Pivalate derivative

The chiral diazo ester 27 was cychzed [16] with four commonly used rhodium car-boxylate catalysts (Tab. 16.2), wherein the rhodium pivalate [20] (entry 4) was most efficient for forming the cyclopentanes, and the rhodium trifluoroacetate (entry 1) was optimum for forming alkenes [21]. Furthermore, it was demonstrated that the yield of the cyclization and the diastereoselectivity could be improved at lower temperature using the pivalate-derived catalyst (entry 5). 

A pivalate derivative of Tcf, Tc2(02CCMe3)4Cl2, is prepared in low yield from (NH4)3Tc2Cl8 and hot pivalic acid [Tc-Tc 219 pm]" . The structure of Tc2(OC5H4N)4Cl, formed from (NH4)3Tc2Cl8 and 2-hydroxypyridine at 150 C, a Tcf" unit with a Tc-Tc distance of 209.5 pm . 

The pivalate derivative Mo2(02CC(CH3)3)4 was prepared most conveniently by reaction of Mo(CO)g with the calculated amount of pivalic acid in refluxing o-dichlorobenzene. The compound crystallized as slender yellow needles when the reaction mixture was cooled to room temperature it was filtered, washed with benzene and cyclohexane, and dried in vacuo. IR data for Moo(02CC(CH3)3)4 are included in Table I. The following lines were observed in the X-ray powder pattern 11.49 w, 10.46 s, 9.16 s, 6.36 s, 5.69 m, 5.51 m, 5.01 s, 4.59 s, 4.26 w, and 4.13 m. 

Pha.rma.ceutica.ls. Neopentanoic acid derivatives are widely used in the preparation of pharmaceuticals, eg, as a means of introducing the tert-huty group into a molecule. More frequendy, however, derivatives have been prepared that exploit the enhanced hydrolytic stabiUty of the neopentanoate group. Eor example, when salmon calcitonin is treated with N-hydroxysuccinimide pivalate [42014-50-6], the resulting derivative retains the biological activity of the precursor, but gives an extended duration of activity (51). 

Reaction of the cyclopropyl-substituted pivalate (25) with dimethyl benzylidenema-lonate in the presence of a palladium catalyst gave a mixture of alkylidenecyclo-propane (26) and vinylcyclopropane (27). The ratio of these two adducts is found to be quite sensitive to the choice of ligand and solvent. While triisopropyl phosphite favors the formation of the methylenecyclopropane (26), this selectivity is completely reversed with the use of the bidentate phosphite ligand dptp (12). Interestingly there was no evidence for any products that would have derived from the ring opening of the cyclopropyl-TMM intermediate (Scheme 2.8) [18]. 

Activity is also retained when oxygen at the 21 position is replaced by sulfur. Preparation of one of these compounds follows a route quite analogous to the foregoing thus, displacement of the mesylate group in the cortisone (56) derivative 57 with the anion from thiopivalic acid affords thioester 58. Reduction of the 11-ketone by means of borohydride affords tixocortol pivalate (59)[13j. 

A potential liability associated with such reductive hydroacylations resides in the fact that only one acyl residue of the symmetric anhydride is incorporated into the coupling product. For more precious carboxylic acids, selective acyl transfer from mixed anhydrides is possible. Mixed anhydrides derived from pivalic acid are especially convenient, as they may be isolated chromato-graphically in most cases. In practice, mixed anhydrides of this type enable completely branch-selective hydroacylation with selective delivery of the aromatic and a,()-unsalurated acyl donors (Scheme 19). 

Scheme 19 Selective acyl transfer in reductive hydroacylations involving mixed carboxylic anhydrides derived from pivalic acid...

An alternative strategy for selective intermolecular G-H insertions has been the use of rhodium carbenoid systems that are more stable than the conventional carbenoids derived from ethyl diazoacetate. Garbenoids derived from aryldiazoacetates and vinyldiazoacetates, so-called donor/acceptor-substituted carbenoids, have been found to display a very different reactivity profile compared to the traditional carbenoids.44 A clear example of this effect is the rhodium pivalate-catalyzed G-H insertion into cyclohexane.77 The reaction with ethyl diazoacetate gave the product only in 10% yield, while the parallel reaction with ethyl phenyldiazoacetate gave the product in 94% yield (Equation (10)). In the first case, carbene dimerization was the dominant reaction, while this was not observed with the donor/acceptor-substituted carbenoids. 

