Search Results (1,920)

This research aimed to develop a rapid, non-destructive, and accurate method for detecting adulteration in turmeric using Visible–Near-Infrared (UV/Vis and NIR) spectroscopy combined with machine learning algorithms. Spectral data from the samples were collected and analyzed in two ranges: 170–870 nm (UV/Vis) and 900–2170 nm (NIR). Four supervised learning algorithms, including Support Vector Machine (SVM), Linear Discriminant Analysis (LDA), the Multilayer Perceptron (MLP) neural network, and Decision Tree, were evaluated for modeling. To quantitatively assess model performance, we employed not only the accuracy metric but also complementary performance indicators including precision, recall, and the F1-score to provide a more comprehensive evaluation of classification effectiveness. The models developed in the 900–2170 nm spectral range demonstrated highly significant performance, with most models achieving 100% accuracy on the independent test set. To reduce data dimensionality and enhance computational efficiency, a hybrid feature selection method combining SVM with five algorithms—League Championship Algorithm (LCA), Genetic Algorithm (GA), Particle Swarm Optimization (PSO), Ant Colony Optimization (ACO), and Imperialist Competitive Algorithm (ICA)—was employed. Upon evaluation of each method, the SVM-LCA was selected as the optimal feature selection technique. This algorithm successfully extracted the most effective wavelengths with the highest correlation and lowest error, which maintained or improved the accuracy of the classification models. This study confirms the high potential of UV/Vis and NIR spectroscopy as rapid, non-destructive, and precise tools for detecting adulteration in turmeric. The findings can pave the way for the development of intelligent quality control systems in the food and pharmaceutical industries, playing a crucial role in ensuring consumer health and safety. Full article

The pharmaceutical development of cannabis-based medicinal products is challenged by significant variability in the quality, composition, and standardization of plant-derived active pharmaceutical ingredients (APIs). In Ukraine, despite recent legislative liberalization, a substantial shortage of standardized raw materials continues to limit the development of innovative dosage forms. This study analyses international practices among API manufacturers to identify technological parameters necessary to overcome domestic market barriers and support the implementation of advanced drug delivery systems. Content analysis was conducted on regulatory documentation, professional literature, and manufacturers’ technical specifications. Candidate evaluation followed predefined inclusion and exclusion criteria. The study assessed compliance with Good Manufacturing Practice (GMP) requirements, extraction and purification technologies, the extent of analytical characterization, and batch-to-batch reproducibility. Purposive sampling enabled a comparative analysis of various technological approaches. Marked heterogeneity was observed in API standardization and analytical control indicators among manufacturers. Possession of a GMP certificate was found necessary but may be insufficient to ensure the pharmaceutical equivalence of materials. Differences in extraction methods and purification levels may affect stability profiles, pharmaceutical development strategies, and risk management related to final product quality. The findings demonstrate that manufacturer selection is a critical decision point in pharmaceutical development, with substantiated supplier choice directly influencing dosage form development and regulatory compliance. Full article

The role of medicinal plants in primary healthcare and livelihoods around the world is both ancient and well-documented. Agathosma betulina (P.J. Bergius) Pillans, commonly known as ‘buchu’, has long been utilised in traditional medicine as a household remedy for various ailments and is also valued for its essential oils in the cosmetics and pharmaceutical industries. This study aimed to profile and quantify the secondary metabolites in buchu using ultra-performance liquid chromatography quadrupole time-of-flight combined with mass spectrometry (UPLC-QTOF-MS) techniques, whereby plant material from three distinct locations in the Western Cape Province, Groot Winterhoek, Citrusdal, and Cederberg, was collected. A total of 32 maker compounds were identified from buchu leaves. The results revealed a significant location-dependent variation in the accumulation of multiple classes of phytochemicals, including phenolic acids, flavonoids, saponins, terpenoids, oligosaccharides, vitamins, and steroids. Citrusdal samples had the most bioactive compounds compared to the Cederberg and Groot Winterhoek. Citrusdal had the highest flavonoid levels, while Cederberg samples were the richest in phenolic acids and Groot Winterhoek was dominant in iridoid glycoside levels. Principal component analysis (PCA) revealed distinct clusters corresponding to the three different regions, confirming chemical differences. Elucidating the distribution of secondary metabolites in this species may provide new information for possible medicinal and pharmacological uses, such as the creation of novel and enhanced organic medications and food products. These results will aid in selecting a buchu chemotype with optimal attributes for the intended therapeutic application, helping to protect wild populations from over-exploitation through cultivation. Full article

