Search Results (2,381)

Morocco’s recent legalization of industrial and medicinal cannabis has created a rapidly expanding seed-oil sector whose sustainability has yet to be fully assessed. This study applies an environmental life cycle assessment (LCA) in accordance with ISO 14040:2006 and ISO 14044:2006, complemented by a qualitative social responsibility assessment based on ISO 26000:2010, aiming to evaluate the life cycle sustainability of Moroccan cannabis seed oil. Three representative processing chains, traditional artisanal presses, producer cooperatives and regulated industrial plants are compared using a functional unit of 1 kg of cold-pressed oil packaged for local distribution. Inventory data were drawn from field measurements and interviews and were modeled in OpenLCA with background datasets from Ecoinvent 3.8 and Agribalyse v3.1. Impact assessment used the ReCiPe 2016 (H) method at the midpoint level across nine categories (climate change, fossil resource scarcity, water use, freshwater eutrophication, terrestrial acidification, land occupation, carcinogenic, non-carcinogenic human toxicity, and fine particulate matter formation). Sensitivity analyses varied seed yield, electricity mix and transport distances by ±20% to gauge uncertainty. Results show that the cooperative scenario achieves the lowest impacts across nearly all categories because of higher extraction yields (3 kg seed per kg oil), lower energy use (0.54 kWh kg⁻¹ oil) and more effective co-product recovery. In contrast, artisanal extraction requires approximately 1 kg of additional seed input per functional unit compared to optimized scenarios, significantly increasing upstream environmental burdens and causing upstream agricultural burdens to multiply. Industrial facilities perform comparably to cooperatives if powered by renewable electricity. Integrating a semi-quantitative social responsibility assessment reveals that legalization has markedly improved organizational governance, labor conditions, consumer protection and community involvement. Cooperatives display the most balanced social performance, whereas industrial plants excel in governance and quality control. A set of recommendations, including drip irrigation, cultivar improvement, co-product valorisation, renewable energy adoption, eco-designed packaging and cooperative governance, is proposed to enhance the environmental and socio-economic sustainability of Morocco’s emerging cannabis seed-oil industry. Full article

Background: Astragalus membranaceus Fisch. ex Bunge has long been used in East Asian medicine for gastrointestinal disorders and immune modulation. Astragaloside IV (AS-IV), a major bioactive saponin from its roots, exhibits potent anti-inflammatory and antioxidant activities, yet its protective effects against inflammatory bowel disease (IBD)-associated multi-organ damage via the gut–liver–brain axis remain unclear. Methods: Experimental colitis was induced in C57BL/6N mice by administering 5% dextran sulfate sodium (DSS) in drinking water for seven days. AS-IV (100 mg/kg/day) was orally administered during DSS exposure. Disease severity was evaluated using body weight, colon length, disease activity index, and histopathology. Inflammatory cytokines and oxidative stress markers were measured using ELISA, and NF-κB and MAPK signaling were analyzed through Western blotting and immunohistochemistry in colonic, hepatic, and brain tissues. Results: AS-IV significantly alleviated DSS-induced weight loss, disease activity, and colon shortening, while improving intestinal histopathological damage. AS-IV also reduced systemic pro-inflammatory cytokine levels and oxidative stress. Mechanistically, AS-IV was associated with a reduced expression of phosphorylated NF-κB and MAPK proteins, including p-NF-κB, p-IκBα, p-ERK, p-JNK, and p-p38, across the colon, liver, and brain. Conclusions: AS-IV attenuates DSS-induced multi-organ inflammation via gut–liver–brain axis modulation through NF-κB and MAPK pathway inhibition in experimental colitis models. Full article

