A comparative analysis of univariate versus multivariate eco-friendly spectrophotometric manipulations for resolving severely overlapped spectra of vonoprazan and amoxicillin new combination.

Vonoprazan and amoxicillin are pharmacological combinations that demonstrate synergistic effects in treating Helicobacter pylori (H. pylori), a global public health concern associated with peptic ulcer disease and gastric cancer. Four spectrophotometric methods were developed, including two univariate techniques (Fourier self-deconvolution and ratio difference) and two multivariate chemometric approaches (partial least squares and principal component regression). These methods provide innovative solutions for effectively resolving and accurately quantifying the overlapping spectra of vonoprazan and amoxicillin. The concentration ranges covered were 3-60 µg ml-1 for vonoprazan and 5-140 µg ml-1 for amoxicillin. To assess the environmental sustainability of the methodologies, various measures such as the Green Analytical Procedure Index (GAPI), National Environmental Method Index (NEMI), Analytical GREEnness Calculator, and Analytical Eco-scale, as well as RGB12 and hexagon toll were implemented. The validation of the developed techniques was carried out in compliance with ICH standards. The present study is highly significant because it is the first time that the mixture has been determined using the current approaches. The comparative analysis demonstrated no significant difference in terms of accuracy and precision compared to reference HPLC method (p = 0.05). The established spectrophotometric methods offer a straightforward, rapid, and cost-effective alternative to complex analytical techniques for determining the vonoprazan and amoxicillin mixture. They show potential for routine analysis in research laboratories and pharmaceutical industries.

Exciting Advances in Sustainable Spectrophotometric Micro-Quantitation of an Innovative Painkiller "Tramadol and Celecoxib" Mixture in the Presence of a Toxic Impurity, Promoting Greenness and Whiteness Studies.

BACKGROUND: Tramadol (TRM) and celecoxib (CLX) form a novel mixture that helps relieve acute pain when other painkillers have no action. It is also reported that these drugs, TRM and CLX, are used to control COVID-19 symptoms. OBJECTIVE: The current work highlights three important pillars of modern pharmaceutical analysis, which are as follows; impurity profiling, greenness/whiteness studies and simplicity accompanied by sensitivity. Since 4-methyl acetophenone inhibits the human carbonyl reductase enzyme (type I) and since this compound may pose a health risk, it is crucial to regulate its concentration in all dosage forms of CLX. METHODS: Two simple and green spectrophotometric methods were developed, namely third derivative (D3) and Fourier self- deconvulation (FSD), for resolving severely overlapped spectra of TRM and CLX in the presence of 4-methyl acetophenone (4-MAP) as a process-related impurity in their novel tablet combination. RESULTS: The two approaches showed acceptable linearity with an excellent correlation coefficient. In both methods, TRM was measured when CLX and 4-methyl acetophenone were zero-crossing. The same procedure was applied for measuring CLX and its process-related impurity 4-MAP. CONCLUSION: The methodologies developed were thoroughly validated in compliance with ICH (International Council on Harmonisation) guidelines. Student t- and F-tests revealed no statistically significant variation among the current methods and the reported method. HIGHLIGHTS: No spectrophotometric methods have been published previously for the simultaneous analysis of TRM and CLX along with 4-MAP. As a result, the newly developed spectrophotometric approaches have great relevance and originality in the field of pharmaceutical analysis.

Sustainable Stability-Indicating spectra manipulations for the concurrent quantification of a novel Anti-COVID-19 drug and its active Metabolite: Green profile assessment.

Millions of individuals have lost their lives and changed their routines as a direct consequence of exposure to the coronavirus (Covid-19). Molnupiravir (MOL) is an orally bioavailable tiny molecule antiviral prodrug that is effective for curing the coronavirus that produces serious acute respiratory disorder (SARS-CoV-2). Fully green-assessed stability-indicating simple spectrophotometric methods have been developed and fully validated as per ICH criteria. The potential impact of degradation products of drug components on the safety and efficacy of a medication's shelf life is likely to be negligible. The field of pharmaceutical analysis necessitates various stability testing under different conditions. The conduct of such inquiries affords the prospect of predicting the most probable routes of degradation and ascertaining the inherent stability characteristics of the active drugs. Consequently, a surge in demand arose for the creation of an analytical methodology that could consistently measure the degradation products and/or impurities that may be present in pharmaceuticals. Herein, five smart and simple spectrophotometric data manipulation techniques have been produced for the concurrent estimation of MOL and its active metabolite as its possible acid degradation product namely; N-hydroxycytidine (NHC). Structure confirmation of NHC build-up through IR, MS and NMR analyses. All current techniques verified linearity ranging from 10 to 150 µg/ml and 10-60 µg/ml for MOL and NHC, respectively. The limit of quantitation (LOQ) values were in the range of 4.21-9.59 µg/ml, while the limit of detection (LOD) values were ranging from 1.38 - 3.16 µg/ml. The current methods were evaluated in terms of greenness by four assessing methods and confirmed to be green. The significant novelty of these methods depends on their being the first environmentally soundness stability-indicating spectrophotometric approaches for the concurrent estimation of MOL and its active metabolite, NHC. Also, the preparation of purified NHC delivers significant cost savings, instead of purchasing an expensive ingredient. These smart methods were utilized for analyzing the pharmaceutical dosage form which may be of great benefit to the pharmaceutical market.

