Validation of stability-indicating LC method, degradation study, and impact on antioxidant and antifungal activities of Eugenia uniflora leaves extract.

The aim of this study is to demonstrate the stability-indicating capacity of an analytical method for Eugenia uniflora, enhance understanding of the stability of myricitrin, and assess the effect of degradation of spray-dried extract (SDE) on antioxidant and antifungal activities. Validation of the stability-indicating method was carried out through a forced degradation study of SDE and standard myricitrin. The antioxidant and antifungal activities of SDE were evaluated both before and after degradation. The quantification method described was found to be both accurate and precise in measuring myricitrin levels in SDE from E. uniflora, with excellent selectivity that confirmed its stability-indicating capability. The forced degradation study revealed that the marker myricitrin is sensitive to hydrolysis, but generally stable under other stress conditions. By contrast, the standard myricitrin displayed greater susceptibility to degradation under forced degradation conditions. Analysis of the antioxidant activity of SDE before and after degradation showed a negative impact in this activity due to degradation, while no significant effect was observed on antifungal activity. The method described can be a valuable tool in the quality control of E. uniflora, and the findings can assist in determining the optimal conditions and storage of products derived from this species.

Aplicação da eletroforese capilar - espectrometria de massas para identificação dos produtos de degradação do aripiprazol em medicamentos / Application of capillary electrophoresis - mass spectrometry to identify aripiprazole degradation products in drugs

Diretrizes internacionais e nacionais como a FDA (Food and Drug Administration), ICH (International Council for Harmonisation) e ANVISA (Agência Nacional de Vigilância Sanitária) estabelecem a exigência de testes de estabilidade para entender melhor a qualidade de um medicamento. O estudo de estabilidade deve ser realizado usando métodos indicativos de estabilidade que possam qualificar e quantificar os insumos farmacêuticos do medicamento, bem como as impurezas e produtos de degradação nele contidos. O aripiprazol é um antipsicótico atípico de segunda geração aprovado para o tratamento de esquizofrenia, transtorno bipolar, depressão e transtornos do espectro do autismo. Os métodos oficiais descritos nas farmacopeias para avaliar o aripiprazol e suas impurezas utilizam a cromatografia líquida de alta eficiência (HPLC) como técnica principal. Nesta pesquisa, objetivou-se desenvolver um método indicativo de estabilidade por eletroforese capilar de zona (CZE) para o aripiprazol na forma farmacêutica de comprimidos, e identificação dos produtos de degradação por espectrometria de massas. O estudo de degradação forçada e a optimização do método desenvolvido por CZE foram realizados utilizando o conceito de delineamento de experimentos (DoE). A separação do aripiprazol de seus produtos de degradação foi conseguida usando uma coluna capilar de sílica fundida (30,2 cm x 75 µm ID), eletrólito de formiato de amônio 6 mmol/L (pH 3) com 5% de metanol sob um potencial de 15 kV e detecção em 214 nm. A capacidade indicativa de estabilidade do método foi investigada pela análise do aripiprazol após ser submetido a condições de estresse ácido, alcalino, térmico, fotolítico e oxidativo, de acordo com as diretrizes ICH. A oxidação foi a principal via de degradação entre as condições de estresse avaliadas. O aripiprazol foi separado dos seus produtos de degradação oxidativa em tempo de corrida abaixo de 5 minutos. O método por CZE mostrou ser linear na faixa de 60 - 140 µg/mL, R2 = 0,9980, precisão calculada como desvio padrão relativo (DPR) menor que 2% e exatidão calculada como recuperação média de 100,93 ± 0,77%. Os resultados obtidos demonstram que o método por HPLC-RP em modo gradiente, separou o aripiprazol e seus produtos de degradação em um tempo de corrida de 30 minutos. Quatro produtos de degradação foram detectados pelo método LC-MS e o principal produto de degradação oxidativo foi identificado. O aripiprazol mostrou-se suscetível à oxidação no grupo piperazina, gerando principalmente o composto aripiprazol-1-N-óxido

