Search Results (876)

Cancer remains a leading cause of morbidity and mortality globally, with current therapies often limited by toxicity, drug resistance, and reduced efficacy in advanced stages. Medicinal plants represent important sources of bioactive compounds (BACs) with anticancer and chemopreventive potential; however, their successful application is strongly influenced by extraction strategies that determine phytochemical recovery and downstream biological activity. This review evaluates solvent-based extraction techniques used to extract BACs from medicinal plants with reported anticancer properties, synthesizing peer-reviewed articles from PubMed and Google Scholar published between 2020 and 2025. Solvent-based methods, including Soxhlet and maceration, were most widely applied due to their operational simplicity and the preservation of structurally diverse metabolites while percolation, decoction, infusion, and hydro-distillation were sparsely utilized. Extraction strategy and solvent polarity emerged as primary factors shaping phytochemical profiles, with phenolics, flavonoids, alkaloids, and terpenoids identified as dominant classes. Reported half maximal inhibitory concentration (IC₅₀) ranged from highly potent (0.12 µg/mL) to weak (30,000 µg/mL), reflecting variability driven by extraction parameters and plant matrix complexity. Anticancer mechanisms commonly involved apoptosis induction, cell-cycle arrest, reactive oxygen species-mediated cytotoxicity, and inhibition of proliferative signaling pathways across breast, cervical, colon, lung, liver, and prostate cancer models. Although solvent-based extraction approaches remain widely used, their context-dependent nature and lack of standardization limit reproducibility. Overall, anticancer and chemotherapeutic efficacy is primarily governed by BAC composition, while extraction methods act as upstream modulators. Future progress requires phytochemical-informed, standardized workflows supported by hybrid extraction systems, AI-assisted optimization, and advanced bioavailability and delivery systems to enable reproducible and clinically relevant translation of plant-derived chemotherapeutics. Full article

Research on academic achievement highlights the combined role of cognitive abilities and motivational beliefs. Grounded in the CHC framework, this study examined how three broad cognitive abilities—verbal, numeric, and spatial—and academic self-concept jointly predict achievement in Portuguese and mathematics. A sample of 3034 students from the third cycle (grades 7–9) and secondary education (grades 10–12) completed the BAC-AB cognitive battery and a validated academic self-concept scale. Using multigroup structural equation modelling, we tested whether the predictive patterns differed across educational stages. Academic self-concept emerged as the most consistent predictor across subjects and levels. Cognitive contributions displayed clear developmental differentiation: verbal ability was more strongly associated with Portuguese (and increasingly with Mathematics) in secondary education, whereas numeric and spatial abilities were comparatively more relevant for Mathematics in the third cycle. These patterns support the view that linguistic, quantitative, and visuospatial processes contribute to achievement in distinct and developmentally sensitive ways. Overall, the findings underscore the importance of instructional approaches that build on quantitative and spatial strengths in earlier grades while progressively supporting advanced verbal comprehension and reasoning in later schooling. Full article

Bactrocera dorsalis (oriental fruit fly) is a destructive invasive pest threatening global agriculture. Although integrated pest management is applied, environmentally friendly genetic control methods are urgently needed. The development of such methods particularly relies on efficient genetic elements. In this study, we compared the transient expression of mScarlet-I driven by various Actin and PUb promoters in B. dorsalis embryos. The truncation of two strong promoters, BdActA3a and BdPUb, revealed that the 5.0-kb BdActA3a and 3.6-kb BdPUb promoters drove significantly higher expression than their truncated variants. Notably, the BdPUb promoter was highly effective in driving fluorescent protein expression in B. dorsalis. Using the 3.6-kb BdPUb promoter, we constructed a transposase plasmid BdPUb-3.6 kb>hyPBase. By co-injecting the BdPUb 3.6kb>mScarlet-I donor construct, we successfully generated a fluorescent transgenic strain with a transgenic efficiency of approximately 26%. The strain exhibited stage-specific fluorescence and maternal effect and the homozygotes showed fecundity comparable to wild-type controls. The high performance of the piggyBac transposase and the fluorescence screening system provides a substantial technical foundation for basic research and future development of genetically modified strains to control B. dorsalis. Full article