Background/Objectives: Gastro-resistant multiparticulate systems are designed to protect drugs in acidic environments and to ensure intestinal release. In practice, the method of administration may need to be modified: pellet-containing capsules opened or tablets halved for patients with swallowing difficulties, yet the type of liquid used for administration is often not specified. This study examined the stability of gastro-resistant coated pellets after exposure to various aqueous media prior to ingestion. Methods: To evaluate administration instructions, 103 Summaries of Product Characteristics of gastro-resistant products were reviewed. Pellets were produced using a bottom-spray fluidized bed process and coated with Eudragit L 30 D-55. Dissolution testing in pH 1.2 medium was performed after pre-soaking the pellets for 5, 15, and 30 min in beverages with various pH and conductivity. Drug release was measured by UV-VIS method, and morphological changes were assessed by image analysis. Marketed gastro-resistant products were also examined visually. Results: SmPC review revealed that the beverage for intake was frequently unspecified. Among the tested beverages differences in pH and conductivity were observed. Alkaline medicinal mineral waters induced increased and time-dependent premature drug release compared to tap and filtered water. Image analysis indicated a reduction in surface area after exposure to alkaline media. Conclusions: Contact with non-specified aqueous media before swallowing may weaken the protective function of gastro-resistant films. More explicit recommendations on suitable administration manipulation and media may improve therapeutic consistency. Full article

The increasing utilization of radiation in medicine, industry, and water purification highlights the need for efficient radiation-protection materials. This study investigates lead-free polymer composites based on high-density polyethylene (HDPE) filled with four metallic fillers: tungsten carbide (WC), molybdenum carbide (MoC), tungsten (W), and molybdenum (Mo) at 15 wt%. The objective is to evaluate their potential as alternatives to lead for shielding ionizing radiation. Mechanical performance was examined through tensile testing, while thermal stability was assessed based on the residual mass. Radiation-attenuation behavior was analyzed through linear and mass attenuation coefficients (µ and µₘ), radiation protection efficiency (RPE), half-value layer (HVL), mean free path (MFP), buildup factors (B), and effective atomic number (Z_eff) within the 47.9–248 keV energy range. The HDPE/W composite exhibited the greatest enhancement, with a mass attenuation coefficient (µₘ) 82.5% higher than that of pure HDPE, along with the highest linear attenuation coefficient (µ). Furthermore, tungsten-loaded samples achieved an RPE of 98.05% at 47.9 keV. The increased density, low B, and high Z_eff values collectively contribute to superior shielding performance. These findings indicate that HDPE filled with WC, MoC, W, and Mo are promising lead-free candidates for low-energy X-ray shielding applications. Full article

Kaurenoic acid (KA) is an ent-kaurane diterpenoid present in several medicinal plant species and has been reported to exhibit anti-inflammatory, cytotoxic, and analgesic activity in experimental models. Despite its pharmacological profile, the development of KA as a therapeutic agent has been hindered by its unfavorable physicochemical and biopharmaceutical properties. KA is highly lipophilic and poorly soluble in water, which limits its dissolution, systemic exposure, and oral bioavailability. These limitations are common among plant-derived bioactive compounds and pose significant challenges for clinical development. Lipid-based nanocarrier systems, particularly liposomal formulations, have therefore been investigated as potential delivery strategies for improving the biopharmaceutical performance of KA. Encapsulating KA within phospholipid bilayers can improve its apparent solubility, protect it from degradation, and modify its biodistribution compared to the free compound. In this review, we discuss the pharmacological mechanisms of KA, its physicochemical properties, and the biopharmaceutical barriers to its therapeutic development. We also critically evaluate published studies on nanocarrier-based formulations, focusing on encapsulation efficiency, particle size, release properties, and pharmacokinetics (PK). Additionally, regulatory and pharmaceutical considerations relevant to lipid-based delivery of KA are addressed. Available evidence supports lipid-based nanocarriers as a promising strategy to improve preclinical development and formulation performance of poorly soluble plant bioactives such as kaurenoic acid. Although KA-loaded nanocarriers demonstrate encouraging activity in preclinical models, comprehensive pharmacokinetic and safety evaluations remain necessary before clinical development can be realistically considered. Full article