International and national guidelines such as the FDA (Food and Drug Administration), ICH (International Council for Harmonization) and ANVISA (National Health Surveillance Agency) establish the requirement for stability tests to better understand quality of a medicine. The stability study must be carried out using stability indicating methods that can qualify and quantify the pharmaceutical ingredients of the drug, as well as the impurities and degradation products contained therein. Aripiprazole is a second-generation atypic antipsychotic drug approved for the treatment of schizophrenia, bipolar disorder, depression, and autism spectrum disorders. The official method described in the pharmacopoeias to evaluate aripiprazole and its impurities is high performance liquid chromatography (HPLC) as the main technique. In this research, the objective was to develop an indicative method of stability by capillary zone electrophoresis (CZE) for aripiprazole in the pharmaceutical form of tablets, and identification of degradation products by mass spectrometry. The forced degradation study and the optimization of the method developed by CZE were carried out using the concept of design of experiments (DoE). The separation of aripiprazole from its degradation products was achieved using a fused silica capillary column (30,2 cm x 75 µm ID), 6 mmol/L ammonium formate electrolyte (pH 3) with 5% methanol under a potential of 15 kV and detection at 214 nm. The indicative stability of the method was investigated by analyzing aripiprazole after being subjected to acid, alkali, thermal, photolytic and oxidative stress conditions, according to the ICH guidelines. Oxidation was the main degradation pathway among the stress conditions evaluated. Aripiprazole was separated from its oxidative degradation products at run times below 5 minutes. The CZE method proved to be linear in the range of 60 - 140 µg/mL, R2 = 0,9980, precision calculated as a relative standard deviation (DPR) of less than 2% and accuracy calculated as a mean recovery of 100,93 ± 0,77%. The results obtained demonstrate that the HPLC-RP method in gradient mode separated aripiprazole and its degradation products in a run time of 30 minutes. Four degradation products were detected by the LC-MS method and the main oxidative degradation product was identified. Aripiprazole was shown to be susceptible to oxidation in the piperazine group, generating mainly the compound aripiprazole-1-N-oxide

Design of experiments applied to stress testing of pharmaceutical products: A case study of Albendazole.

Forced degradation tests are studies used to assess the stability of active pharmaceutical ingredients (APIs) and their formulations. These tests are performed submitting the API under extreme conditions in order to know the main degradation products in a short period of time. The results of these studies are used to assess the degradation susceptibility of APIs and to validate chromatographic analytical methods. However, most of degradation studies are performed using one-factor-at-the-time (OFAT) which does not consider the interactions between degradation variables. This work proposes the use of Design of Experiment (DoE) approach in forced degradation of albendazole (ABZ). It was used a central composite design (CCD) to evaluate the forced degradation in a multivariate way. Experiments were performed taking into account the variables pH, temperature, oxidizing agent (H2O2) and UV radiation. It was verified the influence of the variables and their interactions on the ABZ degradation. The ABZ oxidation showed to be the main degradation route for ABZ, which is strongly influenced by the temperature. The hydrolysis was relevant at alkaline medium and high temperature. LC-IT-MSn was used to identify the degradation products. It was found three known degradation products (albendazole-2-amino, albendazole sulfoxide and albendazole sulfone) and a new derivate of albendazole molecule (albendazole sulfoxide with a chlorine). This last one was isolated and characterized by UPLC-QToF-MS and NMR analyses.

Taxifolin stability: In silico prediction and in vitro degradation with HPLC-UV/UPLC-ESI-MS monitoring.

Taxifolin has a plethora of therapeutic activities and is currently isolated from the stem bark of the tree Larix gmelinni (Dahurian larch). It is a flavonoid of high commercial interest for its use in supplements or in antioxidant-rich functional foods. However, its poor stability and low bioavailability hinder the use of flavonoid in nutritional or pharmaceutical formulations. In this work, taxifolin isolated from the seeds of Mimusops balata, was evaluated by in silico stability prediction studies and in vitro forced degradation studies (acid and alkaline hydrolysis, oxidation, visible/UV radiation, dry/humid heating) monitored by high performance liquid chromatography with ultraviolet detection (HPLC-UV) and ultrahigh performance liquid chromatography-electrospray ionization-mass spectrometry (UPLC-ESI-MS). The in silico stability prediction studies indicated the most susceptible regions in the molecule to nucleophilic and electrophilic attacks, as well as the sites susceptible to oxidation. The in vitro forced degradation tests were in agreement with the in silico stability prediction, indicating that taxifolin is extremely unstable (class 1) under alkaline hydrolysis. In addition, taxifolin thermal degradation was increased by humidity. On the other hand, with respect to photosensitivity, taxifolin can be classified as class 4 (stable). Moreover, the alkaline degradation products were characterized by UPLC-ESI-MS/MS as dimers of taxifolin. These results enabled an understanding of the intrinsic lability of taxifolin, contributing to the development of stability-indicating methods, and of appropriate drug release systems, with the aims of preserving its stability and improving its bioavailability.

