Dynamic aldehydes

The thermal glass-transition temperatures of poly(vinyl acetal)s can be determined by dynamic mechanical analysis, differential scanning calorimetry, and nmr techniques (31). The thermal glass-transition temperature of poly(vinyl acetal) resins prepared from aliphatic aldehydes can be estimated from empirical relationships such as equation 1 where OH and OAc are the weight percent of vinyl alcohol and vinyl acetate units and C is the number of carbons in the chain derived from the aldehyde. The symbols with subscripts are the corresponding values for a standard (s) resin with known parameters (32). The formula accurately predicts that resin T increases as vinyl alcohol content increases, and decreases as vinyl acetate content and aldehyde carbon chain length increases. 

Additional evidence that a dynamic equilibrium exists between an enamine, N-hemiacetal, and aminal has been presented by Marchese (41). It should be noted that no acid catalysts were used in the reactions of aldehydes and amines discussed thus far. The piperidino enamine of 2-ethylhexanal (0.125 mole), morpholine (0.375 mole), and p-toluene-sulfonic acid (1.25 x 10 mole) diluted with benzene to 500 ml were refluxed for 5 hr. At the end of this time the enamine mixture was analyzed by vapor-phase chromatography, which revealed that exchange of the amino residue had occurred in a ratio of eight morpholine to one piperidine. Marchese proposed a scheme [Eqs. (4), (5) and (6)] to account for these... 

The dynamic resolution of an aldehyde is shown in Figure 8.40. The racemization of starting aldehyde and enantioselective reduction of carbonyl group by baker s yeast resulted in the formation of chiral carbon centers. The enantiomeric excess value of the product was improved from 19 to 90% by changing the ester moiety from the isopropyl group to the neopentyl group [30a]. 

Other biocatalysts were also used to perform the dynamic kinetic resolution through reduction. For example, Thermoanaerobium brockii reduced the aldehyde with a moderate enantioselectivity [30b,c], and Candida humicola was found, as a result of screening from 107 microorganisms, to give the (Jl)-alcohol with 98.2% ee when ester group was methyl [30dj. 

When a reverse procedure was applied, i.e. enzymatic acetylation of racemic 3, formed in situ from the appropriate aldehydes and thiols, the reaction proceeded under the conditions of dynamic kinetic resolution and gave enantiomerically enriched acetates 2 with 65-90% yields and with ees up to 95% (Equation 2). It must be mentioned that the addition of silica proved crucial, as in its absence no racemization of the initially formed substrates 3 occurred and the reaction stopped at the 50% conversion. 

The ability of enzymes to achieve the selective esterification of one enantiomer of an alcohol over the other has been exploited by coupling this process with the in situ metal-catalysed racemisation of the unreactive enantiomer. Marr and co-workers have used the rhodium and iridium NHC complexes 44 and 45 to racemise the unreacted enantiomer of substrate 7 [17]. In combination with a lipase enzyme (Novozyme 435), excellent enantioselectivities were obtained in the acetylation of alcohol 7 to give the ester product 43 (Scheme 11.11). A related dynamic kinetic resolution has been reported by Corberdn and Peris [18]. hi their chemistry, the aldehyde 46 is readily racemised and the iridium NHC catalyst 35 catalyses the reversible reduction of aldehyde 46 to give an alcohol which is acylated by an enzyme to give the ester 47 in reasonable enantiomeric excess. 

Photocatalytic oxidation is a novel approach for the selective synthesis of aldehyde and acid from alcohol because the synthesis reaction can take place at mild conditions. These reactions are characterized by the transfer of light-induced charge carriers (i.e., photogenerated electron and hole pairs) to the electron donors and acceptors adsorbed on the semiconductor catalyst surface (1-4). Infrared (IR) spectroscopy is a useful technique for determining the dynamic behavior of adsorbed species and photogenerated electrons (5-7). 

A catalyst used for the u-regioselective hydroformylation of internal olefins has to combine a set of properties, which include high olefin isomerization activity, see reaction b in Scheme 1 outlined for 4-octene. Thus the olefin migratory insertion step into the rhodium hydride bond must be highly reversible, a feature which is undesired in the hydroformylation of 1-alkenes. Additionally, p-hydride elimination should be favoured over migratory insertion of carbon monoxide of the secondary alkyl rhodium, otherwise Ao-aldehydes are formed (reactions a, c). Then, the fast regioselective terminal hydroformylation of the 1-olefin present in a low equilibrium concentration only, will lead to enhanced formation of n-aldehyde (reaction d) as result of a dynamic kinetic control. 

Corwen [140] used dynamic purge and trap analysis to determine ketones and aldehydes (acetone, butyaldehyde, and 2-butanone) in seawater. 

