Efficient solid-phase synthesis of peptides with tripodal side-chain bridges and optimization of the solvent conditions for solid-phase cyclizations

Unnatural amino amides and peptide amides can be synthesized, using solid-phase chemistry, from glycine attached directly (or through an intervening peptide sequence) to a Rink resin. The glycine is converted to an activated benzophenone imine derivative, followed by C-alkylation and hydrolysis. Thi

## Abstract Many naturally occurring peptide acids, e.g., somatostatins, conotoxins, and defensins, contain a cysteine residue at the C‐terminus. Furthermore, installation of C‐terminal cysteine onto epitopic peptide sequences as a preliminary to conjugating such structures to carrier proteins is a

AbstractÐA 1,4-butanediol dimethacrylate cross-linked polystyrene (PS±BDODMA) support was prepared by aqueous suspension polymerization. The C-terminal amino acid incorporation, N a -Fmoc and Boc-deprotection, acylation reactions and the removal of the target peptide from the support were optimized.

## Abstract magnified image To increase the flexibility for the insertion of highly sensitive and robust [Ru^II^(bathophenanthroline)] complexes into peptides, we have evaluated three different solid‐phase strategies (bathophenanthroline=4,7‐diphenyl‐1,10‐phenanthroline). Among these, insertion of

A solid phase approach has been used to synthesize a large branched disulphide peptide from IgG Fc, Ac- This peptide combines the lower hinge region of IgG and a proximal i-hairpin loop, both implicated in binding to FckRI. Solid phase Tl(tfa) 3 cyclization of the linear branched peptide resulted i