Luliconazole: Stability-indicating LC method, structural elucidation of major degradation product by HRMS and in silico studies / Luliconazol: método por LC indicativo de estabilidad, elucidación estructural del producto de degradación mayoritario por HRMS y estudios in silico / Luliconazol: método LC indicativo de estabilidade, elucidação estrutural do principal produto de degradação por HRMS e estudos in sílico

SUMMARY Aim: A new stability-indicating liquid chromatography method was developed and validated for the quantitative determination of luliconazole. Materials and methods: Preliminary forced degradation study demonstrated an additional peak of the degradation product at the same retention time to the drug, due to this, the method was developed optimizing the chromatographic conditions to provide sufficient peak resolution (R ≥ 2). The experimental design was evaluated to assess the robustness and the best chromatographic conditions to be used for the validation. Methodology: Luliconazole solutions were exposed to various stress conditions to evaluate the method indication stability, in which the degradation product (DP-1) formed was isolated, identified, and evaluated in silico to predict degradation pathway and toxicity. The procedure was validated by robustness, selectivity, linearity, precision, and accuracy. Liquid chromatography was performed in a Phenomenex® RP-18 column with a mixture of acetonitrile and 0.3% (v/v) triethylamine solution as a mobile phase in isocratic elution. Results and conclusions: The method demonstrated robustness, good recovery, precision, linear response over a range from 5.0 to 40.0 μg.mL-1- and to be stability indicating. The alkaline stress condition resulted in the formation of DP-1. HRMS studies identified this product as an hydroxyacetamide derivative, and in silico studies did not show toxic potential.

RESUMEN Objetivo: Un nuevo método indicativo de estabilidad por cromatografía líquida fue desarrollado y validado para la determinación cuantitativa de luliconazol. Materiales y métodos: Estudios preliminares de degradación forzada demostraron un pico adicional en el mismo tiempo de retención del fármaco. El método desarrollado para optimizar las condiciones cromatográicas proporcionó una adecuada resolución (R ≥ 2). El diseño experimental fue evaluado para verificar su robustez y la mejor condición cromatográica para validación. Metodología: Las soluciones de luliconazol fueron expuestas a diferentes condiciones de estrés para evaluar la indicación de estabilidad del método, el aislamiento del producto de degradación formado (DP-1), su identificación y análisis in silico para predecir su ruta de degradación y toxicidad. El procedimiento se validó por robustez, selectividad, linealidad, precisión y exactitud. Las condiciones cromatográficas incluyeron una columna Phenomenex® RP-18, como fase móvil una mezcla de acetonitrilo y solución 0,3% (v/v) de trietilamina en elución isocrática. Resultados y conclusiones: El método mostró ser robusto, con buena recuperación, precisión, respuesta lineal en el rango de 5,0 a 40,0 μg.mL-1 e indicativo de la estabilidad. La condición de estrés alcalina resultó en la formación de DP-1. Estudios por HRMS identificaron este producto como un derivado hidroxiacetamida y los estudios in silico no mostraron potencial de toxicidad.

RESUMO Objetivo: Um novo método indicativo de estabilidade por cromatograia líquida foi desenvolvido e validado para a determinação quantitativa de luliconazol. Materiais e métodos: Estudos preliminares de degradação forçada demonstraram um pico adicional no mesmo tempo de retenção do medicamento. O método desenvolvido para otimizar as condições cromatográficas proporcionou resolução adequada (R ≥ 2). O delineamento experimental foi avaliado para verificar sua robustez e a melhor condição cromatográica para validação. Metodologia: Soluções de luliconazol foram expostas a diferentes condições de estresse para avaliar a indicação da estabilidade do método, o isolamento do produto de degradação formado (DP-1), sua identificação e análise in silico para predizer sua rota de degradação e toxicidade. O procedimento foi validado quanto à robustez, seletividade, linearidade, precisão e exatidão. As condições cromatográficas incluíram uma coluna Phenomenex® RP-18, como fase móvel uma mistura de acetonitrila e solução de trietilamina 0,3% (v/v) em eluição isocrática. Resultados e conclusões: O método mostrou-se robusto, com boa recuperação, precisão, resposta linear na faixa de 5,0 a 40,0 μg.mL-1 e indicativo de estabilidade. A condição de estresse alcalino resultou na formação de DP-1. Os estudos da HRMS identificaram este produto como um derivado da hidroxiacetamida e os estudos in silico não mostraram nenhum potencial de toxicidade.

Stability-indicating method for the novel antifungal compound RI76: Characterization and in vitro antifungal activity of its active degradation product.

