Eco-friendly estimation of isosorbide dinitrate and hydralazine hydrochloride using Green Analytical Quality by Design-based UPLC Method

Analysing isosorbide dinitrate and hydralazine by using an eco-friendly method is an initial stepping stone towards environmentally benign method development, and its combination with the AQbD makes it the method to use for ages without revalidation.

PART II: OPTIMIZATION OF ISOSORBIDE DINITRATE SUSTAINED RELEASE LAYER IN ANTIHYPERTENSIVE BILAYER TABLET

Objective: Aim of the present study was the optimization of the sustained release (SR) layer of isosorbide dinitrate (ISDN) 40 mg and compressed with the immediate-release (IR) layer of hydralazine hydrochloride (HHC) 25 mg to decrease the dosing frequency and development of a novel b. i. d dosage form. Methods: Drug excipients compatibility study was carried out by FT-IR and a preliminary study was conducted for screening of polymer. The amount of HPMC K100M (X1) and the amount of Polyoxtm WSR303 (X2) were chosen as independent variables in 32full factorial designs. While % cumulative drug releases at 1 h (Q1) (Y1), % cumulative drug release at 2 h (Q2) (Y2), % cumulative drug release at 4 h (Q4) (Y3) and % cumulative drug release at 6 h (Q6) (Y4), were taken as dependent variables and statistically evaluation by using sigma plot 13.0. In the present study, according to the U. S. P. 2007 the following constraints were used for the selection of an optimized batch: Q1=15% to 30%, Q2=50% to 70%, Q4=65% to 85% and Q6>75%. To validate the evolved mathematical models, a checkpoint batch was selected from its desirability value. Results: FT-IR spectra show that the drug and excipients were compatible with each other. The calculated F values found for Q1, Q2, Q4, and Q6 were 084.583, 038.188, 057.719, and 118.396, respectively. All Calculated F values are greater than the tabulated value for all dependent variables. Prepared checkpoint batch selected from its desirability value 1 and it gives a 93.40±1.29 % drug release within 6 h. Conclusion: This bilayer formulation of anti-hypertensive drugs decreases the dosing frequency of HHC and ISDN.

PART I: OPTIMIZATION OF HYDRALAZINE HYDROCHLORIDE IMMEDIATE RELEASE LAYER IN ANTIHYPERTENSIVE BILAYER TABLET

Objective: Aim of the present study was the optimization of the immediate release (IR) layer containing hydralazine hydrochloride (HHC) 25 mg and compressed with a sustained-release (SR) layer of isosorbide dinitrate (ISDN) 40 mg to decrease the dosing frequency. Methods: In this study, Drug-excipients compatibility study was carried out by FT-IR and a preliminary trial was conducted for screening of super disintegrating agents. The amount of sodium starch glycolate (SSG) (X1) and the amount of ac-di-sol® (X2) was chosen as independent variables in 32 full factorial design while wetting time (WT) (Y1), disintegration time (DT) (Y2) and In vitro drug release at 15 min (Q15) (Y3) were taken as dependent variables. Multiple linear regression analysis, ANOVA, and graphical representation of the influence of factor by 3D plots were performed by using sigma plot 13.0. In the present study, the following constraints were used for the selection of an optimized batch: WT<16 s, DT<25 s, and Q15>90%. To validate the evolved mathematical models, a checkpoint batch was selected from its desirability value. Results: FT-IR spectra show that the drug and excipients were compatible with each other. The calculated F values found for WT, DT, and Q15 were 045.559, 077.100 and 278.760, respectively. All Calculated F values are greater than tabulated values for all dependent variables. Prepared checkpoint was selected from its desirability value 0.935 and it gives a 100% drug release within 30 min. Conclusion: These results confirm that the prepared HHC 25 mg IR layer is used for rapid control of hypertension.