Another representative highlight of the regioselective O-acylation work undertaken at QEC can be found in Richardson s selective O-pivaloylation of sucrose, which led to two papers with Les Hough and Manjit Chowdhary. One of these was on the regioselective O-pivaloylation itself, the other on the applications of the pivalate products in the preparation of various ring-modified sucrose derivatives. 

Although 68e could not be prepared, the less reactive pivalic acid ester analogues 71a-d (Scheme 29) were synthesized. Hydrolysis rate constants at 40°C were pH independent from pH 1.0 to 7.0 and k i,s correlated with to give a of —6.0. The products derived from 71a-c are summarized in Scheme 29. These products are consistent with a nitrenium ion mechanism. In particular, the products and product ratios derived from the meta-hxomo ester 71b were consistent with those previously reported for 68e and the Bamberger rearrangement of N-(3-bromophenyl)hydroxylamine, with the exception of the rearrangement products. The rearrangement products 72 appear to be derived from intramolecular aminolysis of 73. These... 

The para-nitro ester 71d generated only 4-nitroaniline (70%) and 4,4 -dinitroazoxybenzene (10%) when it underwent decomposition (Scheme 29). These products could have been derived from either a triplet nitrene or a triplet nitrenium ion precursor. Homolysis of the N—O bond to generate radical intermediates was ruled out because of the nearly quantitative yield of pivalic acid derived from 71d. The pivaloxy radical would have undergone rapid decarboxylation to generate CO2 and the rert-butyl radical under these conditions. Since no rearrangement product was observed, it was tentatively concluded that this ester underwent direct decomposition to 4-nitrophenyl-nitrene without the intermediacy of a nitrenium ion. ... 

Shortly after Anderson and Falvey reported the first observation of a shortlived nitrenium ion in CH3CN by UV spectroscopy, Novak and McClelland and co-workers demonstrated that the nitrenium ions 75h and 75o could be observed in aqueous solution after LFP of the pivalic acid ester 76h, the sulfuric acid ester 76o, and its N-chloro analogue N-chloro-4-phenylacetanilide. The transients with A ax of ca. 450 nm were identified as singlet nitrenium ions, based on the kinetics of their decomposition in the presence of NJ, the equivalence of kaz/ks determined by the azide clock method and by direct observation, the lack of sensitivity of the transients to O2, product studies that showed similar products from solvolytic and photolytic decomposition of N-chloro-4-phenylacetanilide, and identical transient UV spectra for 75o derived either from 76o or its N-chloro analogue. A comparison of azide/solvent selectivity data obtained by azide clock and direct observation of 7Sh and 75o is presented in Table 1. 

Problem 16.1 Give a derived and lUPAC name for the following carboxylic acids. Note the common names, (a) CH,(CH,) COOH (caproic acid) (b) (CH,),CCOOH (pivalic acid) (c) (CH,)X HCH,CH,COOH ( y-methylvaleric acid) (d) C H,CH,CH,COOH (/3-phenylpropionic acid) (e) (CH,),C(OH)COOH (a-hydroxyisobutyric acid) (/) H06C(CH,),C00H (succinic acid) (no derived name). ... 

In subsequent years, much evidence has been adduced to support this mechanism. Alkaline phosphatase and, by analogy, other serine enzymes, are directly phosphorylated on serine serine phosphate is not an artifact (Kennedy and Koshland, 1957). In the presence of nitrophenyl acetate, chymotrypsin is acetylated on serine, and the resulting acetylchymotrypsin has been isolated (Balls and Aldrich, 1955 Balls and Wood, 1956). Similarly, the action of p-nitrophenyl pivalate gave rise to pivaloyl chymotrypsin, which could be crystallized (Balls et al., 1957). Neurath and workers showed that acetylchymotrypsin is hydrolyzed at pH 5.5, but that it is reversibly denatured by 8 M urea the denatured derivative is inert to hydrolysis and even to hydroxylamine, whereas the renatured protein, obtained by... 

