Validation of a Generic Quantitative 1H NMR Method for Natural Products Analysis

IntroductionNuclear magnetic resonance (NMR) spectroscopy is increasingly employed in the quantitative analysis and quality control (QC) of natural products (NP) including botanical dietary supplements (BDS). The establishment of QC protocols based on quantitative H-1 NMR (qHNMR) requires method validation. ObjectiveDevelop and validate a generic qHNMR method. Optimize acquisition and processing parameters, with specific attention to the requirements for the analysis of complex NP samples, including botanicals and purity assessment of NP isolates. MethodsIn order to establish the validated qHNMR method, samples containing two highly pure reference materials were used. The influence of acquisition and processing parameters on the method validation was examined, and general aspects of method validation of qHNMR methods discussed. Subsequently, the method established was applied to the analysis of two NP samples: a purified reference compound and a crude mixture. ResultsThe accuracy and precision of qHNMR using internal or external calibration were compared, using a validated method suitable for complex samples. The impact of post-acquisition processing on method validation was examined using three software packages: TopSpin, Mnova and NUTS. The dynamic range of the qHNMR method developed was 5000:1 with a limit of detection (LOD) of better than 10 mu m. The limit of quantification (LOQ) depends on the desired level of accuracy and experiment time spent. ConclusionThis study revealed that acquisition parameters, processing parameters and processing software all contribute to qHNMR method validation. A validated method with a high dynamic range and general workflow for qHNMR analysis of NP is proposed. Copyright (c) 2013 John Wiley & Sons, Ltd. Quantitative H-1 NMR (qHNMR) is a suitable technique for quality control (QC) of natural products (NP) and botanical dietary supplements (BDS). The presented generic qHNMR protocol provides guidance for both purity assessment of NP and quantitation of marker compounds in complex BDS. Several qHNMR calibration approaches and post-acquisition processing strategies were examined with respect to their impact on method validation. The study revealed that acquisition, processing parameters, and processing software are equally important for building validating qHNMR methods.