盐酸雷诺拉嗪的环保型水热分光光度法分析。

Sarthak G Kulkarni, Minal S Patil, Dipali N Patel, Suraj R Chaudhari, Atul A Shirkhedkar
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引用次数: 0

摘要

设计并验证了简单、环保的可生物降解的水托品辅助分光光度法实验,用于定量缓释片中的盐酸兰诺拉嗪(RAN.HCl)。柠檬酸和柠檬酸钠被用作水托品,有望替代极性有机溶剂。开发快速、特异的分光光度法实验,旨在增强 RAN.HCl 的光谱吸收。分光光度法实验为 D0 和 D0 AUC,其中在 270.50 纳米处观察到最高吸光度峰值,AUC 范围为 265.00 至 275.50 纳米。此外,还对 D1 和 D2 进行了光谱分析,分别在 280.00 纳米和 274.40 纳米记录到峰值振幅。D1 的 AUC 波长范围为 275.00-287.00 nm,D2 的 AUC 波长范围为 265.00-279.50 nm。优化实验显示,在 0.02-0.16 mg/mL 浓度范围内呈线性关系。准确度为 50-150%,总体平均回收率为 100.02%。在这些研究中,可准确检测和定量的 RAN.HCl 最低限度分别为 0.0016 和 0.0049、0.0018 和 0.0055、0.0058 和 0.0176、0.0024 和 0.0075、0.0074 和 0.0224、0.0021 和 0.0064 mg/mL。根据 p = 0.05 时的 t 值和 F 值(分别低于 2.2622、2.3646、6.26 和 19.20 的理论值),统计分析显示本调查的结果与文献报告中的结果没有明显差异。
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Eco-friendly hydrotropic spectrophotometric analysis of ranolazine hydrochloride.

Simple and eco-friendly biodegradable hydrotropes-assisted spectrophotometric experiments have been designed and validated to quantify ranolazine hydrochloride (RAN.HCl) in extended-release tablets. The citric acid and sodium citrate are employed as hydrotropes, serving as promising alternatives to polar organic solvents. The development of rapid and specific spectrophotometric experiments aimed at enhancing the spectral absorption of RAN.HCl. The spectrophotometric experiments are D0 and D0 AUC, in which the highest peak absorbance was observed at 270.50 nm, with an AUC ranging from 265.00 to 275.50 nm. Moreover, spectral analysis of D1 and D2 were conducted with peak amplitudes recorded at 280.00 nm and 274.40 nm, respectively. The AUC in the wavelength ranges 275.00-287.00 nm for D1, and 265.00-279.50 nm for D2 were implemented to quantify RAN.HCl confirms no interference from the common additives incorporated into the marketed preparation. The optimized experiments disclosed a linear relationship in the 0.02-0.16 mg/mL concentration range. The accuracy was performed at 50-150 %, revealing an overall average recovery of 100.02 %. The lowest limits of RAN.HCl that could be accurately detected and quantified were 0.0016 and 0.0049, 0.0018 and 0.0055, 0.0058 and 0.0176, 0.0024 and 0.0075, 0.0074 and 0.0224, 0.0021 and 0.0064 mg/mL, respectively, across these investigations. Statistical analysis revealed no significant differences between the outcomes of the present investigation and those documented in literature reports, based on the t- and F-values at p = 0.05, which were below the theoretical values of 2.2622, 2.3646, 6.26, and 19.20, respectively.

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