Background/Objectives: Pharmacists play an essential role in healthcare delivery across Europe, yet growing professional demands, organisational constraints, and evolving practice models may negatively affect job satisfaction and professional fulfilment. This study aimed to evaluate job satisfaction and professional perception among pharmacists across multiple European countries and to identify sociodemographic and workplace-related factors associated with these outcomes. Methods: A cross-sectional, web-based survey was conducted between October 2023 and January 2024 among licensed pharmacists from 17 European countries. Eligible participants were pharmacists employed in community pharmacies, hospitals, clinical pharmacy services, or the pharmaceutical industry. The questionnaire, developed and administered in English, collected sociodemographic and professional data and included two composite measures: the Job Satisfaction Scale (12 items) and the Pharmacist Professional Perception Scale (6 items). Responses were recorded using 5-point Likert scales. Descriptive statistics and inferential analyses were performed using SPSS version 27.0. Results: A total of 789 pharmacists participated (median age 40 years; 80.1% female). The mean job satisfaction score was 3.26 (SD 0.88), with the lowest scores related to staffing adequacy and salary, and the highest to collegial relationships. The mean professional perception score was 3.08 (SD 0.81), indicating moderate perceived professional recognition. Significant associations were identified between both scales and workplace setting, income level, employment status, geographical region, education, and professional experience (p < 0.05). Conclusions: In this multi-country convenience sample, pharmacists reported moderate levels of job satisfaction and professional perception, with variation across workplace and sociodemographic factors. These findings should be interpreted cautiously, as the sample is not representative of all European pharmacists; however, they suggest that staffing conditions, remuneration, professional recognition, and career development opportunities may be relevant areas for further investigation and policy attention. Full article

Volatile organic compound (VOC) emissions exhibit strong process-level heterogeneity, yet regional source characterization still commonly relies on sector-average profiles, introducing substantial uncertainty into source identification and control prioritization. In this study, process-resolved VOC source profiles were established for five representative industrial sectors in Deyang, a typical industrial city in the Chengdu–Chongqing region, including pharmaceutical manufacturing, industrial coating, chemical industry, food manufacturing, and the textile industry. A total of 19 organized emission samples were collected from 9 enterprises, and 123 VOC species were quantified. These measured profiles were further integrated with literature-derived profiles and a bottom-up emission inventory to construct an emission-weighted regional composite source profile for 17 major industrial sectors. An emission-based hydroxyl radical (OH) reactivity-weighted framework was then introduced to compare mass-dominant and chemically dominant VOC sources. The results showed pronounced process- and sector-specific differences in composition. Pharmaceutical manufacturing was mainly dominated by oxygenated VOCs (OVOCs), industrial coating by low-carbon halocarbons, the chemical industry by methanol and reactive low-carbon compounds, food manufacturing by alkenes and OVOCs, and the textile industry by light alkanes. At the regional scale, industrial VOC emissions were dominated by OVOCs (35.67%), followed by alkanes (19.01%) and aromatics (15.99%). Ethyl acetate, 1,4-dioxane, 1,1,2,2-tetrachloroethane, and m/p-xylene were identified as the most abundant species. However, OH reactivity was largely dominated by alkenes, and substantial discrepancies were observed between emission contribution and OH-reactivity-weighted contribution across sectors. In particular, the chemical industry contributed 21.10 ± 8.43% of reactive organic gas emissions but 28.82 ± 11.61% of OH-weighted emissions, whereas printing contributed 13.55 ± 13.42% of mass emissions but only 7.66 ± 13.08% of OH-weighted emissions. These findings demonstrate that regional VOC management should move beyond bulk mass reduction and prioritize high-reactivity sectors and process units to maximize O₃ mitigation benefits. Full article