Transfer hydrogenation is a mild and efficient means of reducing aldehydes, and can be advantageous over other reagents such as sodium borohydride. Clearly, the product is a primary alcohol and therefore not chiral, but a chiral center might be alpha to the aldehyde, in which case a resolution can be effected. Indeed, under the appropriate conditions the chiral center can be race-mized and a dynamic kinetic resolution effected [57]. 

The asymmetric hydroformylation of aryl ethenes such as substituted styrene and substituted -naphthyl ethene will lead to the intermediates for important pharmaceuticals. Much concerted effort has been applied to achieve high enantioselectivity as well as high regioselectivity toward the branched aldehydes. The research work in this area is of great industrial interest, and it continues to be a dynamic field of study. 

Wipf et al. <2005OL4483> elaborated a new metathesis method including ring opening in order to generate dynamic combinatorial libraries. The transformation is shown in Scheme 12. The essence of this method is the recognition that an equilibrium takes place with 93 and an aldehyde in aqueous conditions at pH 4 in a phosphate buffer. With the help of this transformation, a series of new R2-substituted products 94 - not available via direct ring closure - have been synthesized. 

The threading-followed-by-capping method has been recently employed by Stoddart to prepare a [2]rotaxane under thermodynamic control [60]. In this approach, the dibenzylammonium ion 28 - which is terminated by an aldehyde function - is mixed with the dibenzo[24]crown-8 ether (20) to form a threaded species. Upon addition of a bulky amine, the aldehyde-terminated template can be converted into an imine in a reversible reaction establishing a dynamic equilibrium (see 29 and 30 in Scheme 17). 

AltshuUer. A. P.. D. L. Klosterman, P. W. Leach. I. J. Hindawi, and J. E. Sigsby. Jr. Products and biological effects from irradiation of nitrogen oxides with hydrocarbons or aldehydes under dynamic conditions. Int. J. Air Water Pollut. 10 81-96, 1966. 

Another process mechanistically related to imine exchange is the dynamic production of pyrazolotriazinones reported in 2005 by Wipf and coworkers [29]. After first verifying that reaction of either 16 or 17 with equimolar quantifies of isobutyraldehyde and hydrocinnamaldehyde at 40°C in water (pH 4.0) resulted in the same 3 7 mixture of 16 and 17 at equilibrium (Fig. 1.6, Eq. 1), the authors demonstrated that a library could be generated by reaction of pyrazolotriazinone 16 with a series of aldehydes (Fig. 1.6, Eq. 2). Direct metathesis of pyrazolotriazinones was also demonstrated, as was reaction with ketones. Importantly, equilibration was halted by raising the pH to 7. 

As proof of principle, Lehn and coworkers individually synthesized all acyl hydrazone combinations from the 13 DCL building blocks and measured their inhibition of acetylthiocholine hydrolysis by ACE in a standard assay. They then established a dynamic deconvolution approach whereby the pre-equilibrated DCL containing all members is prepared, frozen, and assayed. Thirteen sublibraries were then prepared containing all components minus one hydrazide or aldehyde component, and assayed. Active components in the DCL were quickly identified by an increase in ACE activity, observed in sublibraries missing either hydrazide 7 or dialdehyde i, pointing to the bis-acyl hydrazone 7-i-7 as the most likely active constituent. This was in line with the individual assay data recorded earlier resynthesis of this compound characterized it as a low nanomolar inhibitor of the enzyme. 

In 2004, Rayner and coworkers reported a dynamic system for stabilizing nucleic acid duplexes by covalently appending small molecules [34]. These experiments started with a system in which 2-amino-2 -deoxyuridine (U-NH ) was site-specifically incorporated into nucleic acid strands via chemical synthesis. In the first example, U-NH was incorporated at the 3 end of the self-complementary U(-NH2)GCGCA DNA. This reactive amine-functionalized uridine was then allowed to undergo imine formation with a series of aldehydes (Ra-Rc), and aldehyde appendages that stabilize the DNA preferentially formed in the dynamic system. Upon equilibration and analysis, it was found that the double-stranded DNA modified with nalidixic aldehyde Rc at both U-NH positions was amplified 34% at the expense of Ra and Rb (Fig. 3.16). The Rc-appended DNA stabilizing modification corresponded to a 33% increase in (melting temperature). Furthermore, imine reduction of the stabilized DNA complex with NaCNBH, resulted in a 57% increase in T. ... 

Figure 3.16 Dynamic combinatorial modification of 2 -amino-2-deoxyuridine (U-NH ) containing DNA by aldehydes Ra-Rc. The nalidixic aldehyde was selectively appended to both U-NH positions resulting in DNA duplex stabilization.

