Amide solid-supported

Base catalysis is most effective with alkali metals dispersed on solid supports or, in the homogeneous form, as aldoxides, amides, and so on. Small amounts of promoters form organoalkali comnpounds that really contribute the catalytic power. Basic ion exchange resins also are usebil. Base-catalyzed processes include isomerization and oligomerization of olefins, reactions of olefins with aromatics, and hydrogenation of polynuclear aromatics. 

Application of the Knorr pyrazole synthesis has also been demonstrated on solid support. ° To prepare trisubstituted pyrazoles, the diketone was linked to the solid support to make 57 using a linker with an amide bond. Alkylation of the diketone followed by condensation of the hydrazine with the resulting diketone gave the desired pyrazoles as mixtures of isomers. Subsequent cleavage of the amide bond linker then provided the pyrazole amides 59. ... 

Cross-hnked polyacrylamides are a group of hydrophihc solid supports introduced primarily for preparation of biopolymers (Fig. 4). Unhke PS resins, polyacrylamides have excellent swelling capacity in both protic (water, alcohols) and aprotic (dichloromethane, dimethylformamide) solvents [88]. These beads are stable towards bases, acids, and weak reducing and oxidizing agents [89]. Predictably, conditions under which amide bonds are cleaved (i.e., sodium in liquid ammonia) [90] lead to rapid decomposition of the polymer. 

Brown DS, Revill JM, Shute RE. Merrifield Alpha-Methoxyphenyl (MAMP) Resin A new versatile solid support for the synthesis of secondary amides. Tetrahedron Lett 1998 39 8533-8536. 

The synthesis of azoniaspirocycles can also be carried out on solid support (Scheme 17) <2005JOC9622>. In the following example the resin-bound piperazine-tethered secondary amine 149 underwent an acylation to give amide 150. This was followed by a spontaneous intramolecular displacement of the bromide to yield the trisubstituted azoniaspiroundecane 151. 

In another application, the group of Berteina-Raboin demonstrated the solid-supported synthesis of the indole core of melatonin analogues under microwave irradiation (Scheme 7.6) [26]. A benzoic acid derivative was coupled to Rink amide resin by... 

The first solid-phase application of the Ugi four-component condensation, generating an 18-member acylamino amide library, was presented in 1999 by Nielsen and Hoel [53]. The authors described a library generation utilizing amino-functionalized PEG-polystyrene (Tentagel S RAM) as the solid support (Scheme 7.36). A set of three aldehydes, three carboxylic acids, and two isonitriles was used for the generation of the 18-member library. 

Scheme 7.46 Solid-supported amide synthesis employingthe safety-catch principle.

In a recent study, the group of Buijsman presented a microwave-mediated preparation of a different N-imidazolium-based ionic analogue of the well-known AMEBA solid support (Scheme 7.93). With this soluble support, a set of various sulfonamides and amides was prepared, and furthermore the use of this novel linker in the synthesis of a potent analogue of the antiplatelet drug tirofiban was presented [106]. 

In a detailed investigation, Turner and coworkers have described the preparation and application of solid-supported cyclohexane-1,3-dione as a so-called capture and release reagent for amide synthesis, as well as its use as a novel scavenger resin [125]. Their report included a three-step synthesis of polymer-bound cyclohexane-1,3-dione (CHD resin, Scheme 7.104) from inexpensive and readily available starting materials. The key step in this reaction was microwave-assisted complete hydrolysis of 3-methoxy-cyclohexen-l-one resin to the desired CHD resin. 

The quest for a solvent-free deprotection procedure has led to the use of relatively benign reagent, ammonium persulfate on silica, for regeneration of carbonyl compounds (Scheme 6.10) [48]. Neat oximes are simply mixed with solid supported reagent and the contents are irradiated in a MW oven to regenerate free aldehydes or ketones in a process that is applicable to both, aldoximes and ketoximes. The critical role of surface needs to be emphasized since the same reagent supported on clay surface delivers predominantly the Beckmann rearrangement products, the amides [49]. 

The same authors performed a microwave assisted Stille reaction on the Rink amide (RAM) Tentagel polymer-tethered 4-iodobenzoic acid [5 b]. Successful palladium-catalyzed coupling of heteroaryl boronic acid with anchored 4-iodobenzoic acid enabled both >99% conversion of the starting material within 3.8 min (45 W) and a minimal decomposition of the solid support. The coupling reactions were realized in a mixture of polar solvents (H20-EtOH-DME, 2.5 1.5 6). 

