Structure and Conformation of Novel BODIPY Ugi Adducts

Overview

Journal ChemistryOpen

Specialty Chemistry

Date 2022 Oct 26

PMID 36284210

Authors

Ismael Javier Arroyo-Cordoba

Gonzalo Gamboa-Velazquez

Claudia Gabriela Avila-Ortiz

Marco A Leyva-Ramirez

Maria Teresa Cortez-Picasso

Marco A Garcia-Revilla

Diana E Ramirez-Ornelas

Eduardo Pena-Cabrera

Eusebio Juaristi

Affiliations

Soon will be listed here.

Abstract

Two novel BODIPY-Ugi (boron dipyrromethene) adducts exhibit peculiar room temperature (T=20 °C) H-1 NMR spectra in that several protons located at the aromatic aniline-type ring are lost in the baseline. This observation revealed the existence of a dynamic conformational process where rotation around the C-N bond is hindered. Variable-temperature H-1 and C-13 NMR spectroscopic analysis confirmed this conclusion; that is, low-temperature spectra show distinct signals for all four aromatic protons below coalescence, whereas average signals are recorded above coalescence (T=+120 °C). Particularly interesting was the rather large difference in chemical shifts for the ortho protons below coalescence, Δδ=1.45 ppm, which was explained based on DFT computational analysis. Indeed, the calculated lowest-energy gas-phase conformation of the BODIPY Ugi adducts locates one half of the aniline-type ring in the shielding anisotropic cone of the bridge phenyl ring in the BODIPY segment. This is in contrast to the solid-state conformation established by X-ray diffraction analysis that shows a nearly parallel arrangement of the aromatic rings, probably induced by crystal packing forces.

Citing Articles

Structure and Conformation of Novel BODIPY Ugi Adducts.

Arroyo-Cordoba I, Gamboa-Velazquez G, Avila-Ortiz C, Leyva-Ramirez M, Cortez-Picasso M, Garcia-Revilla M ChemistryOpen. 2022; 11(10):e202200197.

PMID: 36284210 PMC: 9596608. DOI: 10.1002/open.202200197.

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