Imidazoline carboxylates

A similar example to obtain imidazoline carboxylic acids 1422 from a palladium-catalyzed multicomponent condensation reaction employs an imine 1420, an acid chloride 1421 and CO (Scheme 367). The reaction is also believed to proceed through a putative miinchnone intermediate <2001AGE3228>. 

The palladium catalyzed coupling of imine, carbon monoxide and acid chloride is reported as a new route to prepare peptide-based imidazoline-carboxylates. Mechanistic studies suggest this process proceeds via the palladium catalyzed generation of l,3-oxazolium-5-oxide intermediates, which react with imine to generate the observed products. 

The synthesis of carboxylate-substituted imidazoline derivatives has previously been accomplished by the condensation of presynthesized 1,2-diamines with amides, or through the transition metal catalyzed aldol-type reaction between isocyanates and imines (4,5). We have recently communicated an alternative palladium catalyzed route to synthesize a new class of imidazoline carboxylates, utilizing acid chloride, imines and carbon monoxide as starting materials (see Table 1)... 

Table 1 Palladium Catalyzed Synthesis of Imidazoline-Carboxylates.

This imidazoline-carboxylate synthesis involves the coupling of four separate cont5)onents (two imines, an acid chloride and carbon monoxide), and the generation of at least five separate bonds, all via a one-pot, palladium catalyzed process. From an analysis of the structure of the imidazoline carboxylate, the individual constituents can be seen (Figure 3). This stmcture might be considered to arise from the dipolar cycloaddition of an imine with a mesoionic l,3-oxazolium-5-oxide (5) intermediate, which itself could be generated from imine, acid chloride and carbon monoxide. Consistent with this potential formulation, performing the catalytic reaction with CO leads to the incorporation of the carbon-13 label into the carboxylate position of 4. 

The role of acid in influencing the cyclization of 14 with imines towards imidazolines products is at present unclear. One possibility is suggested by the work of Ferraccioli and Croce (16), who have shown that the electronic nature of the imine can have a significant influence upon its reactivity with Munchnone. In particular, while N-alkyl substituted imines react with Munchnones to form (3-lactams, more electron poor imines, such as the N-tosyl substituted substrates, have been found to undergo a 1,3-dipolar cyclization with 14 to form imidazoles. (16) In our case, the role of acid may be in protonation of the imine substrate, thereby creating a more electrophilic C=N which can undergo a dipolar cycloaddition with 14 (path A, Scheme 2). Subsequent heterolysis of the C-0 bond in 18, would yield the observed imidazoline-carboxylate 17. 

These types of surfactants exhibit anionic properties at high pH and cationic properties at low pH and may be categorized as [87] jS-iV-alkylaminopropionic acids, TZ-alkyl-yS-iminodipropionic acids, imidazoline carboxylates, W-alkylbetaines and amine oxides. The sulfobetaines are amphoteric at all values of pH. These surfactants are not commonly used in emulsion polymerization formulations. 

Amphoteric Detergents. These surfactants, also known as ampholytics, have both cationic and anionic charged groups ki thek composition. The cationic groups are usually amino or quaternary forms while the anionic sites consist of carboxylates, sulfates, or sulfonates. Amphoterics have compatibihty with anionics, nonionics, and cationics. The pH of the surfactant solution determines the charge exhibited by the amphoteric under alkaline conditions it behaves anionically while ki an acidic condition it has a cationic behavior. Most amphoterics are derivatives of imidazoline or betaine. Sodium lauroamphoacetate [68647-44-9] has been recommended for use ki non-eye stinging shampoos (12). Combkiations of amphoterics with cationics have provided the basis for conditioning shampoos (13). 

Condensation of aromatic methylesters such as methyl 4-methoxybenzoate 351 a or methyl 4-hydroxybenzoate 351b with excess sodium-HMDS 486 in a mixture of THF-l,3-dimethyl-imidazolin-2-one (DMEU) at 185 °C in a closed vessel affords 59 or 93% of 4-hydroxybenzonitrile 298 as well as 26% 352 with smooth cleavage of the aromatic methyl ether in 351a (Scheme 4.47). Methyl indole-3-carboxylate gives hkewise 3-cyanoindole in 81% yield [127] (cf. also ref [92] in section 4.3). 

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]. 

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. 

Fig. 10 Synthesis of imidazolines or benzimidazoles by condensation of an additional amine with the carboxylic acid-derived carbonyl...

Compositions and functions of typical commercial products in the 2-alkyl-l-(2-hydroxyethyl)-2-imidazolines series are given in Table 29. 2-Alkyl-l-(2-hydroxyethyl)-2-imidazolines are used in hydrocarbon and aqueous systems as antistatic agents, corrosion inhibitors, detergents, emulsifiers, softeners, and viscosity builders. They are prepared by heating the salt of a carboxylic acid with (2-hydroxyethyl)ethylenediamine at 150—160°C to form a substituted amide 1 mol water is eliminated to form the substituted imidazoline with further heating at 180—200°C. Substituted imidazolines yield three series of cationic surfactants by ethoxylation to form more hydrophilic products quatemization with benzyl chloride, dimethyl sulfate, and other alkyl halides and oxidation with hydrogen peroxide to amine oxides. 

Reactions of 1,2-diaminoalkenes with alcohols, aldehydes, or carboxylic acids and derivatives at high temperatures in the presence of a dehydrogenating agent are common approaches to the synthesis of 2-substituted imidazoles (89KFZ1246). In the absence of the dehydrogenating agent the products are imidazolines. 

By analogous fashion to imidazoline synthesis (Section 1.11.4.2.2), oxazolines have been introduced by modification of an acrylonitrile-containing polymer with ethanolamine (75JAP(K)75160392). In another modification (Scheme 99), chloromethylated polystyrene) (192) was treated with a Iithiated oxazoline (207) derived from reaction of 2-methyloxazo-Iine and butyllithium (78MI11106). The oxazoline groups were incorporated, in this study, as intermediates to carboxyl groups. 

Imidazolidine-2-carboxylic acid (15) is also referred to as 3-azaproline. Procedures for the synthesis of protected derivatives have been reported racemic l-(benzyloxycarbonyl)-3-(tert-butoxycarbonyl)imidazoline-2-carboxylic acid [formally identical to l-(te/7-butoxy-carbonyl)-3-(benzyloxycarbonyl)imidazoline-2-carboxylic acid], a useful intermediate for... 

An earlier series of experiments established useful synthetic transformations involving carboxylation of ketones and nitroalkanes to yield P-keto acids and a-nitro acids respectively (Scheme 94).362 363 The reagent is methylmagnesium carbonate and the intermediate (130) can be alkylated with concomitant decarboxylation to provide greater versatility. These reactions can also be extended to ketone functions in imidazoline- and oxazolidine-diones (Scheme 95).364,365... 

Recently, Ikarya has reported the use of imidazolin-2-ylidenes with N-alkyl and N-aryl substituents and their C02 adducts as catalyst of the carboxylative cydiza-tion of internal and terminal propargylic alcohols [215], The reaction of internal propargyl alcohols with C02 has been carried out also under supercritical conditions. Ikariya et al. have developed a synthetic process to afford Z-alkylidene cyclic carbonates promoted by P( -C4H9)3 with high efficiency [216],... 

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