The paper describes the preparation of silver-containing nanocomposites by thermolysis of silver cinnamate and their application for the manufacture of reactive indicator paper (RIP) sensitive to iodine. The composition, structure, and properties of the obtained materials were studied using IR spectroscopy, X-ray diffraction, the gravimetric analysis method, scanning electron microscopy, transmission electron microscopy, and energy-dispersive X-ray spectroscopy. Optimal conditions for modifying a cellulose carrier with nanocomposites in laboratory conditions were selected, ensuring high sensitivity of RIP to iodine and uniform and reproducible distribution of the reagent. A new gas extraction colorimetric technique for determining iodide ions in the range of 0.03–1.6 mg L⁻¹ (limit of detection 0.01 mg L⁻¹) was developed, allowing iodides to be determined in multicomponent objects such as food products, pharmaceuticals, and various water bodies with minimized sample preparation. The use of iron(III) as an oxidizing agent and the use of dynamic gas extraction ensure high selectivity and good analytical performance. Full article

Nyaope is a highly addictive street drug that is widely used in South Africa, particularly in urban and peri-urban settings. Although it is traditionally consumed by smoking, increasing injection use has raised serious public health concerns due to an elevated risk of bloodborne viral infections and other drug-related health complications. The composition of nyaope is highly variable, frequently adulterated, and continually evolving, thus highlighting the need for detailed chemical characterization to support forensic investigations and public health interventions. An exploratory study design was conducted using eight nyaope samples seized from six sites within the City of Tshwane Metropolitan Municipality that were provided by the South African Police Service Forensic Science Chemistry Laboratory (SAPS-FSCL). Samples were analyzed using Ultra-High-Performance Liquid Chromatography coupled to Quadrupole-Time-of-Flight Mass Spectrometry (UHPLC-qTOF-MS) operated in data-dependent acquisition mode under positive ionization. Raw data from the methanolic extracts of nyaope was converted to mzML format and processed using SIRIUS software for compound annotation based on isotope pattern ranking and fragmentation analysis. Chemical profiling revealed multiple opiate-related compounds, including noscapine, heroin, papaverine, and codeine. Molecular networking revealed chemically diverse yet structurally related metabolites consistent with a poppy-derived botanical origin. In addition, multiple synthetic pharmaceutical adulterants were detected. Notably, one sample contained formaline, a toxic rodenticide structurally related to protopine, highlighting the risk of misidentification using less advanced analytical approaches. This study demonstrates the value of advanced computational metabolomics, including molecular networking and machine-learning-assisted mass spectrometry interpretation, for comprehensive characterization of complex illicit drug mixtures. These approaches enhance forensic accuracy and support informed public health and law-enforcement responses. Full article

Due to its abundant content of biologically active compounds, Althaea officinalis L. (marshmallow) has been extensively researched and applied in both the food and pharmaceutical industries. This study aimed to evaluate hydroethanolic and natural deep eutectic solvent (NADES) extracts from leaves, flowers, and roots in terms of their chemical composition and biological activities. Extracts were characterized using chromatographic and spectrophotometric methods. Phytochemical profiling by HPLC-MS revealed a diverse composition, with 35 secondary metabolites identified or tentatively assigned, mainly hydroxycinnamic acid derivatives and flavonoid glycosides. GC-MS analysis of the ethanol extracts identified ten free amino acids, seven organic acids, several mono- and disaccharides, and one oligosaccharide. Their concentrations varied across different parts of the plant depending on the specific metabolism of the respective organ. Ethanolic extracts showed the highest total phenolic content (up to 176 mg GAE/L), while flower extracts exhibited the strongest antioxidant activity (DPPH up to 89 µmol TE/L). The antimicrobial potential of the extracts was assessed by the agar well diffusion method. NADES1 extracts demonstrated significant antibacterial activity, with inhibition zones reaching up to ~34 mm, whereas NADES2 extracts were largely inactive. In contrast, antifungal activity was negligible or absent across all samples. Full article

