Kinetic Degradation Study of Dapagliflozin Coupled with UHPLC Separation in the Presence of Major Degradation Product and Metformin

Metabolism and Chemical Degradation of New Antidiabetic Drugs: A Review of Analytical Approaches for Analysis of Glutides and Gliflozins

The drug metabolism and drug degradation pathways may overlap, resulting in the formation of similar constituents. Therefore, the metabolism data can be helpful for deriving safe levels of degradation impurities and improving the quality of respective pharmaceutical products. The present article contains considerations on possible links between metabolic and degradation pathways for new antidiabetic drugs such as glutides, gliflozins, and gliptins. Special attention was paid to their reported metabolites and identified degradation products. At the same time, many interesting analytical approaches to conducting metabolism as well as degradation experiments were mentioned, including chromatographic methods and radioactive labeling of the drugs. The review addresses the analytical approaches elaborated for examining the metabolism and degradation pathways of glutides, i.e., glucagon like peptide 1 (GLP-1) receptor agonists, and gliflozins, i.e., sodium glucose co-transporter 2 (SGLT2) inhibitors. The problems associated with the chromatographic analysis of the peptide compounds (glutides) and the polar drugs (gliflozins) were addressed. Furthermore, issues related to in vitro experiments and the use of stable isotopes were discussed.

Determination of the Chemical Stability of Dapagliflozin by LC/DAD and MS/MS Methods

A simple and fast stability-indicating liquid chromatographic method with diode array detection (DAD) was developed and validated for the determination of dapagliflozin (DAPA) in bulk and tablets, in the presence of its major degradation products (DP). The drug was subjected to hydrolytic, oxidative, photolytic, thermal and humidity/thermal stress conditions, showing significant degradation under humidity/thermal with the formation of two DP, which were preliminarily identified by liquid chromatography with diode array detector coupled with electrospray ionization-tandem mass spectrometry (HPLC-DAD-ESI-MS/MS). Chromatographic separation of dapagliflozin and its DP was achieved with a core-shell RP-18 column, using acetonitrile and water as mobile phase in isocratic elution mode. The described method was linear over a range of 50-150 μg/mL. For precision, the relative standard deviation (RSD) was <1.3%, the recovery was 99.64-100.11%, and the assay demonstrated adequate selectivity. The degradation kinetics of dapagliflozin was evaluated corresponding to first-order under thermal and humidity/thermal stress conditions. Dapagliflozin was well resolved from its drug products showing the power of stability-indicating of the method. The results showed that the proposed method was found to be suitable for routine analysis, quantitative determination and the stability study of dapagliflozin in pharmaceutical samples.

Fluorescence spectroscopy for determination of dapagliflozin in pure form and its tablets formulation; Application to content uniformity testing

A new, valid method was developed for quantitative spectrofluorimetric analysis of dapagliflozin (DGF) in its pure form and its commercially available tablets (Farxiga®). The proposed analytical method based on measurement of fluorescence intensity for DGF at 303 nm after excitation at 278 nm. Various experimental parameters influencing the fluorescence of DGF were examined to produce the optimal conditions. DGF was successively assayed in concentration range of (100-1000 ng mL^-1) with lower detection limit (LOD) of 26.49 and quantitation limit (LOQ) was 79.48 ng mL^-1. The suggested method was validated according to ICH guidelines for the estimation of DGF in its pure form and its new dosage form with percent recovery of 100.43 ± 1.15. The proposed method was adapted to examine DGF in content uniformity testing according to United States Pharmacopeia guidelines. This method can be used in routine analysis of DGF in quality control lab.

Pharmaceutical Analytical Profile for Novel SGL-2 Inhibitor: Dapagliflozin

Dapagliflozin (DPG) is a novel drug from class of sodium glucose co-transporter 2 (SGL-2) inhibitors which has been evolved as profound treatment option for the type-2diabetes mellitus (T2DM). Considering the severity of the disease the drug is of crucial significance for the therapy and associated research. As a pharmaceutical dosage form DPG has immense importance as an individual drug and with other antidiabetic drugs as combinations. The drugs existing in combination with DPG are Metformin (MET) and Saxagliptin (SXG). The existence of the Dapagliflozin in combinations further created more interest in reviewing its pharmaceutical, analytical and bio-analytical profile. Such estimations are always in need of precise pharmacological and physicochemical information; hence authors have presented it beforehand. Authors hereby wish to present an essential update pertaining to emergence of gliflozins and DPG. The article further presents a simultaneous and comparative assessment of the analytical investigations published in literature for pharmaceutical estimation to assist future analysis. The thorough literature searches revealed fifty three research papers in total till date. A comprehensive presentation of typical; hyphenated and unique methods used for analysis are outlined effectively. The percentile utilization of analytical approaches since appearance of first publication in 2010 is investigated to report trend in determination. The present review explores the pharmaceutical estimation of DPG to scientifically potentiate analytical research and therapeutic future of DPG as a novel SGL-2 Inhibitor antidiabetic.

Second-derivative synchronous spectrofluorimetric assay of dapagliflozin: Application to stability study and pharmaceutical preparation

A highly accurate, simple and sensitive spectrofluorimetric analytical method for dapagliflozin (DGF) quantitation was developed. The proposed method was successively applied to DGF analysis in both its pure and pharmaceutical dosage forms. This method was developed to investigate DGF stability in its degradation products, as laid out in International Council for Harmonisation (ICH) rules. Kinetics of alkaline degradation of DGF was also calculated. The half-life time (t_1/2 ) of the reaction was 75.32 min. An alkaline degradation pathway was described. The present study involved measurement of the second-derivative synchronous fluorescence intensity of DGF at Δλ = 30 nm. Peak amplitude was measured at 322 nm. Linear range of the calibration curve was 0.1-1.0 μg ml^-1 . Lower detection and quantitation limits were 0.023 and 0.071 μg ml^-1 , respectively, and indicated good sensitivity of the proposed method. Mean per cent recovery was 99.78 ± 1.78%. The proposed analytical approach was successfully applied to DGF in the quality control laboratory and would be suitable as a stability-indicating assay.