Interestingly, the Suzuki reaction worked smoothly on solid supports and high yields of a variety of products were reported under these reaction conditions (Eq. 11.22) [36]. 4-Bromo- and 4-iodobenzoic acid linked to Rink-amide TentaGel re-... 

An intramolecular Heck cyclization strategy was developed for the construction of indole and benzofuran rings on solid support [82], enabling rapid generation of small-molecular libraries by simultaneous parallel or combinatorial synthesis. Sn2 displacement of resin-bound y-bromocrotonyl amide 97 with o-iodophenol 96 afforded the cyclization precursor 98. A subsequent intramolecular Heck reaction using Jeffery s ligand-free conditions furnished, after double bond tautomerization, the resin-bound benzofurans, which were then cleaved with 30% TFA in CH2CI2 to deliver the desired benzofuran derivatives 99 in excellent yields and purity. 

Parallel Synthesis We start the reaction by using two sets of building blocks, amines (A) and carboxylic acids (B). The amines are first attached to solid supports, normally polystyrene beads coated with linking groups, in separate reaction vessels for each amine. After the amines have been attached, excess unreacted amines are washed off. Next, the carboxylic acids are added to the amines to form the desired amides. We illustrate these steps in Fig. 3.8. Assuming there are 8 amines to react with 12 carboxylic acids in a 96-well plate with 8 rows and 12 columns of tiny wells, the amines, A1 to A8, are added across the rows to each well containing the polystyrene beads. Different types of carboxylic acids, B1 to B12, are added to the wells in each column. 

TFA). Among various linkers studied in this work, the indole linker [21] was found to be the most suitable linker in terms of cleavage kinetics and actual cost. Rink linker was the second best in term of kinetics. The rate of cleavage of various functional groups linked to the above-mentioned resins was as follows sul-fonamide>carbamate urea>amide. Results from this study demonstrated that optimization of cleavage conditions often led to more suitable conditions and safer release of precious compounds synthesized on a solid support. 

Attachment to a solid support via a secondary amide linkage allows ortholithiations to be carried out in the sohd phase. After a reaction with an aldehyde or ketone, refluxing in toluene returns the amino-substituted polymer 41 (Scheme 21). ... 

Two approaches for solid-phase chemical ligation have been described. Canne et al. have developed an elegant system that utilizes an oxime forming ligation to attach the first peptide to the resin, a selectively cleavable ester link to remove the peptide from the resin as a C-terminal carboxylic acid, and the Acm group to protect the N-terminal cysteine residue)311 A complementary approach has been developed by Brik et al. that utilizes native chemical ligation to attach the first peptide to the solid support, a safety-catch acid labile linker to remove the final polypeptide from the support as a C-terminal amide and either Acm or Msc group for N-terminal cysteine protection)32 ... 

Taking advantage of the side-chain linkage of C-terminal trifunctional amino acids to solid supports, related iV-mono(alkyl)amides or Ai-bis(alkyl)amides serve for the production of C-terminally lipidated peptides. So far, this approach has been reported only for the synthesis of a C-terminally mono-alkylated peptide.1 1 ... 

In the following discussion a selection of optimized procedures is presented for the synthesis on solid support of homodetic monocyclic and bicyclic as well as mixed homodetic/ heterodetic bicyclic peptides that contain at least one lactam ring, whereas heterodetic cyclic peptides containing other than amide bonds or peptidomimetics are not discussed here because of their unlimited diversity. 

The majority of cyclic peptides synthesized on solid support are cyclized in the head-to-side-chain or side-chain-to-side-chain mode. For this purpose the amino acids involved in cyclization must be side-chain protected in a manner that allows for an additional level of orthogonal deprotection. Thus, upon assembly of the fully protected linear precursor on-resin, deprotection of the functionalities involved in the lactam ring formation is performed, followed by regio-selective cyclization by amide bond formation, and finally by the resin-cleavage/deprotection step as outlined in Scheme 16. In Table 8, examples of syntheses of such cyclic peptides are listed with the relevant information regarding protection scheme, resin anchor, and mode of cyclization. 

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