Background: Stable isotope-based analytical methods have brought about a significant transformation in the study of energy nutrient metabolism, enabling precise in vivo measurement of metabolic fluxes at systemic, tissue, and organ-specific levels in both healthy and diseased states. The regulation of these metabolic fluxes is governed by dynamic interactions between proteins, lipids, carbohydrates, and their precursors—such as glucose, fatty acids, and amino acids—as well as final metabolic products. Discussion: Advanced analytical technologies, including nuclear magnetic resonance (NMR) spectroscopy and mass spectrometry (MS), which can offer enhanced precision, have been developed for investigating nutrient metabolism and fluxes in humans, providing precise information on metabolic pathways. These techniques have primarily utilized stable isotopes, such as ²H, ¹³C, ¹⁵N, and ¹⁸O, which have largely replaced radioactive isotopes and are now central to metabolic research. These isotopes have been used to label glucose, fatty acids, or amino acids—the main biomolecular precursors—enabling detailed investigation at systemic, tissue, and organ-specific levels of carbohydrate, lipid, and protein metabolism, and revealing pathway alterations associated with diseases conditions, such as diabetes, non-alcoholic fatty liver disease, cardiovascular disorders, and cancer. The use of deuterium oxide (D₂O) has allowed for long-term metabolic studies, providing a cost-effective and less invasive means to monitor metabolic changes over days to months. Total daily energy expenditure can be measured in free living conditions by the doubly stable isotopes ²H- and ¹⁸O-labeled water method. Stable isotope tracing, combined with advanced imaging and modeling, has also been instrumental in assessing body composition, energy expenditure, and nutrient bioavailability. Collectively, these methods have expanded our understanding of human physiology and disease, supporting the development of novel diagnostic tools, the identification of new biomarkers, and the tailoring of nutritional and therapeutic interventions. Conclusions: This review aimed to provide an overview of the applications of stable isotopes for the study of energy nutrient metabolic pathways. The ongoing integration of stable isotope approaches with artificial intelligence, omics technologies, and miniaturized detection techniques could promise to further refine our understanding of human metabolism and drive advances in personalized medicine. Full article

Healing skin wounds is still difficult in many clinical situations, especially when the wounds are chronic or infected. These wounds often stay inflamed for long periods, and the risk of bacterial invasion is high. Oxidative stress tends to increase as well, while the formation of new blood vessels is often inadequate. Because of these factors, wound repair depends on the proper coordination of several biological events. These include basic antimicrobial activities, the control and resolution of inflammation, protection against oxidative damage, the rebuilding of collagen structures, and the development of new vascular networks. Traditional Chinese Medicine (TCM) provides many active compounds. These compounds work on many targets and through different pathways. They show good potential in wound treatment. But many TCM compounds have poor solubility in water. They are also unstable, have low bioavailability, and do not pass through the skin easily. These problems limit their use in clinical settings. Nanotechnology offers new ways to solve these problems. Nanodelivery systems can improve the solubility and stability of active compounds. They can also help the compounds enter the skin and stay in the wound area. Many types of nanocarriers have been developed, such as liposomes, polymer nanoparticles, nanogels, and inorganic nanomaterials. These systems can also provide controlled release or release that responds to the wound environment. This can make the treatment more accurate. In this review, we summarize how major TCM-derived compounds support wound repair and describe the biological mechanisms behind their effects. We also discuss recent nanodelivery approaches that aim to strengthen these therapeutic actions. These combinations can improve antibacterial performance, shape the immune response, reduce reactive oxygen species, and help the skin close more quickly. We also point out several challenges, such as concerns about material safety, the need for more consistent herbal extraction methods, gaps in mechanistic understanding, and the difficulty of producing these formulations on a large scale. Taken together, these points suggest that nanodelivery approaches using TCM-derived compounds still need more careful study and steady improvement before they can be used more widely in wound care. Full article

