Fmoc aminotriacid

Despite numerous reports on catalytic amide bond formation (ABF), these methods have thus far had a minimal impact on the universal fluorenylmethoxycarbonyl (Fmoc)/t-Bu solid-phase peptide synthesis (SPPS) methodology. We now report a proof-of-principle Fmoc/t-Bu SPPS in which both couplings and Fmoc deprotections were catalyzed by readily available reagents in an inexpensive green solvent. Couplings were carried out with >99% stereoselectivity, employing 1.1 equiv of Fmoc amino acids (AAs), using diisopropylcarbodiimide (DIC) as a coupling agent and 1-hydroxy-1,2,3-triazole-5-carboxylic acid ethyl ester (HOCt) (TON ~ 30) as a catalyst, while Fmoc deprotections were carried out using 1,8-diazabicyclo(5.4.0)undec-7-ene (DBU) (TON ~ 7), facilitating synthesis of a model pentapeptide in 95% HPLC purity while also enabling minimization of solvent washing.

Hydrogels (HGs) are tri-dimensional materials with a non-Newtonian flow behaviour formed by networks able to encapsulate high amounts of water or other biological fluids. They can be prepared using both synthetic or natural polymers and their mechanical and functional properties may change according to the preparation method, the solvent, the pH, and to others experimental parameters. Recently, many short and ultra-short peptides have been investigated as building blocks for the formulation of biocompatible hydrogels suitable for different biomedical applications. Due to its simplicity and capability to gel in physiological conditions, Fmoc-FF dipeptide is one of the most studied peptide hydrogelators. Although its identification dates to 15 ago, its behaviour is currently studied because of the observation that the final material obtained is deeply dependent on the preparation method. To collect information about their formulation, here are reported some different strategies adopted until now for the Fmoc-FF HG preparation, noting the changes in the structural arrangement and behaviour in terms of stiffness, matrix porosity, and stability induced by the different formulation strategy on the final material.

Today, Fmoc SPPS is the method of choice for peptide synthesis. Very-high-quality Fmoc building blocks are available at low cost because of the economies of scale arising from current multiton production of therapeutic peptides by Fmoc SPPS. Many modified derivatives are commercially available as Fmoc building blocks, making synthetic access to a broad range of peptide derivatives straightforward. The number of synthetic peptides entering clinical trials has grown continuously over the last decade, and recent advances in the Fmoc SPPS technology are a response to the growing demand from medicinal chemistry and pharmacology. Improvements are being continually reported for peptide quality, synthesis time and novel synthetic targets. Topical peptide research has contributed to a continuous improvement and expansion of Fmoc SPPS applications.