RI76 is a novel 2-thiazolylhydrazone compound with reported antifungal activity. In preclinical drug development, it is fundamental to know the impurity profile and to understand degradation mechanisms of the molecule. In our study, RI76 was subjected to forced degradation conditions, and a stability-indicating HPLC-DAD method was developed and validated. Separation was carried out on a C18 column (150 × 4.6 mm i.d., 5 µm) maintained at 40°C using a 1 mL/min flow rate of 2 mM ammonium acetate with 0.1% formic acid (pH 3.0) and acetonitrile in gradient mode. The method was linear in the range of 0.7-91 µg/mL for RI76 and 0.7-25 µg/mL for its degradation product PD76. The formation of a major degradation product was quickly observed when RI76 was in aqueous solution. The chemical structure of this product, named PD76, was proposed based on LC-UV-MS experiments, synthesized in-house, and confirmed by NMR spectroscopy and chromatographic analysis. In vitro antifungal activity assays demonstrated that this resultant product shows a promising activity against clinically important Candida and Cryptococcus strains, matching or surpassing the activity of its precursor and of well-established antifungal drugs.

Comparative stability of arbutin in Arctostaphylos uva-ursi by a new comprehensive stability-indicating HPLC method.

INTRODUCTION: Arbutin is a phenol glucoside found in high concentrations in bearberry leaves and associated with the antimicrobial activity of the plant. Hydroquinone can also be found in leaves or be formed by degradation of arbutin. Lengthy exposure to free hydroquinone is associated with induction of toxicity in different organs. OBJECTIVE: To develop and validate a stability-indicating method by high-performance liquid chromatography diode array detector (HPLC-DAD) for simultaneous quantification of arbutin and hydroquinone in bearberry leaves and perform a comprehensive forced degradation study comparing synthetic arbutin and the arbutin in bearberry leaves. METHODS: Separation was performed using a C18 column, mobile phase with water-methanol (95:5), flow rate 1.0 mL/min and detection at 280 nm. Bearberry leaves were assayed and a forced degradation study of arbutin was performed in different conditions. RESULTS: The method complied with all required validation parameters. Contents varied from 1.19 to 4.15% (w/w) of arbutin and from 0.022 to 0.604% (w/w) of hydroquinone. Synthetic arbutin was susceptible to acid hydrolysis and oxidative degradation, forming hydroquinone as the main degradation product. The same study using bearberry leaves showed that constituents of the plant matrix may act as antioxidants, reducing the oxidative degradation of arbutin, however acid hydrolysis of arbutin occurred in higher intensity. CONCLUSION: Analysis of bearberry leaves evidenced high variation in arbutin and hydroquinone levels, demonstrating the need for standardisation and control. The stability profiles of synthetic arbutin and the arbutin in bearberry leaves were considerably different and the results may be useful for determining the most appropriate conditions for extraction and production of bearberry-based formulations.

Ensaios de degradação forçada e degradação em plasma sanguíneo de peptídeos intracelulares com potencial para composição farmacológica / Forced degradation and blood plasma degradation tests on intracellular peptides with potential for drug composition.Forced degradation and blood plasma degradation tests on intracellular peptides with potential for drug composition

Several proteins that act in the control of the cell cycle are degraded by the ubiquitin proteasome system UPS. Among them, cyclin D2, which is the precursor protein of pep5, an intracellular peptide with potential for the pharmacological composition of antitumor drugs and in combating Chagas disease. Previous studies have characterized pep5 and its minimal sequence with pharmacological action, that is, the smallest portion of the molecule without losing its therapeutic effect. The objective of this work was accomplishing tests to understand the stability profile of this promising molecule and its minimum sequence with six residues (pep5r) with pharmacological action. For this, we employ a method of forced degradation analysis in which we promote stressful situations, such as oxidation, temperature and hydrolysis to determine the degradation times under common conditions during the conditioning and transport of these peptides, in addition to these experiments, we carried out a profile study degradation of peptides in interaction with human blood plasma. The results showed that pep5r is more stable than pep5 among the parameters analyzed, in addition, pep5 was more susceptible to modification by hydrolysis in alkaline media. Both peptides did not undergo thermal modification at 37 ° for 4 hours of incubation, requiring a prolonged study or with higher temperature values to promote degradation. The degradation tests in plasma showed that pep5 is not whole after 15 minutes in interaction with human blood plasma, in contrast, the mass of pep5r was found throughout the analysis period. Therefore, we conclude that although the experiments were carried out with only one sample, the results enabled us to construct initial ideas about some characteristics related to the stability of these peptides, either by environmental actions or degradation in blood plasma. Furthermore, all the initial tests carried out in this work provide guidance for future tests aiming at an eventual pharmacological record of the peptides in question.