Aquaporins (AQPs) are transmembrane channel proteins that transport water and small solutes. Their dysregulation in cancer reveals functions beyond maintaining osmotic balance. This review summarizes that AQPs drive tumor progression through three core mechanisms: metabolic reprogramming, enhanced motility, and remodeling of the immune microenvironment. Specifically, AQP3, AQP7, and AQP9 serve as metabolic hubs for glycerol, while AQP3 and AQP8 help maintain redox homeostasis. AQP1 and AQP4 facilitate cell migration via hydrodynamic mechanisms, and AQP5 promotes invasion through signaling pathways such as Ras/NF-κB. In immune regulation, AQP9 and AQP3 modulate immune cell function by transporting metabolites, and AQP1 influences angiogenesis. Other isoforms, including AQP0, AQP2, AQP6, AQP10, and AQP11, also play roles in malignancy. Collectively, AQPs form a multifunctional network linking tumor metabolism, physical properties, and immunity, offering insights for novel diagnostic and therapeutic strategies. However, tissue-specific functions, complex regulatory mechanisms, and challenges in developing targeted therapies remain significant hurdles in translational medicine. Full article

Background: Apocynum venetum L., a saline–alkali-tolerant plant, is a valuable resource for forage, textile, and medicinal purposes. This study aimed to identify the AQP gene family in A. venetum genome-wide and explore their potential functions under abiotic stress. Methods: Gene identification, phylogenetic relationships, structural features, and evolutionary patterns were analyzed, along with gene expression patterns and correlations with physiological traits. Results: Phylogenetic analysis classified the 25 candidate AvAQP genes into five distinct subgroups, with members exhibiting conserved gene structures, motifs, and phosphorylation patterns. Subcellular localization predictions indicate targeting primarily to the plasma membrane or the vacuole, with one isoform (AvTIP5;1) predicted to localize to both. Synteny analysis revealed three intraspecific and multiple interspecific gene pairs (26 with Arabidopsis thaliana and 34 with Medicago truncatula). In silico promoter analysis identified 49 cis-regulatory elements associated with phytohormone response, stress signaling, and development, providing preliminary clues for their possible involvement in diverse biological processes. qPCR profiling under abiotic stress demonstrated tissue-specific expression patterns among AvAQP members under different stress conditions. Correlation analyses between gene expression and physiological indicators (growth- and water-related traits) were predominantly positive, with only a few negative correlations under stress conditions, suggesting that AvAQP expression may be associated with plant physiological status. Conclusions: This study presents a comprehensive analysis of the AQP family in A. venetum providing a foundation for further functional characterization of these genes in response to abiotic stress. Full article

Background: Chronic Obstructive Pulmonary Disease (COPD) is a common condition that can cause dyspnea, pain, and biomechanical-postural alterations, especially when overlapping with Myofascial Pain Syndrome (MPS). Balneological rehabilitation medicine can help manage COPD and MPS, but it lacks homogeneity and detailed descriptions of effective therapeutic protocols. Therefore, we conducted a case series to preliminarily evaluate the clinical effects of a detailed and codified approach, called Bio-Physico-Metric Integrated Thermal Care (BPM-ITC), for COPD+MPS. Methods: 10 patients were observed while undergoing 20 sessions of BPM-ITC in 4 weeks. Patients were assessed before and after the protocol using the Medical Research Council (MRC) dyspnea scale, Numeric Pain Rating Scale (NPRS), and the Bio-Postural Questionnaire (BPQ) for bio-physical health status. Treatments included manual therapy of key myofascial trigger points combined with crenotherapy, steam inhalations, mud therapy, vascular path, and water-based motor re-education. Results: At the end of the protocol, clinically relevant improvements were observed in almost all parameters considered in single observed cases; overall statistical analysis of the data highlighted significant positive effects in concomitance with the BPM-ITC protocol. Conclusions: The BPM-ITC protocol was followed by significant clinical improvements in the observed cases, suggesting its potential as a complementary approach for COPD+MPS. Further studies on this topic are recommended. Full article

