Spiro Compounds. Группа авторов

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       Alberto Vega-Peñaloza1, Suva Paria1, Luca Dell’Amico1, and Xavier Companyó1, 2

       1 Department of Chemical Sciences, University of Padova, Padova, Italy

       2 Section of Organic Chemistry, Department of Inorganic and Organic Chemistry, University of Barcelona, Barcelona, Spain

      Spiro compounds are organic molecules that present a twisted structure where two perpendicular cycles are linked together by a single tetrasubstituted stereogenic center, known as the spiro center. Since its definition in early 1900 [1], spiro compounds have attracted the attention of the scientific community owing to their unique features. The spiranic motif is present in several natural and non‐natural compounds possessing a wide range of biological activities [2]. As a result, the introduction of spiranic scaffolds in drug candidates is gaining interest in modern drug discovery programs [3]. Their well‐defined 3D structure along with the enhanced conformational rigidity offer distinctive features for new drug candidates, such as enhanced drug–target recognition or improved physicochemical properties [3]. Hence, the increasing demand of new compounds derived from privileged scaffolds in chemistry, biology, and medicinal research has fueled the development of novel methodologies toward the synthesis of spiro compounds [4]. In addition, the construction of spiro centers in a catalytic, stereocontrolled manner represents by itself a formidable synthetic challenge. In this light, methodologies based on the catalysis by organometallic complexes offer a robust approach for the discovery of novel cycloaddition reactions [5]. The versatility of the diverse transition metals, such as Cu, Rh, or Ni, together with the development of new chiral ligands make the use of transition‐metal catalysts a very powerful approach. Recently, the advent of organocatalysis has paved the way for unprecedented activation modes and reaction pathways [6], including cyclization, cycloaddition, and cascade transformations [7], representing a complementary and straightforward approach to construct spiro compounds in asymmetric fashion.


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