Diversas proteínas que atuam no controle do ciclo celular são degradadas pelo sistema ubiquitina proteossoma (UPS). Dentre elas, a ciclina D2, que é a proteína precursora do pep5, um peptídeo intracelular com potencial para composição farmacológica de medicamentos antitumorais e no combate à doença de chagas. Estudos anteriores caracterizaram o pep5 e sua mínima sequência com ação farmacológica, ou seja, a menor porção da molécula sem que ela perca seu efeito terapêutico. O objetivo deste trabalho foi realizar ensaios para compreender o perfil de estabilidade dessa promissora molécula e de sua mínima sequência com seis resíduos (pep5r) com ação farmacológica. Para isso, empregamos um método de análise de degradação forçada em que promovemos situações de estresse, como oxidação, temperatura e hidrólise para determinar os tempos de degradação em condições comuns durante o acondicionamento e transporte desses peptídeos, além desses experimentos, realizamos um estudo do perfil degradação dos peptídeos em interação com o plasma sanguíneo humano. Os resultados mostraram que o pep5r é mais estável que o pep5 dentre os parâmetros analisados, além disso, o pep5 mostrou-se mais suscetível a modificações por hidrólise em meios alcalinos. Ambos os peptídeos não sofreram modificações térmica a 37° durante 4 horas de incubação, sendo, necessário um estudo prolongado ou com valores de temperatura maiores para promover a degradação. Os ensaios de degradação em plasma sanguíneo humano mostraram que o pep5 não se encontra integro após 15 minutos, em contrapartida, a massa do pep5r foi encontrada durante todo o período de análise. Portanto, concluímos que apesar dos experimentos terem sido realizados com apenas uma amostragem, os resultados nos possibilitaram a construção de ideias iniciais sobre algumas características relacionadas à estabilidade desses peptídeos, seja por ações do ambiente ou degradação em plasma sanguíneo. Além disso, todos os ensaios iniciais realizados nesse trabalho possibilitam um direcionamento para realização de ensaios futuros visando um eventual registro farmacológico dos peptídeos em questão.

Stability-indicating HPLC method for determination of amiodarone hydrochloride and its impurities in tablets: a detailed forced degradation study

Resumo Amiodarone hydrochloride is one of the most important drugs used to treat arrhythmias. The USP monograph for amiodarone hydrochloride describes an HPLC method for the quantification of seven impurities, however, this method shows problems that result in unresolved peaks. Moreover, there is no monograph for tablets in this compendium. Thus, a stability indicating HPLC method was developed for the determination of amiodarone, its known impurities and degradation products in tablets. A detailed forced degradation study was performed submitting amiodarone API, tablets and placebo to different stress conditions: acid and alkaline hydrolysis, oxidation, metal ions, heat, humidity, and light. Amiodarone hydrochloride API was susceptible to degradation in all stress conditions. The tablets also showed degradation in all environments, except in acidic condition. The analytes separation and quantification were achieved on an Agilent Zorbax Eclipse XDB-C18 column (100 x 3.0 mm, 3.5 µm). The mobile phase was composed of 50 mM acetate buffer pH 5.5 (A) and a mixture of methanol-acetonitrile (3:4, v/v) (B) in gradient elution. The method was validated in the range of 350-650 µg/mL for assay and 10-24 µg/mL for impurities determination. Therefore, this method can be used both for stability studies and routine quality control analyses.

Chemometrics Approaches in Forced Degradation Studies of Pharmaceutical Drugs.

Chemometrics is the chemistry field responsible for planning and extracting the maximum of information of experiments from chemical data using mathematical tools (linear algebra, statistics, and so on). Active pharmaceutical ingredients (APIs) can form impurities when exposed to excipients or environmental variables such as light, high temperatures, acidic or basic conditions, humidity, and oxidative environment. By considering that these impurities can affect the safety and efficacy of the drug product, it is necessary to know how these impurities are yielded and to establish the pathway of their formation. In this context, forced degradation studies of pharmaceutical drugs have been used for the characterization of physicochemical stability of APIs. These studies are also essential in the validation of analytical methodologies, in order to prove the selectivity of methods for the API and its impurities and to create strategies to avoid the formation of degradation products. This review aims to demonstrate how forced degradation studies have been actually performed and the applications of chemometric tools in related studies. Some papers are going to be discussed to exemplify the chemometric applications in forced degradation studies.

Validation of a UPLC-PDA method to study the content and stability of 5-chloro 8-hydroxyquinoline and 5,7-dichloro 8-hydroxyquinoline in medicated feed used in swine farming.