HPLC-DAD technique for the quantification of a recently approved anti-diabetic triple combination along with two toxic official impurities: Toxicity confirmation aided by molecular docking application.

BACKGROUND: Gliflozins and gliptins are two distinct groups of pharmacological drugs that reduce blood glucose levels in individuals with type II diabetes in various ways that may perform their functions harmoniously. Trijardy® tablet, which contains empagliflozin, linagliptin, and metformin, was recently approved. The scientific database does not yet have a method that is sensitive enough to quantify the aforementioned medications in the presence of metformin official toxic impurities melamine and cyanoguanidine. Molecular docking modeling was utilized in this work to further prove the toxicity of melamine. METHODS: The five analytes listed before were quantified using RP-HPLC-diode array detector and a Zorbax® C8 column (4.6 × 250 mm, 5 µm) with isocratic mobile phase composed of acetonitrile and 0.05 M potassium dihydrogen phosphate buffer, which had been treated by ?-phosphoric acid to restore a pH of 4.0 (90:10, v/v) at a flow rate of 1.2 mL/min and the eluted peaks were scanned at 250 nm. CONCLUSION: The utilization of the simplest isocratic elution mode give the current technique a significant time-and cost-saving benefit. The current method can quantify the triple therapy agents in the presence of each other as well as with two official toxic impurities of metformin in one short analytical run.

Manipulation and Processing of Spectral Signals for the Assay of the Newly Authorized Mixture of Bupivacaine/Meloxicam Using Fully Green Solvents and a Comparative Green Evaluation Supporting the Greenness and Sustainability of the Developed Smart Spectrophotometric Methods.

BACKGROUND: The bupivacaine (BVC)/meloxicam (MLX) combination is the first extended-release dual-acting local anesthetic (DALA) that provides 72 h of postoperative pain relief. It reduces opioid use after surgery and manages pain better than BVC alone over 72 h, and overcomes surgical site inflammation with a new synergistic mode of action that combines BVC with a low dosage of MLX. OBJECTIVE: In today's pharmaceutical research, we take great care to only use non-toxic solvents that pose no threat to either humans or the environment. This work determines BVC and MLX simultaneously, utilizing water and 0.1 M HCl in water as solvents. Moreover, the eco-friendliness of the specified solvents and the whole method development steps was evaluated based on how user-friendly they were using four standard methodologies. METHODS: The developed spectrophotometric methods depended on either zero-order, derivative, or ratio spectra that only required simple mathematical handling. The current techniques include dual wavelength (DW), Fourier self-deconvolution (FSD), first derivative (D1), ratio difference (RD), and first ratio derivative (DD1). RESULTS: Linearity was confirmed over a concentration range of 50-700 µg/mL for BVC and 1-10 µg/mL for MLX. For BVC and MLX, the LOQs were 26.85-41.33 µg/mL and 0.21-0.95 µg/mL, while the LODs were 8.86-13.64 µg/mL and 0.06-0.31 µg/mL, respectively. For the full validation of the proposed methods, ICH (international conference on harmonization) criteria were followed. CONCLUSION: Current methods have the advantage of sticking to the basis of zero-order, derivative, or ratio spectra and needing just the barest minimum of data processing: no complex software, lengthy stages, or transformations are needed. HIGHLIGHTS: No spectrophotometric methods have been published for the simultaneous analysis of BVC and MLX. As a result, the newly developed spectrophotometric approaches have great relevance and originality in the field of pharmaceutical analysis.

Green micelle and complex inclusion enhance synchronous spectrofluorimetric quantification of a novel analgesic combination: Tramadol and celecoxib in tablet dosage form and spiked human plasma.