The purpose of this work is to investigate the binding state of inorganic elements to flavonoid components in aqueous extract of Silybum marianum (SM) seeds, as well as the antioxidant activity of the extract. This study employed reversed-phase high-performance liquid chromatography (RP-HPLC) to separate silymarin flavonoids in boiling water decoction of SM seeds, and collected the post-column effluent in the segments according to the retention time of seven main silymarin flavonoid components. Inductively coupled plasma mass spectrometry (ICP-MS) was subsequently utilized to quantify nine inorganic elements (As, Cd, Co, Cr, Cu, Fe, Mn, Mo, Zn) in the collected HPLC fractions of the decoction. Meanwhile, electron paramagnetic resonance spectroscopy (EPR) was employed to assess the free radical scavenging activity of aqueous extract of SM seeds, using the signal intensity changes of 2,2-diphenyl-1-picrylhydrazyl (DPPH) and DMPO-OH• adducts as quantitative metrics. The results showed that essential trace elements (Cu, Fe, Mn, Zn) mainly existed as inorganic ions or strong polar forms in the tea-like infusion, with weak binding to flavonoid compounds. On the other hand, the aqueous extract exhibited significant •OH scavenging capacity, with a scavenging rate of 95% against •OH generated by continuous 5 min ultraviolet irradiation of H₂O₂ aqueous solution. This study provides experimental evidence for the development of SM as a food–medicine dual-purpose resource, proposing that consumption of SM seed tea represents a facile and effective approach to supplement trace elements and intake silymarin for enhancing endogenous antioxidant defense. Full article

Medicinal hemp (Cannabis sativa L.) has gained global attention due to its high-value phytocannabinoids, particularly cannabidiol (CBD) and tetrahydrocannabinol (THC), which exhibit significant therapeutic potential. Protected cultivation offers a climate-resilient and sustainable strategy to optimize hemp production by controlling environmental factors, ensuring year-round supply, and improving quality attributes. This paper outlines the key principles and technologies for protected hemp cultivation, including light spectrum management, temperature and humidity control, CO₂ enrichment, nutrient and water management, pest and disease suppression, and post-harvest handling techniques. Advanced greenhouse and indoor production systems enable precise regulation of microclimate, reduce crop losses, and enhance cannabinoid and terpene profiles compared to open-field production. The integration of smart technologies and autonomous control systems can further enhance operational efficiency and consistency. The paper concludes that protected cultivation systems represent an effective approach to overcome climatic uncertainties and meeting the increasing demand for medicinal hemp production on sustainable grounds. Full article

Pueraria lobata (Willd.) Ohwi root is a traditional medicinal resource rich in bioactive isoflavonoids with known antioxidant and anti-inflammatory properties. However, the chemical composition and biological activities of P. lobata root extracts can vary depending on the extraction solvent. In this study, we systematically compared P. lobata root extracts prepared using water, ethanol (30%, 70%, and 100%), and methanol to evaluate the effects of solvent selection on extraction yield, HPLC-based chemical profiles of major isoflavonoids, antioxidant capacity, and cellular responses in vitro. Chemical characterization by HPLC revealed distinct solvent-dependent differences in the relative abundance of key isoflavonoids, including puerarin, daidzin, and daidzein, defining characteristic chemical profiles for each extract. Antioxidant activity was evaluated using DPPH and ABTS radical scavenging assays, along with measurements of total polyphenol and flavonoid content. Cell viability was examined in HeLa cells using an MTT assay to define non-cytotoxic concentration ranges. The anti-inflammatory potential of the extracts was further assessed by measuring TNF-α-induced secretion of pro-inflammatory cytokines in HeLa cells. The results revealed marked solvent-dependent differences in extraction yield, chemical composition, and functional activity. Notably, methanol and ethanol extracts exhibited enriched isoflavonoid profiles associated with enhanced antioxidant and anti-inflammatory responses. Overall, this integrated chemical and functional evaluation demonstrates that solvent selection plays a critical role in determining the chemical characteristics and bioactivity of P. lobata root extracts. These findings provide a basis for rational solvent selection in the preparation of plant-derived extracts and support the potential use of P. lobata root as a functional source of antioxidant and anti-inflammatory compounds. Full article