While MS-MS allows for unequivocal identification of most metabolites, there are a few exceptions. In particular, the short-chain acylcarnitines of 4 and 5 carbons represent more than one analyte. C4-Acylcarnitine is known to be a mixture of bu-tyrylcarnitine derived from fatty acid metabolism and isobutyrylcarnitine derived from the metabolism of valine (Fig. 3.2.3) [21, 58]. C5-Acylcarnitine is a mixture of isovalerylcarnitine and 2-methylbutyrylcarnitine derived from leucine and isoleucine degradation, respectively (Fig. 3.2.4) [20, 59]. Samples of patients treated with antibiotics containing pivalic acid may contain pivaloylcarnitine another C5 species... 

The Z-protected derivative, again prepared by standard methods using benzyl chloroformate,t208 may serve in the case of racemic pipecolic acid for resolution into the pure enantiomers by fractional crystallization with L-tyrosine hydrazide/208 Acylation with N-protected pipecolic acid or of pipecolyl peptides is performed by standard procedures via the active ester methods, e.g. A-hydroxysuccinimide ester/121 by the mixed anhydride method, e.g. with isobutyl chloro-formate 95-114 or pivalic acid chloride/121 as well as by DCC/HOBt/118 In the synthesis on solid support, longer coupling times are required when compared to N-protected proline.1[235 ... 

Less reactive than acyl halides, but still suitable for difficult couplings, are symmetric or mixed anhydrides (e.g. with pivalic or 2,6-dichlorobenzoic acid) and HOAt-derived active esters. HOBt esters smoothly acylate primary or secondary aliphatic amines, including amino acid esters or amides, without concomitant esterification of alcohols or phenols [34], HOBt esters are the most commonly used type of activated esters in automated solid-phase peptide synthesis. For reasons not yet fully understood, acylations with HOBt esters or halophenyl esters can be effectively catalyzed by HOBt and HOAt [3], and mixtures of BOP (in situ formation of HOBt esters) and HOBt are among the most efficient coupling agents for solid-phase peptide synthesis [2]. In acylations with activated amino acid derivatives, the addition of HOBt or HOAt also retards racemization [4,12,35]. 

The alkylation products are synthetically useful because simple subsequent transformations furnishes precursors of important natural products as illustrated in Scheme 8E.23. Simple oxidative cleavage of allylic phthalimide 45 generates protected (5)-2-aminopimelic acid, whose dipeptide derivatives have shown antibiotic activity. The esterification via deracemization protocol is not limited to the use of bulky pivalic acid. The alkylation with sterically less hindered propionic acid also occurs with high enantioselectivity to give allylic ester 116, which has been utilized as an intermediate towards the antitumor agent phyllanthocin and the insect sex excitant periplanone. Dihydroxylation of the enantiopure allylic sulfone gives diol 117 with complete diastereoselectivity. Upon further transformation, the structurally versatile y-hydroxy-a,(f-un-saturated sulfone 118 is readily obtained enantiomerically pure. 

Another estimate seemed to support an inductive contribution to deuterium IEs on the acidity of carboxylic acids.37 This IE on acidity of some carboxylic acids was attributed to an inductive effect arising from the electrostatic interaction of the C-H or C-D dipole with the negative charge of the carboxylate, as expressed in Equation (31). The derivative dpK/dfi was estimated from the effect of a C-Cl dipole on acidity, using the difference in pATas of trichloroacetic acid (0.63) and acetic acid (4.75) and the difference between the dipole moments of t-butyl chloride (2.13 D) and isobutane (-0.13 D). Next Afj, was estimated as 0.0086 D, the difference between the dipole moments of (CH3)3CD and (CH3)3CH. Thus ApK was estimated as 0.005 per D, in excellent agreement with the observed 0.014 for acetic-d3 acid. Moreover, the IE of 0.002 per D in pivalic-J9 acid is consistent with a 2.8-fold falloff factor for inductive effects. Yet those estimates depend crucially on the difference between the dipole moments of isobutane and isobutane-d, which is unusually large, amounting to 6.5% of either s total dipole moment. 

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