Chiral amines are important building blocks in 40–45 % of small molecule pharmaceuticals, as well as in numerous industrially important fine chemicals and agrochemicals. Furthermore, environmental regulations and the increasing demand for enantiopure compounds as high-value products for different sectors necessitate the integration of traditional chemical synthetic methods with greener (bio)catalytic approaches. Since nitrogen-containing heterocycles represent a privileged structure in many APIs, in this work we focused our attention on the asymmetric synthesis of enantiopure piperidines as high-value scaffolds for the synthesis of different alkaloids. A pyridoxal 5'-phosphate (PLP)-dependent transaminase (ATA-117) was selected and immobilized to perform a stereoselective transamination, followed by a spontaneous intramolecular aza-Michael reaction (IMAMR), to synthesize natural (-)-pinidinone. First, two chemical steps were performed in batch to prepare the desired substrate 1, namely an oxidation reaction followed by a Wittig olefination using commercially available ylides. Then, after expressing and purifying the enzyme, various trials were conducted to immobilize the (R)-selective biocatalyst. Eupergit®C was chosen as the carrier for the covalent immobilization of ATA-117 to enhance its operational stability and reusability. The reaction was then optimized in a continuous flow system evaluating substrate concentration, isopropylamine equivalents, reaction temperature, residence time, type and amount of cosolvent. The protocol was extended to different substrates to isolate variuos 2,6-disubstituted chiral piperidines (compounds 7-10).
Chemo-enzymatic flow synthesis of enantiopure piperidines / S. Vicinanza, S. Patti, M. Pirotta, I. Magrini Alunno, F. Annunziata, R. Gandolfi, C. Borsari, I. Bassanini, D. Monti, E. Elisa Ferrandi, L. Tamborini. 14. ISBOC International Symposium on BioOrganic Chemistry : June, 21st - 24th Milano 2026.
Chemo-enzymatic flow synthesis of enantiopure piperidines
S. VicinanzaPrimo
;S. PattiSecondo
;F. Annunziata;R. Gandolfi;C. Borsari;I. Bassanini;L. TamboriniUltimo
2026
Abstract
Chiral amines are important building blocks in 40–45 % of small molecule pharmaceuticals, as well as in numerous industrially important fine chemicals and agrochemicals. Furthermore, environmental regulations and the increasing demand for enantiopure compounds as high-value products for different sectors necessitate the integration of traditional chemical synthetic methods with greener (bio)catalytic approaches. Since nitrogen-containing heterocycles represent a privileged structure in many APIs, in this work we focused our attention on the asymmetric synthesis of enantiopure piperidines as high-value scaffolds for the synthesis of different alkaloids. A pyridoxal 5'-phosphate (PLP)-dependent transaminase (ATA-117) was selected and immobilized to perform a stereoselective transamination, followed by a spontaneous intramolecular aza-Michael reaction (IMAMR), to synthesize natural (-)-pinidinone. First, two chemical steps were performed in batch to prepare the desired substrate 1, namely an oxidation reaction followed by a Wittig olefination using commercially available ylides. Then, after expressing and purifying the enzyme, various trials were conducted to immobilize the (R)-selective biocatalyst. Eupergit®C was chosen as the carrier for the covalent immobilization of ATA-117 to enhance its operational stability and reusability. The reaction was then optimized in a continuous flow system evaluating substrate concentration, isopropylamine equivalents, reaction temperature, residence time, type and amount of cosolvent. The protocol was extended to different substrates to isolate variuos 2,6-disubstituted chiral piperidines (compounds 7-10).| File | Dimensione | Formato | |
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