the basis of substituent effects at the 3-position, the following reactivities being observed H > CH3 > Et Ph. It was thought that A-1 ring opening... 

Structures have been determined for [Fe(gmi)3](BF4)2 (gmi = MeN=CHCF[=NMe), the iron(II) tris-diazabutadiene-cage complex of (79) generated from cyclohexanedione rather than from biacetyl, and [Fe(apmi)3][Fe(CN)5(N0)] 4F[20, where apmi is the Schiff base from 2-acetylpyridine and methylamine. Rate constants for mer fac isomerization of [Fe(apmi)3] " were estimated indirectly from base hydrolysis kinetics, studied for this and other Schiff base complexes in methanol-water mixtures. The attenuation by the —CH2— spacer of substituent effects on rate constants for base hydrolysis of complexes [Fe(sb)3] has been assessed for pairs of Schiff base complexes derived from substituted benzylamines and their aniline analogues. It is generally believed that iron(II) Schiff base complexes are formed by a template mechanism on the Fe " ", but isolation of a precursor in which two molecules of Schiff base and one molecule of 2-acetylpyridine are coordinated to Fe + suggests that Schiff base formation in the presence of this ion probably occurs by attack of the amine at coordinated, and thereby activated, ketone rather than by a true template reaction. ... 

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