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For the quality assurance of substances for pharmaceutical use, a variety of analytical techniques are available to address specific analytical problems. In this field of application, liquid chromatography (LC) stands out as the gold standard in the pharmaceutical industry. Various detectors can be employed, which are e.g. based on UV/Vis spectroscopy for the examination of molecules with a chromophore, or mass spectrometry (MS) for structural elucidation of analytes. For the separation of enantiomers, the use of capillary electrophoresis (CE) may be more favorable due to the high separation efficiency and easy-to-use and comparatively inexpensive chiral selectors, in contrast to chiral columns for LC, which are usually very expensive and limited to a restricted number of analytes. For structure elucidation in impurity profiling, one- and multidimensional 1H NMR spectroscopy is a valuable tool as long as the analyte molecule has got nuclei that can be detected, which applies for the magnitude of organic pharmaceutical substances.
For the evaluation of the amount of mineral oil aromatic hydrocarbons (MOAH) in various paraffin samples from different suppliers, a straightforward method based on 1H NMR spectroscopy was elaborated. The MOAH/MOSH ratio was used to indicate the amount of MOAH of paraffins and to evaluate the extent of refining. In addition, a representative paraffin sample was measured without sample solvent at high temperatures (about 340 K) to avoid the interfering residual solvent signals in the spectral regions of interest. The results of both methods were in good accordance.
Moreover, the 1H NMR results were complemented with the UV measurements from the purity testing of paraffins according to the DAB 8. Correlations of the NMR and UV spectroscopic data indicated a linear relationship of both methods for the determination of MOAH in paraffins.
Finally, the 1H NMR data was evaluated by principal component analysis (PCA) to explore differences within the paraffin samples and the spectral regions in the 1H NMR spectrum which are responsible for the formation of groups. It could be found that most variation is due to the MOSH of the paraffins. The PCA model was capable of differentiating between soft, liquid and solid paraffins on the one hand and between natural and synthetic liquid paraffins on the other hand.
The impurity profiling of L-ascorbic acid 2-phosphate magnesium (A2PMg) was performed by means of one- and two-dimensional NMR spectroscopy. Several ethylated impurities could be detected, which were likely to be formed during synthesis of A2PMg. The structures of two of the ethylated impurities were identified as ascorbic acid 2-phosphate ethyl ester and ethanol, (residual solvent from synthesis). NMR spectroscopic studies of the fractions obtained from preparative HPLC of A2PMg revealed two additional impurities, which were identified as phosphorylated derivatives of ascorbic acid, ascorbic acid 3,5-phosphate and ascorbic acid 5-phosphate.
Solid state mechanochemistry as an alternative approach for stress testing was applied on the drug substances S-Ibuprofen (Ibu) and Clopidogrel (CLP) using a ball mill, in order to study their degradation profile:
First, the isomerization of S-Ibu was investigated, which was stressed in the solid state applying several milling frequencies and durations under basic, acidic and neutral conditions. For the separation of Ibu enantiomers, a chiral CE method was developed and validated according to ICH Q2(R1). It was found that S-Ibu is overall very stable to isomerization; it shows minor conversion into the R-enantiomer under basic environment applying long milling times and high frequencies.
Last, the degradation profile of clopidogrel hydrogen sulfate (CLP) was investigated, which was stressed in the solid state under various oxidative conditions. An already existing HPLC-UV method was adjusted to sufficiently separate the degradation products, which were characterized by means of UV and MS/(MS) detection. Most of the degradation products identified were already reported to result from conventional CLP stress tests. The degradation profile of CLP was mainly influenced by the material of the milling jar and the type of catalyst used.
In this thesis, a new approach of a qNMR method has been investigated to demonstrate the reliability and importance of this method as an alternative solution for analyzing oil quality parameters, especially in RFO, which has particular characteristics (red color). This study also includes the chemometric evaluation of spectral data for authentication, visual grouping, and prediction of RFO quality based on the degree of unsaturation, FFA value, and unsaturated fatty acid content.
