What question did this study set out to answer?

The goal is to synthesize Niraparib using a novel chemoenzymatic dearomatization process.

March 18, 2026Open Access

Synthesis of Niraparib via Chemoenzymatic Dearomatization of Substituted Pyridines

Key Points

The goal is to synthesize Niraparib using a novel chemoenzymatic dearomatization process.
Reduction of pyridinium using sodium borohydride
Application of AmOx/EneIRED cascade
Screening various tetrahydropyridines for substrate efficacy
Final N-dealkylation step to isolate Niraparib.
N-ethyl 3-(4′-aminophenyl)-1,2,5,6-tetrahydropyridine selected as the optimal substrate
Synthesis yielded (S)-3-(4′-aminophenyl)piperidine at 66% yield
Achieved 93% enantiomeric excess on a 50 mL scale.

Abstract

A chemoenzymatic dearomatization strategy, involving initial reduction of a pyridinium with sodium borohydride followed by a biocatalytic amine oxidase/ene imine reductase (AmOx/EneIRED) cascade, has enabled the synthesis of the PARP inhibitor Niraparib. A variety of tetrahydropyridines with different N ‐alkyl and 3‐ (4′‐aryl) substituents were screened, leading to the selection of N ‐ethyl 3‐ (4′‐aminophenyl) ‐1, 2, 5, 6‐tetrahydropyridine as the preferred substrate for the synthesis of Niraparib. Using AmOx 6‐HDNO E350LE352D and EneIRED361 yielded the (S) ‐3‐ (4′‐aminophenyl) piperidine product in 66% yield and 93% enantiomeric excesses (ee) on 50 mL scale. Subsequent modifications and a final N ‐dealkylation step allowed for the isolation of Niraparib.

Synthesis of Niraparib via Chemoenzymatic Dearomatization of Substituted Pyridines

Key Points

Abstract

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