4- oxazoline carboxylates

Another domino Michael addition/SN sequence has been elaborated by the group of de Meijere. It was discovered that upon basic treatment of 2-chloro-2-cyclopropyl-idenacetates 2-168 with carboxamides 2-169 in MeCN, 4-spirocyclopropane-anne-lated oxazoline-5-carboxylates 2-172 are formed (Scheme 2.40) [91]. As intermediates, the carbanion 2-170 and 2-171 can be proposed. 

Alkyl oxazoline-5-carboxylates 71, precursors of P-amino-a-hydroxycarboxylic acids, have been produced by iodocyclisation of alkyl 3-benzamidocatboxylates 70. The oxazolines can be resolved enzymatically <99SL1727>. The amides 72 are cyclised to N-aryloxazolium salts 73 by fluoroboric acid <99EJ0297>. 

Lee S-H, Yoon J, Nakamura K, Lee Y-S (2000) Efficient Syntheses and Ring-Opening Reactions of trans- and c/5-Oxazoline-5-carboxylates. Org Lett 2 1243... 

Scheme 7.74 de Meijere s domino synthesis of oxazoline-5-carboxylates. 

Following the original report that the oxazoline carboxylic acid 7.5.12 can serve as an excellent side chain precursor 281), several syntheses of this compound have been reported. Thus racemic oxazoline was prepared from protected cinnamyl alcohol by addition of phenyl-selenyl triflate and azide ion to give the adduct 7.5.9, which was then converted to oxazoline 7.5.10 and ester 7.5.11 282). A similar but more efficient route used diphenyldiselenide and ammonium persulfate to give the racemic oxazoline 7.5.10 in 95% yield from cinnamyl acetate 283). 

PMMA-f-oxazoline/carboxylic acid-terminated PS TEM/solid-state NMR/static light scattering Holderle et al. 1998... 

Ring-opening reaction Oxazoline Carboxylic acid, MAn, amine, halide ... 

An example of an additive effect of trialkylalumimun on the diastereoselectivity and efficiency in the particular aldol reaction was reported [30]. During the synthesis of cfasto-lactacystin P-lactone analog (34), Adams and coworkers found that treatment of the frthium enolate of oxazoline carboxylate (35) with 2.2-2.4 equivalent MeaAlCl, prior to the reaction with the aldehyde (36), afforded the desired aldol adduct (37) exclusively (Scheme 6.24). Although detail of the role of... 

ScHOLLKOPF et al (360) reacted a-metallated isocyanoacetic ester with aldehydes and ketones in aprotic solvents to form formyl-enamino acid esters (24) via intermediate oxazoline carboxylic acid esters. 

In readily available (see p. 22f.) cyclic imidoesters (e.g. 2-oxazolines) the ot-carbon atom, is metallated by LDA or butyllithium. The heterocycle may be regarded as a masked formyl or carboxyl group (see p. 22f.), and the alkyl substituent represents the carbon chain. The lithium ion is mainly localized on the nitrogen. Suitable chiral oxazolines form chiral chelates with the lithium ion, which are stable at —78°C (A.I. Meyers, 1976 see p. 22f.). 

A number of 2-acylazetidines have been prepared by reaction of 1,3-dihaloacyl compounds with amino derivatives (Section 5.09.2.3.l(m)). This is illustrated for azetidine 2-carboxylic acid (56), the only known naturally occurring azetidine. Ring expansion of activated aziridines (43) and contraction of 4-oxazolines (55) has also found limited use (Section 5.09.2.3.2(f) and Hi)). 

In turn the oxazoline-containing polymer may then react very rapidly (e.g. at 240°C) with such groups as carboxyls, amines, phenols, anhydrides or epoxides, which may be present in other polymers. This reaction will link the two polymers by a rearrangement reaction similar to that involved in a rearrangement polymerisation without the evolution of water or any gaseous condensation products (Figure 7.14). 

Chiral oxazolines developed by Albert I. Meyers and coworkers have been employed as activating groups and/or chiral auxiliaries in nucleophilic addition and substitution reactions that lead to the asymmetric construction of carbon-carbon bonds. For example, metalation of chiral oxazoline 1 followed by alkylation and hydrolysis affords enantioenriched carboxylic acid 2. Enantioenriched dihydronaphthalenes are produced via addition of alkyllithium reagents to 1-naphthyloxazoline 3 followed by alkylation of the resulting anion with an alkyl halide to give 4, which is subjected to reductive cleavage of the oxazoline moiety to yield aldehyde 5. Chiral oxazolines have also found numerous applications as ligands in asymmetric catalysis these applications have been recently reviewed, and are not discussed in this chapter. ... 

The important factors that affect the rubber toughening are (1) interfacial adhesion, (2) nature of the matrix, (3) concentration of the rubber phase, and (4) shape and size of the rubber particles. In the PS-XNBR blend containing OPS, due to the reaction between oxazoline groups of OPS and carboxylic groups of XNBR, the interfacial adhesion increases and as a result, the minor rubber phase becomes more dispersed. The immiscible blend needs an optimum interfacial adhesion and particle size for maximum impact property. In PS-XNBR, a very small concentration of OPS provides this optimum interfacial adhesion and particle size. The interfacial adhesion beyond this point does not necessarily result in further toughening. 

