<p>In the past decade, asymmetric catalysis has undergone significant advances, driven by the development of chiral phosphoric acids, transition metal complexes, and photoredox catalytic systems. Among these, asymmetric multicomponent reactions (AMCRs) have emerged as powerful tools for the rapid and selective construction of structurally complex molecules. This research highlights recent progress (2019–2025) in AMCRs from the perspectives of these three key catalytic platforms, emphasizing their distinct and cooperative roles in enabling enantioselective bond formation. Particular emphasis is placed on AMCRs catalyzed by chiral phosphoric acids, photoredox systems, and Lewis acids and bases, alongside representative transition metal-catalyzed AMCRs. These are discussed as discrete yet interconnected catalytic manifolds, providing a balanced and comprehensive overview of the field. Mechanistic features, including catalyst interplay, activation modes, and stereocontrol elements, are critically analyzed to establish a unified understanding of reactivity and selectivity. By focusing on these well-defined catalytic domains, this manuscript delineates the fundamental principles that underpin modern AMCR design and highlights emerging strategies that integrate light-driven processes with chiral induction. Collectively, these advances underscore the evolution of asymmetric catalysis into a cohesive and versatile platform for the efficient synthesis of functionally and structurally sophisticated molecules.</p>

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Synergistic Catalysis: Integrating Acids, Metals, and Light in Nature-Inspired Asymmetric Multicomponent Synthesis

  • Aeyaz Ahmad Bhat,
  • Magdi E. A. Zaki,
  • Amel Gacem,
  • Sami A. Al-Hussain,
  • Sobhi M. Gomha,
  • Maha Awjan Alreshidi,
  • Jaskaran Singh,
  • Krishna Kumar Yadav,
  • Mohammad Aamir Mumtaz,
  • Meraj Ahmed,
  • Anurag Malik,
  • Atif Khurshid Wani

摘要

In the past decade, asymmetric catalysis has undergone significant advances, driven by the development of chiral phosphoric acids, transition metal complexes, and photoredox catalytic systems. Among these, asymmetric multicomponent reactions (AMCRs) have emerged as powerful tools for the rapid and selective construction of structurally complex molecules. This research highlights recent progress (2019–2025) in AMCRs from the perspectives of these three key catalytic platforms, emphasizing their distinct and cooperative roles in enabling enantioselective bond formation. Particular emphasis is placed on AMCRs catalyzed by chiral phosphoric acids, photoredox systems, and Lewis acids and bases, alongside representative transition metal-catalyzed AMCRs. These are discussed as discrete yet interconnected catalytic manifolds, providing a balanced and comprehensive overview of the field. Mechanistic features, including catalyst interplay, activation modes, and stereocontrol elements, are critically analyzed to establish a unified understanding of reactivity and selectivity. By focusing on these well-defined catalytic domains, this manuscript delineates the fundamental principles that underpin modern AMCR design and highlights emerging strategies that integrate light-driven processes with chiral induction. Collectively, these advances underscore the evolution of asymmetric catalysis into a cohesive and versatile platform for the efficient synthesis of functionally and structurally sophisticated molecules.