The analytical measurement procedure of NMR spectroscopy begins with optimization of the analytical acquisition parameters, including effect of solvent, effect of sample concentration, selection of appropriate internal standards, determination of T1, and method validation. Furthermore, the results of the method development were interpreted to RFO samples evaluation, which began with determining the assignment of signal spectra for the determination of AV, SV, EV, and IV simultaneously with: the hydrolysis approach and standard addition of palmitic acid.
Bone Morphogenetic Proteins (BMPs) are secreted protein hormones that act as morphogens and exert essential roles during embryonic development of tissues and organs. Signaling by BMPs occurs via hetero-oligomerization of two types of serine/threonine kinase transmembrane receptors. Due to the small number of available receptors for a large number of BMP ligands ligand-receptor promiscuity presents an evident problem requiring additional regulatory mechanisms for ligand-specific signaling. Such additional regulation is achieved through a plethora of extracellular antagonists, among them members of the Chordin superfamily, that modulate BMP signaling activity by binding. The key-element in Chordin-related antagonists for interacting with BMPs is the von Willebrand type C (VWC) module, which is a small domain of about 50 to 60 residues occurring in many different proteins. Although a structure of the VWC domain of the Chordin-member Crossveinless 2 (CV2) bound to BMP-2 has been determined by X-ray crystallography, the molecular mechanism by which the VWC domain binds BMPs has remained unclear. Here we present the NMR structure of the Danio rerio CV2 VWC1 domain in its unbound state showing that the key features for high affinity binding to BMP-2 is a pre-oriented peptide loop.
A series of 22 new bis(phosphine), bis(carbene) and bis(isonitrile) tetrahalodiborane adducts has been synthesized, either by direct adduct formation with highly sensitive B2X4 precursors (X = Cl, Br, I) or by ligand exchange at stable B2X4(SMe2)2 precursors (X = Cl, Br) with labile dimethylsulfide ligands. The isolated compounds have been fully characterized using NMR spectroscopic, (C,H,N)- elemental and, for 20 of these compounds, X-ray crystallographic analysis, revealing an unexpected variation in the bonding motifs. Besides the classical B2X4L2 diborane(6) adducts, some of the more sterically demanding carbene ligands induce a halide displacement leading to the first halide-bridged monocationic diboron species, [B2X3L2]A (A = BCl4, Br, I). Furthermore, low-temperature 1:1 reactions of B2Cl4 with sterically demanding N-heterocyclic carbenes led to the formation of kinetically unstable mono-adducts, one of which was structurally characterized. A comparison of the NMR and structural data of new and literature-known bis-adducts shows several trends pertaining to the nature of the halides and the stereoelectronic properties of the Lewis bases employed.
The absence of fluorine from most biomolecules renders it an excellent probe for NMR spectroscopy to monitor inhibitor–protein interactions. However, predicting the binding mode of a fluorinated ligand from a chemical shift (or vice versa) has been challenging due to the high electron density of the fluorine atom. Nonetheless, reliable \(^{19}\)F chemical‐shift predictions to deduce ligand‐binding modes hold great potential for in silico drug design. Herein, we present a systematic QM/MM study to predict the \(^{19}\)F NMR chemical shifts of a covalently bound fluorinated inhibitor to the essential oxidoreductase tryparedoxin (Tpx) from African trypanosomes, the causative agent of African sleeping sickness. We include many protein–inhibitor conformations as well as monomeric and dimeric inhibitor–protein complexes, thus rendering it the largest computational study on chemical shifts of \(^{19}\)F nuclei in a biological context to date. Our predicted shifts agree well with those obtained experimentally and pave the way for future work in this area.
We present the rapid biophysical characterization of six previously reported putative G‐quadruplex‐forming RNAs from the 5′‐untranslated region (5′‐UTR) of silvestrol‐sensitive transcripts for investigation of their secondary structures. By NMR and CD spectroscopic analysis, we found that only a single sequence—[AGG]\(_{2}\)[CGG]\(_{2}\)C—folds into a single well‐defined G‐quadruplex structure. Sequences with longer poly‐G strands form unspecific aggregates, whereas CGG‐repeat‐containing sequences exhibit a temperature‐dependent equilibrium between a hairpin and a G‐quadruplex structure. The applied experimental strategy is fast and provides robust readout for G‐quadruplex‐forming capacities of RNA oligomers.