A new, rapid, simple and specific method to determine 5-chloro 8-hydroxyquinoline (5-HQ) and 5,7-dichloro 8-hydroxyquinoline (5,7-HQ) stability in swine feed was optimized and validated. A system consisting of an ACQUITY UPLC BEH C18 column (1.7 µm, 2.1 mm × 100 mm), a mobile phase of acetonitrile-0.1% o-phosphoric acid (55:45 v/v) with a 0.5 mL/min flow rate, and a PDA detector (247 nm) were used. The retention times of 5-HQ and 5,7-HQ, were 0.77 min and 1.6 min, respectively. The pure drug was subjected to acid and alkali hydrolysis, chemical oxidation and UV light degradation to perform forced degradation studies. 5,7-HQ was more susceptible to degradation than 5-HQ. The figures of merit of the method (linearity, accuracy, precision, and robustness) were determined. The method was successfully applied to estimate the stability of both analytes in medicated feed.

Forced degradation of l-(+)-bornesitol, a bioactive marker of Hancornia speciosa: Development and validation of stability indicating UHPLC-MS method and effect of degraded products on ACE inhibition.

The antihypertensive activity of the medicinal plant Hancornia speciosa has been previously demonstrated by us, being the activity ascribed to polyphenols and cyclitols like l-(+)-bornesitol. We herein evaluated the stability of the bioactive marker bornesitol submitted to forced degradation conditions. Bornesitol employed in the study was isolated from H. speciosa leaves. An UHPLC-ESI-MS/MS method was developed to investigate bornesitol stability based on MRM (Multiple Reaction Monitoring) acquisition mode and negative ionization mode, employing both specific (m/z 193 → 161 Da) and confirmatory (m/z 193 → 175 Da) transitions. A gradient elution of 0.1% formic acid in water and acetonitrile was performed on a HILIC column. The method was validated and showed adequate linearity (r2 > 0.99), selectivity, specificity, accuracy, and precision (RSD < 2.9%). The method was robust for deliberate variations on dessolvation temperature, but not for changes in the flow rate and dessolvation gas. The results from the stability studies allowed us to classify bornesitol as labile for acidic and alkaline hydrolysis, but as very stable for oxidative and neutral hydrolysis exposure. Bornesitol was categorized as practically stable under photolysis degradation, whereas a considerable reduction on its contents was induced by metal ions and thermolysis exposure. Degraded samples from neutral hydrolysis and thermolysis were assayed in vitro for ACE inhibition and showed a substantial decrease in biological activity as compared to intact bornesitol. myo-Inositol was identified as the major degradation products in both matrices. This is the first report on bornesitol stability under different stress conditions and the obtained data are relevant for the development and quality control of standardized products from H. speciosa leaves.

Evaluation of the influence of fluoroquinolone chemical structure on stability: forced degradation and in silico studies

ABSTRACT Fluoroquinolones are a known antibacterial class commonly used around the world. These compounds present relative stability and they may show some adverse effects according their distinct chemical structures. The chemical hydrolysis of five fluoroquinolones was studied using alkaline and photolytic degradation aiming to observe the differences in molecular reactivity. DFT/B3LYP-6.31G* was used to assist with understanding the chemical structure degradation. Gemifloxacin underwent degradation in alkaline medium. Gemifloxacin and danofloxacin showed more degradation perceptual indices in comparison with ciprofloxacin, enrofloxacin and norfloxacin in photolytic conditions. Some structural features were observed which may influence degradation, such as the presence of five member rings attached to the quinolone ring and the electrostatic positive charges, showed in maps of potential electrostatic charges. These measurements may be used in the design of effective and more stable fluoroquinolones as well as the investigation of degradation products from stress stability assays.

Forced degradation of gliquidone and development of validated stability-indicating HPLC and TLC methods

Forced degradation studies of gliquidone were conducted under different stress conditions. Three degradates were observed upon using HPLC and TLC and elucidated by LC-MS and IR. HPLC method was performed on C18 column using methanol-water (85:15 v/v) pH 3.5 as a mobile phase with isocratic mode at 1 mL.min-1 and detection at 225 nm. HPLC analysis was applied in range of 0.5-20 µg.mL-1 (r =1) with limit of detection (LOD) 0.177 µg.mL-1. TLC method was based on the separation of gliquidone from degradation products on silica gel TLC F254 plates using chloroform-cyclohexane-glacial acetic acid (6:3:1v/v) as a developing system with relative retardation 1.15±0.01. Densitometric measurements were achieved in range of 2 -20 µg /band at 254 nm (r = 0.9999) with LOD of 0.26 µg /band. Least squares regression analysis was applied to provide mathematical estimates of the degree of linearity. The analysis revealed a linear calibration for HPLC where a binomial relationship for TLC. Stability testing and methods validation have been evaluated according to International Conference on Harmonization guidelines. Moreover, the proposed methods were applied for the analysis of tablets and the results obtained were statistically compared with those of pharmacopeial method revealing no significant difference about accuracy and precision.

