Ranolazine Quantification in Human Plasma: A QbD-Guided LC-MS Method Development and Validation

Abstract

The present research outlines a comprehensive and systematic approach for the development and validation of a bioanalytical Liquid chromatography–mass spectrometry (LC-MS) method to quantify ranolazine in human plasma. The study employs principles of quality by design (QbD) to enhance method robustness, precision, and accuracy. The primary goals of this research were to create a reliable LC-MS method for the accurate quantification of ranolazine in human plasma and to validate this approach in accordance with established standards set by regulatory bodies. A secondary objective was to explore the application of QbD principles to optimize method performance. The study resulted in the successful development of an LC-MS method that exhibits exceptional specificity, sensitivity, accuracy, and precision in the quantification of ranolazine in human plasma. Specificity tests revealed no interference from endogenous plasma components. The method demonstrated good sensitivity with limit of quantitation (LoQ) of 5 ng/mL and limit of detection (LoD) of 2 ng/mL. Accuracy, as assessed through recovery studies, showed mean recoveries of 98, 99, and 101% for three different spiked concentrations. Precision, expressed as RSD, was below 5% for both intra-day and inter-day analyses. Linearity studies resulted in a calibration curve with an R² value of 0.9998. By employing QbD principles, the method demonstrated improved robustness, thus minimizing the impact of variability during sample analysis. Robustness experiments revealed minimal effects on precision and accuracy when varying critical parameters. This research not only presents a reliable LC-MS method for ranolazine quantification but also underscores the importance of incorporating QbD principles in bioanalytical method development. The validated method holds significant implications for clinical research, pharmacokinetic studies, and therapeutic drug monitoring. By enhancing the accuracy and robustness of ranolazine quantification, this method contributes to the advancement of pharmaceutical and clinical research, ultimately benefiting patient care and treatment outcomes.