N-Acylaziridine-2-carboxylates readily rearrange to oxazolines under thennal, acidic, or nucleophilic conditions [91, 123-127]. Treatment of trans-aziridine-2-car-boxylate 176 (Scheme 3.63) with Nal in acetonitrile, for example, resulted in ring-expansion product 177 through the so-called Heine reaction. The reaction involves initial opening of the aziridine ring by iodide and subsequent oxazoline ring-closure by Sn2 displacement of the resultant iodide intermediate [127]. 

Scheme 15 Parallel synthesis of 2-oxazolines from carboxylic acids and aminoalcohols using PS-Mukaiyama reagent...

When the reaction is run with potassium fert-butoxide in THF at -5°C, one obtains (after hydrolysis) the normal Knoevenagel product (32), except that the isocyano group has been hydrated (16-65). With the same base but with DME as solvent the product is the nitrile (33). When the ketone is treated with 31 and thallium(I) ethoxide in a 4 1 mixture of absolute ethanol and DME at room temperature, the product is a 4-ethoxy-2-oxazoline (34). Since 33 can be hydrolyzed to a carboxylic acid and 34 to an a-hydroxy aldehyde, this versatile reaction provides a means for achieving the conversion of RCOR to RCHR COOH, RCHR CN, or RCR (OH)CHO. The conversions to RCHR COOH and to RCHR CN have also been carried out with certain aldehydes (R = H). 

Whereas cycHzation of the cu-keto-co -hydroxyamide 1466 in boihng toluene or xylene in the presence of camphorsulfonic acid (CSA) results in decomposition of the starting material 1466, heating of 1466 with excess TMSOTf 20 and N-methyl-morphoHne in 1,2-dichloroethane affords 46% of the desired cycHzation product 1467 [30] (Scheme 9.16). The close relationship of product 1467 to d -oxazolines suggests that reaction of carboxylic acids 11 with free (or C-substituted) ethanola-mines 1468 and HMDS 2/TCS 14 might lead analogously, via the silylated intermediates 1469, to d -oxazolines 1470 and HMDSO 7. As demonstrated in the somewhat related cyclization of 1466 to 1467, combination of TMSOTf 20 with N-... 

To examine if the higher catalytic activity and selectivity of 47a as compared to the COP-X system 46 is mainly caused by the pentaphenyl ferrocenium or by the imidazoline moiety, oxazoline 53-Cl was prepared in diastereomerically pure form starting from carboxylic acid 51 and (5)-valinol via oxazoline 52 (Fig. 27) [73]. 

Carboxylic acids can be protected as oxazolines [96, 105-107, 186, 191] or as ester functions. Alkynic esters such as silyl esters [153, 211], tert-butyl esters [216], and even benzyl esters [153, 211] have been successfully hydrozirconated when the reactive site was a terminal alkyne or vinyl group (Scheme 8-27). 

In 2003, Bonini et al. reported a new synthesis of ferrocenyloxazolines based on an iodide-mediated ring expansion of A-ferrocenoyl-aziridine-2-carboxylic esters. The thus-formed ligands were successfully employed as palladium chelates for the test reaction, since they allowed the product to be formed in quantitative yields and good to high enantioselectivities (Scheme 1.69). According to the results, it seemed that the additional chiral centre present in the oxazoline backbone of these ligands did not play a major role for the asymmetric induction and the activity of the corresponding catalysts. 

Polyamides containing a-aminoacid units are readily obtained by reaction of bisazlactones (2-oxazolin-5-ones) with diamines. When polyamines such as diethylenetriamine (DETA) or triethylenetetramine (TETA) are used as the diamine component, the resultant polyamides readily cyclodehydrate above 200°C to produce polymers containing 2-imidazolin-5-one units in the backbone. Polyamides derived from simple diamines (e.g. 1,6-hexanedi amine) cyclodehydrate only in the presence of a suitable catalyst. Carboxylate salts and certain Lewis acids have been found to be efficient catalysts for this transformation. 

Because of the easy conversion of A-acylaziridines[471 into oxazolines, this method is also useful for protecting carboxylic acids furthermore, it is a means for resolving chiral carboxylic acids. 

Oxazolines have also been obtained from aziridines and carboxylic imidazolides via iV-acylaziridinesJ1271 Isomerization of the Af-acylaziridines can be achieved by heating with a catalytic amount of tetrabutylammonium iodide or bromide. The transformation can be carried out as a one-pot reaction in quantitative yield (solvents THF, CHC13, benzene) with a wide spectrum of substituents R (R = H, alkyl, c-C6Hi i, C6H5,3-pyridyl). 

It is worth mentioning here that the spirocyclopropyl-substituted oxazoline-5-car-boxylates 2-172, as well as the corresponding thiazoline-4-carboxylates, can be transformed into cyclopropyl-substituted amino acids, which might act as potential enzyme inhibitors [93] and interesting building blocks for peptidomimetics [94]. 

A direct catalytic conversion of esters, lactones, and carboxylic acids to oxazolines was efficiently achieved by treatment with amino alcohols in the presence of the tetranuclear zinc cluster Zn4(0C0CF3)60 as catalyst, essential for condensation and cyclodehydration reactions. For example, the use of (5)-valinol allowed the easy synthesis of oxazolines 125 and 126 in satisfactory yields <06CC2711>. A one-pot direct preparation of various 2-substituted oxazolines (as well as benzoxazoles and oxadiazoles) was also performed from carboxylic acids and amino alcohols (or aminophenols or benzhydrazide) using Deoxo-Fluor reagent <06TL6497>. 

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