This work offers for the first time an optimized, highly sensitive, simple, and accurate synchronized spectrofluorimetric technique for the simultaneous measurement of tramadol and celecoxib in powder form, their combined multimodal tablet, and finally spiked human plasma samples. Tramadol and celecoxib were recently released as a new drug combination to alleviate intense, sudden pain when other pain medications had failed. The technique entailed taking measurements of the fluorescence amplitudes of the synchronized spectra at Δλ = 100 nm. Excitation was made at 220 nm and 264 nm, whereas the emission points were 282 nm and 368 nm for tramadol and celecoxib, respectively. This technique offers linearity of 40-400 ng/ml and 100-2000 ng/ml for tramadol and celecoxib, respectively. Complex formation between the cited medications with the surfactant sodium dodecyl sulphate enhanced the fluorescence intensity and other control parameters. Tramadol and celecoxib were both determined in spiked human plasma using the current technique with marked percentage recoveries of 98.63 ± 6.30% and 99.32 ± 6.67%, respectively. Last, the research was extended to check the greenness profile of the finally optimized method and the results revealed excellent eco-friendliness. Three greenness assessment tools were used including Eco-scale, the Green Analytical Procedure Index tool, and the AGREE calculator. Sustainable development, economic feasibility, and environmental soundness were all considered throughout the development of the present technique. The approach was validated in accordance with the requirements provided by the International Council for Harmonization.

Expeditive Chromatographic Methods for Quantification of Solifenacin Succinate along with its Official Impurity as the Possible Acid Degradation Product.

Two selective stability-indicating procedures were adopted for the quantification of Solifenacin succinate (SOL) along with its acid degradant, in its powder form or in pharmaceutical tablet. Under stress conditions, the acid degradation pathway of SOL was investigated, its official impurity (SOL imp-A) was obtained as the possible acid degradation product, also. A densitometric technique based on the separation of SOL from SOL imp-A employing HPTLC plates prelaminated with silica gel 60 F254 as the stationary phase and a developing solution containing methanol:chloroform:ammonia (8:1:1, v/v/v) and UV scanning of the developed bands at 220 nm. Linear regression analysis data for the calibration plot of SOL showed perfect linear relationships throughout the range of concentration 10-60 µg/band. A reversed phase C18 analytical column (4.6 × 250 mm, 5 µm) was also used to separate the mixture at a flow rate of 1 mL/min, using acetonitrile:0.05 M phosphate buffer (70:30, v/v) as the mobile phase and phosphoric acid to set pH = 3.5. Quantification was obtained at 220 nm using peak area and linear calibration curve across a concentration range of 10-70 µg/mL. The recommended procedures were applied to the existing dosage form, and they generated satisfactory results.

Two green chromatographic methods for the quantification of tamsulosin and solifenacin along with four of their impurities.

Modern analytical procedures often include impurity profiling to verify the potency, safety, and effectiveness of new formulations. We had to develop techniques based on green analysis since the detrimental influence of solvents and chemicals on the environment has now become a serious concern. Two selective, sensitive, and green liquid chromatography methods were established and fully validated for quantitation of tamsulosin hydrochloride and solifenacin succinate along with four of their official and/or related impurities namely; tamsulosin sulfonic acid, tamsulosin impurity H, solifenacin impurity A and solifenacin impurity C. The first used high-performance thin-layer chromatography with silica gel 60 F254 plates as the stationary phase and an elution system of ethyl acetate:butanol:glacial acetic acid (10.0:0.4:0.1, by volume) and a scanning wavelength of 225.0 nm. The second method depended on HPLC with diode array detection. Chromatographic separation was accomplished on a Zorbax SB C18 (250 × 4.6 mm2 , 5 µm) column utilizing a mixture of 10.0 mM sodium dihydrogen phosphate (pH 3.0, adjusted by o-phosphoric acid) and methanol, at a flow rate of 0.8 mL/min in a gradient elution mode and then the separated peaks were scanned at a wavelength of 225.0 nm. To assess the greenness profile, three distinct methodologies were applied.

Three Smart and Original Spectrophotometric Data Processing Ratio Techniques for Resolving the Partial Overlapped Spectra of the Binary Antiviral Mixture Daclatasvir/Sofosbuvir: Application to Combined Dosage Form Darvoni® Tablets.

