Effects of Molecular Structure on H Chemical Shifts

The dependence of the principal components of the nuclear magnetic resonance (NMR) chemical shift tensor of non-hydrogen nuclei in model dipeptides is investigated. It is observed that the principal axis system of the chemical shift tensors of the carbonyl carbon and the amide nitrogen are intimately linked to the amide plane. On the other hand, there is no clear relationship between the alpha carbon chemical shift tensor and the molecular framework. However, the projection of this tensor on the C-H vector reveals interesting trends that one may use in peptide secondary structure determination. Effects of hydrogen bonding on the chemical shift tensor will also be discussed. The dependence of the chemical shift on ionic distance has also been studied in Rb halides and mixed halides. Lastly, the presence of motion can have dramatic effects on the observed NMR chemical shift tensor as illustrated by a nitrosyl meso-tetraphenyl porphinato cobalt (III) complex. 

Prediction of the NMR signals for derivatives of naphthalene was studied using statistical SCS values. F, H, and C NMR spectral data are reported for a variety of oxetane compounds containing fluorine on or near the ring. Effects of substituents on the spectra are analyzed and correlations of chemical shifts and coupling constants in terms of molecular structure are presented. A series of 2-aryl-2-hydroxy-1,1,3,3-tetramethyl-5,8-dioxaspir-o[3.4]octanes (1), 3-aryl-3-hydroxyl-2,2,4,4-tetramethylcyclobutanones (2), and... 

The use of 19F NMR for a variable temperature (VT) NMR study of fluorinated taxoids is obviously advantageous over the use of H NMR because of the wide dispersion of the l9F chemical shifts that allows fast dynamic processes to be frozen out. Accordingly, F2-paclitaxel 65 and F-docetaxel 66 were selected as probes for the study of the solution structures and dynamic behavior of paclitaxel and docetaxel, respectively, in protic and aprotic solvent systems.77 The inactive 2, 10-diacetyldocetaxel (73) was also prepared to investigate the role of the 2 -hydroxyl moiety in the conformational dynamics.89 While molecular modeling and NMR analyses (at room temperature) of 73 indicate that there is no significant conformational changes as compared to paclitaxel, the 19F NMR VT study clearly indicates that this modification exerts marked effects on the dynamic behavior of the molecule.77... 

The goal of many biomolecular NMR studies is characterization of global molecular structure. In metallo-biomolecules, and in particular, for paramagnetic species, it is sometimes preferable to use NMR to perform a more focused study of the metal ion coordination enviroiunent and the metal electronic structure. Metal sites show great variation in the effects on chemical shifts and line widths and thus often call for tailored approaches. In this section, characteristics of some of the metalloproteins metal sites most frequently studied by NMR are summarized. Examples have been selected to illustrate approaches described in this chapter such as metal substitution, use of pseudocontact shifts, RDCs, relaxation enhancement, and detection of nuclei other than H. 

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