Development and validation of a stability-indicating LC-UV and LC-MS/MS methods for quantitative analysis of anisomycin and identification of degradation products

ABSTRACT Multifunctional drug anisomycin was subjected to forced degradation in accordance with International Conference on Harmonisation (ICH) guidelines for the first time. The drug was exposed to the recommended stress conditions of hydrolysis (acidic, alkaline and neutral), oxidation, thermal stress and photolysis, in order to investigate its stability. Optimized LC-MS/MS method was validated as recommended by ICH Q2(R1) guideline with respect to the specificity, accuracy, precision, limits of detection and quantitation, linearity and robustness. Anisomycin exhibited high instability under alkaline and thermal (neutral hydrolysis) conditions. It showed moderate stability under acidic, neutral, oxidative, thermal (acidic hydrolysis) and photolytic conditions, with the lowest degradation level observed in the case of light and oxidation stress. Formation of the same degradation product, identified as deacetylanisomycin, was observed under all applied stress conditions.

Developed and validated stability indicating HPLC method for the determination of epirubicin in bulk drug, marketed injection and polymeric nanoparticles

Present work is aimed to develop a simple, sensitive, robust and reliable HPLC method for routine quality control of epirubicin (EPI) in bulk drug, marketed injections and polymeric nanoparticles. Separation was carried out by C18 column. Isocratic elution was carried out using mobile phase A: 0.16% o-phosphoric acid solution, B: acetonitrile and methanol mixture (80:20, v/v) in the ratio of 60:40 (A: B) while the flow rate was maintained at 1mL/min. Analyses were performed at 233.5 nm using PDA detector. Excellent linear relationship was observed between peak-area versus drug concentration in the range of 1.0-100.0 µg/mL (r2, 0.999). Developed method was found to be sensitive (Limits of detection and quantification were found to be ~8 ng/mL and ~25 ng/mL, respectively), precise (RSD <1.0%, for repeatability and <2.0% for intermediate precision, within acceptable ranges of precision), accurate (recovery in different dosage form, 94.65 -100.26%, within acceptable range, 80-120%), specific and robust (% RSD <2, for system suitability parameters). Stress-induced degradation studies demonstrated that method can suitability be applied in the presence of degradants. Developed method has been successfully applied for the determination of entrapment efficiency, drug loading, in vitro release profile, in vitro permeation studies as well as stability assessment of polymeric nanoparticles

Development and validation of a stability indicating method for quantification of the sesquiterpene lactone eremantholide C from Lychnophora trichocarpha (Brazilian arnica)

ABSTRACT Pharmacological activities as anti-inflammatory, anti-hyperuricemic, anti-gouty arthritis, antitumor and trypanocidal activities of the aerial parts from Lychnophora trichocarpha (Spreng.) Spreng. ex Sch.Bip., Asteraceae (Brazilian arnica) have already been proved. Eremantholide C is a sesquiterpene lactone and one of the active chemical constituents responsible for these activities presented by L. trichocarpha. Therefore, the aim of this work was to develop and validate a stability indicating HPLC method for eremantholide C. Eremantholide C stability was evaluated in L. trichocarpha ethanolic extract and in its isolated form. Analytical conditions employed C18 column, acetonitrile/water in gradient elution, flow of 0.8 ml/min at 30 ºC. To correct for the loss of analyte during sample preparation the use of coumarin as an internal standard was necessary. The developed method provides good separation and resolution of the peaks, allowing quantification of eremantholide C, isolated or directly in the ethanolic extract, in internal standard presence. Validation results showed that this method is linear in the concentration range 2-180 µg/ml, precise, accurate and specific. Stability studies showed that L. trichocarpha ethanolic extract and eremantholide C remain stable for 6 months when stored at room temperature and impermeable glass bottle, therefore they can be used safely and effectively within this period. While at 40 ºC there was stability loss, at 8 ºC a stability increase was observed for the extract and the isolated eremantholide C. Forced degradation studies showed that eremantholide C degraded under acidic and alkaline conditions and was stable for three days under neutral and oxidative conditions, and when exposed to high temperature. Thus, with the development of a stability indicative method and the application of it in eremantholide C stability studies, the results can guide the development of new products that adequately preserve the original features of the biologically active substance with quality, safety and efficacy.

