Grover Nitika, Flanagan Keith J, Trujillo Cristina, Kingsbury Christopher J, Senge Mathias O
School of Chemistry Trinity Biomedical Sciences Institute Trinity College Dublin The University of Dublin 152-160 Pearse Street Dublin 2 Ireland.
Institute for Advanced Study (TUM-IAS) Technical University of Munich, Focus Group - Molecular and Interfacial Engineering of Organic Nanosystems Lichtenberg-Str. 2a 85748 Garching Germany.
European J Org Chem. 2021 Feb 19;2021(7):1113-1122. doi: 10.1002/ejoc.202001564. Epub 2020 Dec 22.
Bicyclo[1.1.1]pentane (BCP) is studied extensively as a bioisosteric component of drugs. Not found in nature, this molecular unit approximates the distance of a -disubstituted benzene which is replaced in medicines as a method of improving treatments. Predicting interactions of these drugs with specific active sites requires knowledge of the non-covalent interactions engaged by this subunit. Structure determinations and computational analysis (Hirshfeld analysis, 2D fingerprint plots, DFT) of seven BCP derivatives chosen to probe specific and directional interactions. X-ray analysis revealed the presence of various non-covalent interactions including I ⋅⋅⋅ I, I ⋅⋅⋅ N, N-H ⋅⋅⋅ O, C-H ⋅⋅⋅ O, and H-C ⋅⋅⋅ H-C contacts. The preference of halogen bonding (I ⋅⋅⋅ I or I ⋅⋅⋅ N) in BCP - strictly depends upon the electronic nature and angle between bridgehead substituents. The transannular distance in co-crystals and was longer as compared to monomers and . Stronger N-H ⋅⋅⋅ O and weaker C-H ⋅⋅⋅ O contacts were observed for BCP while the O ⋅⋅⋅ H interaction was a prominent contact for BCP . The presence of 3D BCP units prevented the π ⋅⋅⋅ π stacking between phenyl rings in , , and . The BCP skeleton was often rotationally averaged, indicating fewer interactions compared to bridgehead functional groups. Using DFT analysis, geometries were optimized and molecular electrostatic potentials were calculated on the BCP surfaces. These interaction profiles may be useful for designing BCP analogs of drugs.
双环[1.1.1]戊烷(BCP)作为药物的生物电子等排体成分被广泛研究。这种分子单元在自然界中不存在,它近似于α-二取代苯的距离,在药物中被取代作为改善治疗的一种方法。预测这些药物与特定活性位点的相互作用需要了解该亚基参与的非共价相互作用。对七种选择用于探究特定和定向相互作用的BCP衍生物进行了结构测定和计算分析( Hirshfeld分析、二维指纹图谱、密度泛函理论)。X射线分析揭示了各种非共价相互作用的存在,包括I∙∙∙I、I∙∙∙N、N-H∙∙∙O、C-H∙∙∙O和H-C∙∙∙H-C接触。BCP中卤素键(I∙∙∙I或I∙∙∙N)的偏好严格取决于桥头取代基之间的电子性质和角度。与单体相比,共晶体中的跨环距离更长。对于BCP观察到更强的N-H∙∙∙O和较弱的C-H∙∙∙O接触,而O∙∙∙H相互作用是BCP的主要接触。3D BCP单元的存在阻止了、和中苯环之间的π∙∙∙π堆积。BCP骨架通常进行旋转平均,表明与桥头官能团相比相互作用较少。使用密度泛函理论分析,优化了几何结构并计算了BCP表面的分子静电势。这些相互作用概况可能有助于设计药物的BCP类似物。
