Abstract

Detailed solvent and temperature effects on the experimental 1H-NMR chemical shifts of the natural products chrysophanol (1), emodin (2), and physcion (3) are reported for the investigation of hydrogen bonding, solvation and conformation effects in solution. Very small chemical shift of │Δδ│ < 0.3 ppm and temperature coefficients │Δδ/ΔΤ│ ≤ 2.1 ppb/K were observed in DMSO-d6, acetone-d6 and CDCl3 for the C(1)–OH and C(8)–OH groups which demonstrate that they are involved in a strong intramolecular hydrogen bond. On the contrary, large chemical shift differences of 5.23 ppm at 298 K and Δδ/ΔΤ values in the range of −5.3 to −19.1 ppb/K between DMSO-d6 and CDCl3 were observed for the C(3)–OH group which demonstrate that the solvation state of the hydroxyl proton is a key factor in determining the value of the chemical shift. DFT calculated 1H-NMR chemical shifts, using various functionals and basis sets, the conductor-like polarizable continuum model, and discrete solute-solvent hydrogen bond interactions, were found to be in very good agreement with the experimental 1H-NMR chemical shifts even with computationally less demanding level of theory. The 1H-NMR chemical shifts of the OH groups which participate in intramolecular hydrogen bond are dependent on the conformational state of substituents and, thus, can be used as molecular sensors in conformational analysis. When the X-ray structures of chrysophanol (1), emodin (2), and physcion (3) were used as input geometries, the DFT-calculated 1H-NMR chemical shifts were shown to strongly deviate from the experimental chemical shifts and no functional dependence could be obtained. Comparison of the most important intramolecular data of the DFT calculated and the X-ray structures demonstrate significant differences for distances involving hydrogen atoms, most notably the intramolecular hydrogen bond O–H and C–H bond lengths which deviate by 0.152 tο 0.132 Å and 0.133 to 0.100 Å, respectively, in the two structural methods. Further differences were observed in the conformation of –OH, –CH3, and –OCH3 substituents.

Highlights

  • The single-crystal X-ray diffraction has been the most widely used method for structural analysis in the solid state [1,2,3]

  • 1 H-NMR spectra of chrysophanol (1), emodin (2), and physcion (3) show extremely deshielded and sharp peaks which are attributed to the C(1)–OH and C(8)–OH protons (Table 1) which participate in a Molecules 2019, 24, 2290 strong intramolecular hydrogen bond with the O=C(9) carbonyl oxygen atom

  • Inclusion of discrete solvent molecules induces a minor effect on the computed 1 H-NMR chemical shifts of the intramolecular hydrogen bond, but shows a significant effect on the 1 H-NMR chemical shifts of the C(3)–OH which participates in intermolecular solute-solvent hydrogen bond; this results in excellent agreement with the experimental 1 H-NMR chemical shifts

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Summary

Introduction

The single-crystal X-ray diffraction has been the most widely used method for structural analysis in the solid state [1,2,3]. It may be argued that the structural data bears some resemblance to the solution structure, since the crystals frequently contain significant. It may be argued that the structural data bears some resemblance to the solution structure, since the crystals frequently contain significant numbers of solvent molecules, usually water [4,5]. Incorporation of solvent molecules can be, in most cases, very limited. Extrapolation, of the the incorporation of solvent molecules can be, in most cases, very limited. Extrapolation, molecular conformation in the crystal to possible conformations in solution, is very problematic since of the molecular conformation in the crystal to possible conformations in solution, is very problematic crystal packing interactions can stabilize conformers that are rarely encountered in solution

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Conclusion

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