Several issues about the quality of urban surface waters, such as the Detroit River, are becoming a concern due to the increasing detection of emerging contaminants. Although the emerging contaminants are present in low concentrations—ranging from nanograms per liter (ng/L) to micrograms per liter (µg/L)—these raise serious concerns about long-term effects on human health and aquatic ecosystems, particularly when left unregulated. Municipal wastewater effluent has been reported as one of the major pathways for these emerging contaminants. Most treatment plants are not equipped to effectively remove many emerging contaminants, allowing them to enter surface waters. To assess the presence of these emerging contaminants, water samples were collected during the summer from sites near the upstream and downstream of the Detroit wastewater treatment plant. Among the sixteen emerging contaminants analyzed were pharmaceuticals, personal care products, and pesticides. Ten of these, such as sucralose, caffeine, acetaminophen, and bisphenol A, were detected at both locations, with concentrations ranging from 42 to 4100 ug/L. Elevated contaminant levels found downstream can come from various sources, such as agricultural runoff, leachate from landfills, overland flow, and Combined Sewer Overflows (CSOs). Furthermore, local pharmaceutical usage patterns and the effectiveness of our treatment facilities play significant roles in the contaminant concentrations we see. Tracking emerging contaminants both upstream and downstream of treatment plants is crucial for pinpointing vulnerable watersheds. This vital information enables us to establish a solid baseline and craft effective strategies to lower contaminant levels. Full article

Species of the genus Prunus, including Prunus nipponica var. kurilensis, Prunus sargentii, and Prunus maximowiczii, are widely distributed in the Far Eastern region, covering the territories of Northern China, Korea, Japan, the Kuril Islands, Sakhalin Island, and Primorsky Region in Russia. As part of this study, the flowers of nine specimens of the aforementioned species were collected from the Peter the Great Botanical Garden of the Russian Academy of Sciences (RAS), which was founded in 1714 and is one of the oldest botanical gardens in Russia. This study is the first comprehensive metabolomic analysis of cherry blossoms from East Asia, with a particular focus on the varieties P. nipponica var. kurilensis, P. sargentii and P. maximowiczii. The main objective of the work was to identify and characterize biologically active polyphenolic substances and other chemotypes in the studied plant samples. Metabolomic analysis of flower extracts from three species of Prunus: P. nipponica var. kurilensis, P. sargentii, and P. maximowiczii revealed the presence of one hundred and eight polyphenol compounds and fourteen compounds belonging to other chemical groups. Principal component analysis showed that PC1 (26.6%) and PC2 (19.0%) explain 45.6% of the total variance. A clear separation of P. maximowiczii was observed, while P. nipponica from all regions was represented by a single species, and P. sargentii showed variability. Samples from Sakhalin were grouped separately. These results suggest that species identity and origin may influence the metabolic differentiation of the plant material studied. The observed separation of P. maximowiczii from other species may be due to both species-specific metabolism and adaptation to the environmental conditions in Sakhalin. A heatmap with hierarchical clustering revealed a clear clustering of samples based on their origin and species. Samples of P. sargentii from different sources were grouped together, indicating a similar metabolic profile. Samples of P. nipponica var. kurilensis formed a separate cluster with characteristic features of compound distribution. Samples of P. maximowiczii from Sakhalin also formed a separate cluster that was not related to the other two species. This supports the hypothesis that the subspecies that grow in the northern regions have a greater metabolic diversity. It is suggested that this richness of polyphenols is due to the harsh climatic conditions and the accompanying stress factors. The flowers of P. nipponica var. kurilensis, P. sargentii, and P. maximowiczii are characterized by a high content of biologically active compounds, which makes them promising objects for the creation of biologically active supplements and the development of new therapeutic agents in the pharmaceutical industry. Full article

Concerns about the environmental and health impacts of plasticized poly (vinyl chloride) (PVC), from plasticizer loss to microplastic formation, have created a clear demand to find alternative packaging materials for medical and pharmaceutical use. As a possible polyolefin-based alternative, we blended polypropylene–ethylene copolymers with different ethylene content-controlled phase structures with styrene–ethylene/butylene–styrene block copolymer (SEBS), as modifier. SEBS is elastomeric and performs mechanically like a cross-linked rubber due to its unique microphase-separated morphology of hard spherical polystyrene (PS) domains dispersed in the soft elastomeric ethylene-butylene copolymer (EB) phase. Tests with injection-molded samples and cast films demonstrated promising combinations of flexibility, durability, and transparency—qualities essential for soft medical packaging like infusion pouches and blow–fill–seal bottles. For the desired level of flexibility (reflected by a flexural modulus of 150–250 MPa), blends with two random-heterophasic (RAHECO) copolymers achieved the lower limit with only 15–25 wt.-% SEBS, compared to the 37 wt.-% needed for a single-phase random copolymer (RACO). These blends also exhibited greater toughness and excellent transparency. In contrast, a standard impact copolymer (HECO), with its more crystalline matrix, required a higher modifier content of 45 wt.-% SEBS. Film morphology analysis indicated a gradual shift in disperse phase structure and orientation, leading to phase inversion at the highest SEBS content without negatively affecting transparency. Full article