Similarly, the authors also examined the stabilization effect of dynamic modification of a U-NH -appended RNA aptamer that forms a kissing complex with the HIVl transactivation-responsive RNA element TAR. In this dynamic library, 2-chloro-6-methoxy-3-quinofinecarboxaldehyde (Rd) was incorporated in place of benzaldehyde (Ra). After equilibration of the U-NHj-substituted aptamer and aldehydes Rb-Rd in the presence of the TAR RNA target, it was found that the nalidixic aldehyde Rc-appended RNA was amplified 20%, and accompanied by an increased (Fig. 3.17). Interestingly, the nalidixic aldehyde Rc was selected in both DNA and RNA complexation experiments. 

Figure 3.17 Approach to the dynamic combinatorial modification of the TAR-binding aptamer. Left, italics The TAR RNA sequence. Left, bold The TAR-binding aptamer. Left, boxed The 2 -amino-2-deoxyuridine (U-NH ) for dynamic RNA modification. Left center Rb—Rd, the aldehyde library components. Right center Imino-linked DCL members. Right The selected nalidixic aldehyde appended to U-NH results in the TAR RNA-aptamer complex stabilization.

Figure 3.23 Dynamic combinatorial assembly of DNA primers on a template through imine formation between 5 -amino-substituted and 3 -aldehyde-substituted DNA strands.

In order to generate the dynamic cyanohydrin systems, several cyanide sources can be used, for example, cyanide salts, TMSCN, and cyanohydrin adducts such as acetone cyanohydrin. The latter method represents a means to form cyanohydrin DCLs under mild conditions, where acetone cyanohydrin is treated with amine base to release the cyanide ion together with acetone in organic solvents. The resulting cyanide ion then reacts with the set of aldehydes (or ketones), giving rise to the corresponding cyanohydrin adducts... 

The benzaldehydes (23-27) were chosen in order to attain similar reactivities in the cyanohydrin reactions, and thus securing sufficiently unbiased, isoenergetic dynamic systems. The rates of the individual reactions of these benzaldehydes were further investigated by H-NMR, indicahng the establishment of individual aldehyde-cyanohydrin equilibria within 30 minutes. Under these conditions, the complete dynamic cyanohydrin system generated from cyanide and benzaldehydes (23-27) then reached... 

The Catalysis Concept of Iminium Activation In 2000, the MacMillan laboratory disclosed a new strategy for asymmetric synthesis based on the capacity of chiral amines to function as enantioselective catalysts for a range of transformations that traditionally use Lewis acids. This catalytic concept was founded on the mechanistic postulate that the reversible formation of iminium ions from a,p-unsaturated aldehydes and amines [Eq. (11.10)] might emulate the equilibrium dynamics and 7i-orbital electronics that are inherent to Lewis acid catalysis [i.e., lowest unoccupied molecular orbital (LUMO)-lowering activation] [Eq. (11.9)] ... 

Scheme 18 Dynamic kinetic resolution of enolizable aldehydes...

Three years later. List and coworkers extended their phosphoric acid-catalyzed dynamic kinetic resolution of enoUzable aldehydes (Schemes 18 and 19) to the Kabachnik-Fields reaction (Scheme 33) [56]. This transformation combines the differentiation of the enantiomers of a racemate (50) (control of the absolute configuration at the P-position of 88) with an enantiotopic face differentiation (creation of the stereogenic center at the a-position of 88). The introduction of a new steri-cally congested phosphoric acid led to success. BINOL phosphate (R)-3p (10 mol%, R = 2,6- Prj-4-(9-anthryl)-C H3) with anthryl-substituted diisopropylphenyl groups promoted the three-component reaction of a-branched aldehydes 50 with p-anisidine (89) and di-(3-pentyl) phosphite (85b). P-Branched a-amino phosphonates 88 were obtained in high yields (61-89%) and diastereoselectivities (7 1-28 1) along with good enantioselectivities (76-94% ee) and could be converted into... 

When the protocol is applied to allylcarbamates 170, the deprotonation in the presence of (—)-sparteine does not occur with kinetic preference. Indeed, a dynamic resolntion by crystallization takes place. The epimeric allylfithinm componnds 171 and 172 are eqni-librating, whereby one of them crystallizes predominantly. Under optimized conditions, when n-butyllithium is used for the deprotonation and cyclohexane serves as a cosolvent, the preference of the diastereomer 172 leads to snbstimtion products in 90-94% gg393-395 enantioselective homoaldol reaction has been developed based on this protocol Transmetalation of the organolithium into the titaninm compound occnrring nnder inversion of the configuration (172 173) and subseqnent addition to aldehydes leads to... 

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