BACKGROUND: The combination of daclatasvir (DCV) and sofosbuvir (SFV) is now widely used as an ideal treatment for hepatitis C virus (HCV) infection. For this purpose, simple, sensitive, rapid, and smart spectrophotometric methods were developed and validated for the determination of these drugs in their combined dosage form. OBJECTIVE: Development of smart, sensitive, low-cost spectrophotometric methods for the determination of DCV and SFV in their combined dosage form. METHODS: Ratio subtraction (RS), amplitude modulation (AM), and mean-centering spectrophotometric methods were established and validated for the estimation of SFV in the presence of DCV without previous separation, using a unified regression equation. RESULTS: A linearity range of 2.5-25.0 µg/mL was confirmed for the direct measurement of DCV at 316 nm (because there is no interference from SFV. Linearity was confirmed over a concentration range of 10.0-80.0 µg/mL for SFV. The current methods were established according to the ICH recommendations, and specificity was examined by testing synthetic mixtures of both drugs. They were tested on their tablet dosage form, and a good recovery was obtained. CONCLUSION: The current methods proved to be simple, specific, and economical. A statistical study of the current ratio approaches and published methods showed there was no apparent statistical variation. HIGHLIGHTS: Both antiviral agents can be quantified in the presence of each other by the current methods, which is a significant time- and cost-saving benefit of the developed methods. This benefit is even more important in the case of the combined dosage form (Darvoni® tablets) for the pharmaceutical market.

HPLC-UV and TLC-Densitometry Methods for Simultaneous Determination of Sofosbuvir and Daclatasvir: Application to Darvoni® Tablet.

Sofosbuvir and daclatasvir are co-formulated as directly acting antiviral agents used for treatment of hepatitis C virus. Two chromatographic methods were developed for their determination; the first one is an Reversed phase-high performance liquid chromatography (RP-HPLC) method, in which the separation was performed on C8 Zorbax® SB column (4.6 × 250 mm, 5 µm) using acetonitrile:water:0.05 M phosphate buffer, pH = 8 (50:45:5, v/v/v) as a mobile phase, and ultraviolet detection was performed at 280 nm. Good resolution was obtained, and linearity was confirmed in the range of 10-100 µg/mL for both drugs. The second method is Thin layer chromatography (TLC)-densitometric one, in which sofosbuvir and daclatasvir were separated on silica gel plates using ethyl acetate:hexane:methanol (9:0.5:0.5, v/v/v) as a developing system and the scanning wavelength was 280 nm. Linearity was confirmed over a concentration range of 0.4-25.4 µg/band for sofosbuvir, whereas for daclatasvir linearity scanning was in the range of 0.4-12.8 µg/band. Both antiviral agents can be quantified simultaneously in one analytical run, which is a great time- and cost-saving valor of the developed methods. This valor is even more important in the case of the combined dosage form (Darvoni® tablets) to the pharmaceutical market.

Smart Mathematical Manipulation οf Spectral Signals: Stability Indicating, fοr the Estimation of Sοlifenacin Succinate: Anti-Muscarinic Drug, in Existence οf Its Acid Degradatiοn Product.

BACKGRΟUND: Fοur rapid, smart, and easy tο apply spectrοphοtοmetric methοds were developed fοr the estimatiοn οf sοlifenacin succinate (SΟL) with its acid-induced degradation prοduct. ΟBJECTIVE: Development οf stability-indicating, smart, sensitive, cheap spectrοphοtοmetric methοds fοr determinatiοn οf SΟL in the presence οf its acid degradate. METHΟDS: Methοd A is a dual wavelength methοd where twο wavelengths were selected (262 and 289 nm) and utilized tο determine SΟL in the presence οf its acid degradate. Methοd B involves develοping the first derivative (1D) οf the absοrptiοn spectra. Peak signal was detected at 276 nm. Methοd C is a ratiο difference methοd where the drug is determined by the difference in signal between twο selected wavelengths, at 240 and 259 nm. Methοd D is dependent οn measuring the peak signal οf the first derivative οf the ratiο spectra (1DD) at 269 nm. RESULTS: Calibratiοn curves οf the suggested methοds exhibited linearity. The selectivity οf the suggested methοds were ascertained using different labοratοry-prepared mixtures οf SΟL with its acid degradate, indicating specificity οf SΟL with accepted recοvery values. The suggested methοds have been successfully applied tο the analysis οf SΟL in its pharmaceutical dοsage fοrm withοut the invοlvement οf additives. CΟNCLUSIΟN: The presented wοrk applied fοur resοlutiοn techniques, based οn absοrbance, derivative, and/οr ratiο spectra, fοr the analysis οf SΟL in the presence οf its acid degradate. HIGHLIGHTS: The study οf degradatiοn pathways οf drugs is οf great impοrtance. Hence, acid hydrοlysis οf SΟL was achieved and then SΟL was determined alοng with its acid degradate.