This study aims to evaluate the antioxidant and anti-inflammatory potential of dichloromethanic, methanolic and hydroalcoholic extracts of seventeen different selected Balkan medicinal herbs with ethnopharmacological interest, with the goal of identifying the most bioactive candidates for further investigation of their therapeutic efficacy in human diseases. A total of fifty-four extracts were initially screened; due to the high sample number, only the most active samples were advanced to subsequent assays in order to identify bioactive candidates with potential therapeutic efficacy in human diseases. The methanolic extract of Cotinus coggygria showed the highest radical scavenging activity (DPPH: 96.4% inhibition), the hydroalcoholic extract of Hypericum empetrifolium exhibited the most potent iron chelation (IC₅₀: 5.0 μg/mL) and the methanolic extract of Sedum sediforme presented the best anti-inflammatory activity in in vitro assays (LOX IC₅₀: 39.4 μg/mL, COX-1 inhibition: 93.1% and COX-2 inhibition: 94.0%). Furthermore, significant inhibition of tyrosinase and collagenase was observed for the methanolic extract of Cistus creticus (94.2% tyrosinase inhibition, 86.8% collagenase inhibition) and the methanolic extract of Cotinus coggygria (83.1% tyrosinase inhibition, 96.1% collagenase inhibition). In vivo, five promising plant extracts were selected and evaluated for their anti-inflammatory activity using a carrageenan-induced paw edema model in female C57BL/6 mice. The study aimed to assess the in vivo anti-inflammatory potential of these extracts under acute inflammatory conditions. The methanolic extract of Cotinus coggygria proved the most active, significantly reducing paw edema by 34% compared to the non-treated control, indicating a pronounced anti-inflammatory effect and supporting its potential as a source of bioactive compounds with therapeutic relevance. The results of this study indicate that several selected herbal extracts exhibit notable pharmacological activities. Given their antioxidant, anti-inflammatory, and inhibitory properties against enzymes related to skin function, these extracts warrant further in vivo and (pre)clinical investigation for potential use in cosmetic and pharmaceutical products targeting skin disorders associated with inflammation and oxidative stress. Full article

Respiratory syncytial virus (RSV) imposes a substantial burden of severe acute respiratory infection (SARI), especially in young children and the elderly. Methods: We describe RSV epidemiology among hospitalized SARI patients at the Ibn Sina University Hospital Center (Rabat, Morocco) from 1 January 2021, to 31 December 2025, using multiplex PCR (BioFire^® RP2.1plus or Xpert^® SARS-CoV-2/Flu/RSV). Results: Among 4604SARI samples, RSV prevalence was 16.1% (739/4604), predominantly pediatric (88.6%, p < 0.001), with peak burden in infants <6 months (70.4% of cases, p < 0.001). Pediatric prevalence was 28.3% (655/2316) vs. 3.8% (84/2204) in adults (p < 0.001), with predominance in the elderly ≥60 years (51/1041, 4.9%). Co-infections occurred in 46.7% (310/665) of FilmArray-tested positives (total = 665), led by rhinovirus/enterovirus (198/310, 63.9%), and were significantly higher in children (48.5%, p < 0.001). RSV peaked in winter (51.6%), except for summer dominance in 2021 (52.5%), reflecting COVID-19 non-pharmaceutical intervention effects. Conclusions: These data establish Morocco’s first comprehensive RSV surveillance baseline, highlighting post-pandemic epidemiological shifts. As maternal vaccines and monoclonal antibodies emerge, these data inform optimal implementation in low- and middle-income countries (LMICs). Full article

