Development and validation of a novel simultaneous equation and Q-absorbance ratio method for the quantitative estimation of atenolol and hydrochlorothiazide in combined tablet dosage forms: A green analytical chemistry approach
Ashok H Akabari, Divya Solanki, Sagarkumar K Patel, Palak Desai, Gamit Jainisha, Bhaveshkumar A. Patel, Birenkumar N Shah, Ketan V. Shah
Abstract
• Novel UV Spectrophotometric Method : Developed for the simultaneous quantification of Atenolol and Hydrochlorothiazide using Simultaneous Equation and Q-Absorbance Ratio methods. • Greenness Assessment : Achieved an Analytical Eco-Scale score of 95, outperforming conventional HPLC methods in environmental sustainability. • Validated with Green Tools : The method scored 0.71 on the AGREE tool, confirming its minimal use of hazardous solvents, energy, and waste generation. • Compliance with ICH Guidelines : Demonstrated high accuracy, precision, and robustness, ensuring analytical reliability. • Sustainability Highlight : Utilized water as a solvent, eliminating the need for hazardous chemicals, making it a highly eco-friendly analytical approach. • Scientific and Practical Relevance : Combines environmental friendliness and analytical efficiency, offering a sustainable alternative for pharmaceutical analysis. This study aims to develop and validate novel UV spectrophotometric methods for the simultaneous estimation of atenolol and hydrochlorothiazide in pharmaceutical dosage forms and bulk. The proposed methods are Simultaneous Equation and Q-Absorbance Ratio methods offer a cost-effective, eco-friendly alternative to chromatographic techniques. The λmax of atenolol and hydrochlorothiazide were identified at 224.00 nm and 234.00 nm, respectively, with an iso-absorptive point at 229.00 nm for the Q-Absorbance Ratio method. The validation followed ICH Q2 (R1) guidelines, demonstrating excellent linearity (R² > 0.99 for both drugs), accuracy (98.5%–101.2%), precision (%RSD < 2%), and sensitivity (LOD: 1.61 µg/mL for atenolol, 0.78 µg/mL for hydrochlorothiazide). The developed methods were successfully applied to a marketed formulation, showing recovery rates within acceptable limits. The environmental sustainability of these methods was assessed using ComplexGAPI, AGREE, Analytical Eco-Scale, ChlorTox WHN, and CHEMS-1 tools. The AGREE score (0.71) and ComplexGAPI assessment (eight green attributes, two red) confirmed superior eco-friendliness over reported HPLC methods (AGREE: 0.62). ChlorTox scores further validated minimal toxicity risks. This research highlights an efficient, accurate, and environmentally benign alternative for atenolol and hydrochlorothiazide analysis, aligning with green analytical chemistry principles.