A comprehensive stability-indicating HPLC method for determination of chloroquine in active pharmaceutical ingredient and tablets: Identification of oxidation impurities.

Malaria is the most common parasitic disease in humans. It is estimated that 3 billion people live under the risk of contracting this disease in the world. Chloroquine (CQ) is the drug of choice to treat cases of non-complicated malaria. Forced degradation studies are important to know the drug's potentials degradation products and to develop a stability indicating method. Thus, chloroquine active pharmaceutical ingredient (API), chloroquine tablets and placebo were submitted to a detailed forced degradation study, using several stressing agents. The results were used on the development of a stability indicating method, using high performance liquid chromatography. The method was validated showing selectivity, precision, accuracy, robustness and linearity in the range of 30-360µg/mL of chloroquine. Chloroquine API and tablets were susceptible to alkaline hydrolysis with NaOH 1mol/L, and to oxidation with H2O2 3.0%. Two degradation products were formed in oxidative test. Kinetics of chloroquine degradation in alkaline hydrolysis was performed for both API and tablets. The calculated decay constant (k1) was 0.223days-1 for API and 0.182days-1 for tablets, while the half-life (t1/2) was 3.1days for API and 3.8days for tablets. Chemical structures have been proposed for the two degradation products formed in the presence of H2O2, using an UHPLC-UV-MS/MS approach.

Stability-indicating UHPLC method for determination of nevirapine in its bulk form and tablets: identification of impurities and degradation kinetic study.

Nevirapine (NVP), a non-nucleoside reverse transcriptase inhibitor, is a drug widely used in the treatment of Acquired Immunodeficiency Syndrome (AIDS). The evaluation of NVP stability is of fundamental importance in order to guarantee drug product efficacy, safety and quality. In this study, NVP active pharmaceutical ingredient (API) and tablets were subjected to a detailed study of forced degradation, employing several degrading agents (acid, alkaline, water, metal ions, humidity, heat, light and oxidation agents). In order to determine NVP and the degradation products formed, a stability-indicating UHPLC method using fused core column was developed and validated. The separation was carried out using a Poroshell 120C18 column (100×2.1mm i.d.; 2.7µm particle size) and the mobile phase was composed of acetonitrile and water in a gradient elution, at a flow rate of 0.2ml/min. Chemical structures and mechanisms for the formation of three degradation products were proposed by means of LC/MS-MS. Also, NVP degradation kinetic was studied and its order of degradation evaluated. NVP was degraded in acidic and oxidative conditions and the degradation profile for NVP tablets and API were similar. The stability-indicating method proved to be selective for NVP and its degradation products. Calibration curve was linear in the range of 8-48µg/ml and the method showed to be precise, accurate and robust for both NVP API and tablets, with detection and quantification limits of 0.092µg/ml and 0.174µg/ml, respectively.

Structural elucidation of gemifloxacin mesylate degradation product.

Gemifloxacin mesylate (GFM), chemically (R,S)-7-[(4Z)-3-(aminomethyl)-4-(methoxyimino)-1-pyrrolidinyl]-1-cyclopropyl-6-fluoro-1,4-dihydro-4-oxo-1,8-naphthyridine-3-carboxylic acid methanesulfonate, is a synthetic broad-spectrum antibacterial agent. Although many papers have been published in the literature describing the stability of fluorquinolones, little is known about the degradation products of GFM. Forced degradation studies of GFM were performed using radiation (UV-A), acid (1 mol L(-1) HCl) and alkaline conditions (0.2 mol L(-1) NaOH). The main degradation product, formed under alkaline conditions, was isolated using semi-preparative LC and structurally elucidated by nuclear magnetic resonance (proton - (1) H; carbon - (13) C; correlate spectroscopy - COSY; heteronuclear single quantum coherence - HSQC; heteronuclear multiple-bond correlation - HMBC; spectroscopy - infrared, atomic emission and mass spectrometry techniques). The degradation product isolated was characterized as sodium 7-amino-1-pyrrolidinyl-1-cyclopropyl-6-fluoro-1,4-dihydro-4-oxo-1,8-naphthyridine-3-carboxylate, which was formed by loss of the 3-(aminomethyl)-4-(methoxyimino)-1-pyrrolidinyl ring and formation of the sodium carboxylate. The structural characterization of the degradation product was very important to understand the degradation mechanism of the GFM under alkaline conditions. In addition, the results highlight the importance of appropriate protection against hydrolysis and UV radiation during the drug-development process, storage, handling and quality control.