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Spiro Compounds


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optimization. This contrasts with some scaffolds that have been at the center of drug discovery over the last decades. Those include the typical poly(hetero)aromatic structures which result from linking of multiple two‐dimensional units, and provide limited scope for targeting the three dimensions. As a result, the 3D character of spirocycles and greatly extended range of accessible vectorizations are regarded as powerful ways to “escape from flatland” [26, 27] through the bioisosteric replacement of “flat”, sp2‐rich scaffolds found in historical fragment and lead screening libraries.

Schematic illustration of a chemical reaction depicting the comparison of substituted biaryl and spiro[3,4]octane scaffolds. Schematic illustration of the chemical structure of examples of saturated spirocyclic ring systems frequently encountered in drug discovery.

      The constrained and directional exit vectors projected from “spiro” scaffolds allow fine‐tuning the relative orientations of functional groups within bioactive molecules in order to achieve optimal molecular interaction with a target receptor. Such rigidity can also be exploited for the bioisosteric replacement and conformational restriction of flexible moieties in biomolecules, hence reducing detrimental entropic penalties for binding [28]. Spirocycles have also been used to modulate physicochemical properties and pharmacokinetics of biomolecules, including aqueous solubility and metabolic stability [26, 27, 29]. A number of reports have also highlighted that a high sp2/aromatic content is generally detrimental to the physicochemical properties of drug candidates [26, 27, 30, 31].

Schematic illustration of the chemical structure of examples of lead optimization employing spirocycles.

      Sources: Based on Zheng and Tice [32]; Zheng et al. [33].