Terminalia arjuna (Arjun) is a tropical deciduous tree species significantly valued for its pharmaceutical properties for various heart diseases, as well as its economic role in the sericulture industry. However, the growth performance and physiological responses of T. arjuna under water stress conditions remain largely unexplored, particularly in the context of increasing climate variability and the growing challenges posed by climate change. Therefore, this study aimed to examine the morpho-physio-biochemical alterations, nutrient uptake changes, and adaptive strategies under different degrees of water stress with respect to field capacity ($F_{wc}$), maintained at 100% $F_{wc}$ (control), 75% $F_{wc}$ (mild), 50% $F_{wc}$ (moderate), and 25% $F_{wc}$ (severe). Key growth parameters, including shoot and root length, leaf traits and shoot dry biomass, were significantly (p < 0.05) reduced under the given water stresses. Root dry biomass showed a distinct response, increasing under mild to moderate water stress but failing to sustain its levels under severe stress. Increasing drought severity resulted in a substantial reduction in stomatal density (15–37%), while stomatal size increased (18–49%) under mild to moderate stress but decreased under severe stress. These responses were associated with significant reductions in gas exchange traits (45–75%), whereas water use efficiency increased by 59–99%, reflecting a survival-focused adaptive mechanism. Moderate water stress triggered the stress responses in T. arjuna through high proline accumulation and increased oxidative stress markers. The most critical impact was found under the severe stress with a substantial reduction in leaf relative water content and membrane stability index (MSI), although MSI was sustained above the critical threshold, reflecting cellular protection. Increased stress intensity also altered mineral uptake, decreased major nutrients, and increased potassium and calcium content, indicating an adaptive strategy. These findings suggest a threshold effect, where T. arjuna tolerates mild stress well and activates adaptive morpho-physiological mechanisms under moderate stress but shifts to survival-focused strategies under severe stress. The demonstrated tolerance of Terminalia arjuna to mild–moderate drought suggests that climate-resilient forestry policies and conservation programs should prioritize its cultivation and restoration in drought-prone landscapes while ensuring adequate water management to prevent severe stress and sustain its medicinal and economic benefits. Full article

Background: Fixed-dose combination drugs (FDCs) are combinations of two or more active ingredients in a single dosage form. These formulations have proven effective in combating the development of resistance in diseases such as tuberculosis and malaria. Despite the benefits observed in the aforementioned cases, fixed-dose antibiotics combinations (FDACs) are increasingly raising questions about their rationality. This is the case for several FDACs listed in the AWaRe classification as not recommended, which unfortunately remain available on the pharmaceutical market, particularly in low- and middle-income countries like the Democratic Republic of Congo (DRC). Objectives: To identify the essential medicines available in pharmacies open to the public in the city of Kinshasa and to assess their inclusion in the DRC’s National List of Essential Medicines (NLEM) and in the World Health Organization’s (WHO) List of Essential Medicines (LEM). The rationality of the FDACs circulating in the city of Kinshasa were also evaluated based on the 2023 AWaRe classification. Methods: A cross-sectional and descriptive study was conducted between February and October 2025 in Kinshasa. For this purpose, fifty registered pharmacies open to the public were selected by systematic random sampling as the research sample. Data collection consisted of completing a data collection form after we had provided the pharmacies’ owners with the necessary explanations regarding the importance of the study and guaranteed their anonymity. Results: The controlled FDACs encountered comprised 27 specialties across 15 different formulations. Out of 15 formulations, 12 (80%) were included on the WHO list of non-recommended antibiotics and were not included in the DRC’s NLEM nor in the WHO’s LEM. Some had been withdrawn from the market in their countries of manufacture. Of the 15 FDACs evaluated for their rationality and compliance, the injectable FDACs presented problems related to the relevance and completeness of information contained on their packaging. On their primary packaging, there was a significant difference in the expiration dates of the powder and sterile water for injection contained in the combination pack, ranging from 6 to 36 months. Furthermore, the secondary packaging lacked data related to the sterile water for injection contained in the combination pack. In addition, several medications contained the same therapeutic combination. For injectable FDAC, for example, the combination Ceftriaxone-Sulbactam was represented by eight medications. For oral FDACs, the combination Sulfamethoxazole-Trimethoprim was represented by seven medications. Globally, 100% of these drug combinations originated from India. Conclusions: Fifteen varieties of FDACs were available in Kinshasa, most of which (80%) were unsuitable. It is important that public health authorities address this situation and develop stricter guidelines for granting marketing authorizations, particularly for FDACs. Full article