Tetracycline antibiotics are increasingly detected in aquatic environments because of their ecological risks and persistence, while conventional wastewater treatment processes are often insufficient for their effective removal from water. Here, we introduce a novel 3D graphene oxide-based nanocomposite that stacks Cu-NPs and amino-functionalized MIL-101(Fe) (denoted by Cu/NH₂-MIL-101(Fe)@GO) to effectively remove tetracycline (TC) and oxytetracycline (OTC) from environmental water samples. XPS, XRD, TEM, SEM, and FTIR analyses were conducted to characterize the structure and surface morphology of the Cu/NH₂-MIL-101(Fe)@GO nanocomposite. Overall, it was confirmed that GO, NH₂-MIL-101(Fe), and Cu-NPs were successfully incorporated, resulting in a porous material with high access to Cu-related sites as well as oxygen- and nitrogen-based functionalities (such as amino-, hydroxy-, and carboxy-groups). This hybrid system facilitates the adsorption by complementary mechanisms like surface complexation/chelation at Cu and Fe centers with the pH-dependent tetracycline species in electrostatic interactions, hydrogen bonding, π–π stacking, and molecule confinement in the metal–organic framework (MOF) pores, and by the synergistic effects at the GO–MOF(Fe)–Cu junction interfaces. The batch adsorption studies showed that the quick and efficient uptake of the two antibiotics at pH 6.5, with removal rates of 99.65–99.83%, was achieved by 15.0 mg of Cu/NH₂-MIL-101(Fe)@GO at an initial concentration of 20 ppm in 40 min at 25 °C. Equilibrium data were found to be well-fitted by the Langmuir isotherm (R² = 0.908–0.909), suggesting monolayer-dominated adsorption with the maximum capacity of 769.8–775.2 mg g⁻¹. The adsorption kinetics was well-described by the pseudo-second order model (R² = 0.9641–0.9749), which agreed with the strong binding between the tetracyclines and active sites of the nanocomposite. The main novelty of this work consists of the design of a single recoverable platform integrating GO-based preconcentration, pore accessibility of NH₂-MIL-101(Fe), and Cu-driven complexation, which led to the strong removal of tetracyclines under a relevant range of water conditions. These findings demonstrate that Cu/NH₂-MIL-101(Fe)@GO could serve as a promising high-efficiency and potentially reusable adsorbent for removing tetracycline from aqueous solution, which provides a more sustainable approach for pharmaceutical wastewater treatment. Full article

Snail mucus is increasingly investigated as a biologically compatible source of multifunctional biomolecules for pharmaceutical and dermatological use. However, the chemical profile and biological activities of mucus from the Moroccan endemic terrestrial snail Otala tingitana remain poorly characterized. In addition, the influence of heliciculture diet on the composition and functional properties of the mucus remains unclear. Here, O. tingitana was reared for 140 days under controlled conditions and fed a basal flour diet or the same diet supplemented with 3% Rosmarinus officinalis, Origanum compactum, or Thymus zygis subsp. zygis. Mucus from wild snails was included for comparison. Mucus samples were chemically profiled by GC–MS and evaluated for antibacterial activity, antioxidant capacity, wound-healing efficacy in mice, and histological anti-inflammatory effects, and evaluated semi-quantitatively based on the degree of inflammatory cell infiltration. GC–MS identified 13 compounds and demonstrated clear diet-dependent shifts in dominant components. All mucus samples exhibited broad-spectrum antibacterial activity against Staphylococcus aureus, Listeria monocytogenes, Escherichia coli, and Salmonella Typhimurium (inhibition zones 10.31–14.30 mm; MIC 120–240 µg/mL), with predominantly bactericidal profiles (MBC/MIC < 4) and significantly enhanced activity in plant-supplemented groups (p < 0.05). Antioxidant performance improved markedly with medicinal-plant supplementation, reaching low IC₅₀ values (best ≈ 1.18 mg/mL) compared with basal-diet mucus. In vivo, topical application accelerated wound closure, achieving complete healing in <21 days, versus 28 days in untreated controls. In addition, histological assessment showed faster resolution of inflammatory cell infiltration in treated groups. Collectively, these findings provide the first integrated evidence that O. tingitana mucus possesses antibacterial, antioxidant, wound-healing, and anti-inflammatory activities, and that heliciculture diet is a practical lever to optimize its bioactive profile. Further studies should prioritize standardized manufacturing, contaminant control, and safety/toxicology assessment before translational development. Full article