Urban and peri-urban river systems subjected to intensive agriculture are vulnerable to diffuse metal(loid) inputs, yet the integration of hydrological compartments, bioindicators, and human health risk remains poorly explored. This study investigated the seasonal dynamics, bioaccumulation patterns, and potential human health risks associated with metal(loid)s in the Santa Virgem River (Brazil–Paraguay border), using water from backwater zones and three plant groups (Apiaceae angiosperms, mosses, and the liverwort Dumortiera sp.). Water and plant samples were collected during five seasonal campaigns (2019–2020) and analyzed by ICP OES. Multivariate analysis (PCA) was applied, and biological accumulation coefficients (BAC) and chronic daily intake (CDI) were estimated for adults and children under different ingestion scenarios. Results showed that Mg, Fe, K, S, and P dominated water chemistry, while As, Cd, Cr, Cu, Pb, and Se were mostly below detection limits. PCA explained 77.6% of total variance, distinguishing agricultural and hydrological phases. Bryophytes exhibited markedly higher BAC values, particularly for Mn (up to 2.3 × 10⁵) and Fe, compared with Apiaceae. CDI and hazard assessment indicated negligible non-carcinogenic risk for most elements (HQ < 1), except phosphorus, which dominated the Hazard Index due to its low reference dose. Overall, the results demonstrate that hydrodynamic conditions and plant functional traits jointly control metal(loid) dynamics, highlighting the value of multispecies biomonitoring in peri-urban river systems. Full article

Crocus sativus L. (saffron), a sterile geophyte of the Iridaceae family, has been traditionally used in culinary and medicinal practices and is currently gaining attention as a source of pharmacologically active metabolites. The main bioactive compounds (BACs) of saffron, crocin, crocetin, picrocrocin, and safranal, are associated with a wide range of biological activities, including anti-inflammatory, antioxidant, immunomodulatory, antimicrobial, antiproliferative, and antidiabetic properties, among others. This review aims to comprehensively and critically summarize the preclinical and clinical evidence for saffron-derived BACs in the context of the most prevalent non-communicable diseases. A literature search of the main scientific databases was conducted to identify peer-reviewed articles on neurodegenerative disorders, cancer, cardiovascular diseases, and diabetes mellitus, with additional topics on ethnopharmacology, phytochemistry, safety, and toxicity. The mechanistic findings include anti-inflammatory, immunomodulatory, antioxidant, antiproliferative, and neuroprotective effects, mediated by activation of the Nrf2 pathway and inhibition of NF-κB. Eligibility criteria were applied, excluding publications focused primarily on food, cosmetics, or technological applications, to prioritize mechanistic and therapeutic endpoints. The findings suggest that BACs from saffron extracts have promising disease-modifying properties and symptom-relieving actions, especially in the case of neurologic disorders, mild cognitive impairment, and some models of metabolic and oncological diseases. Nevertheless, the current variability in study design, dosage, standardization of plant extracts, and sample size limits a conclusive clinical application. More carefully designed studies with a representative number of cases and well-defined plant preparations are needed to validate efficacy, establish structure-activity relationships, and define the prevention and therapeutic potential of saffron in evidence-based pharmacotherapy. Full article

Sustainable indoor growing management requires biological alternatives that protect against pathogens, preserve fruit quality and minimise chemical inputs in strawberries. We compared the impacts of a four-strain Bacillus consortium (BacMix) and chemical fungicides on two cultivars (cv. Elsanta and cv. Sonsation) by evaluating the metabolite outcomes—the free amino acids (FAAs) in the leaves and the sugars in the fruits. Furthermore, the descriptive shotgun metagenomics provides a functional context for these biochemical traits. The BacMix increased the total FAAs in the leaves and stabilised the fruit sugar profiles, maintaining moderate–high sucrose with controlled glucose and fructose. The chemically treated plants showed significant reductions in both FAAs and sugars. The metagenomic data showed BacMix-related shifts in the microbial functional potential in the leaves, but the biological agent did not affect diversity. An increased representation of genes involved in amino acid biosynthesis (aminoacyl tRNA pathway) and secondary metabolite biosynthesis was observed, along with changes in the relative CAZy signals. The direction of these metagenomic trends aligned with the metabolite outcomes, suggesting that BacMix influences the endophytic microbiome in a way that supports nitrogen-related metabolism and carbohydrate stability during the vegetation period. The cultivar-independent metabolic improvements emphasise the benefits of BacMix and highlight microbiome-based interventions as promising tools for sustainable, chemical-reduced strawberry production. Full article

Textile wastewater contains recalcitrant azo dyes and auxiliary chemicals that are resistant to conventional biological treatment, resulting in persistent organic pollution in aquatic ecosystems. While supercritical water oxidation (SCWO) achieves superior chromophore mineralization, its high energy requirements limit industrial scalability. Conversely, biomass-derived activated carbon (BAC) offers a low-cost adsorption solution, but it rapidly becomes saturated with toxic oxidation intermediates. Notably, the literature lacks systematic analyses of hybrid SCWO-BAC systems with integrated thermal energy, which represents a crucial gap in assessing their economic feasibility. This review employed a systematic methodology, selecting studies relevant to the topic from peer-reviewed publications and databases, including Scopus, SciELO, ScienceDirect, and Google Scholar, for critical synthesis. Using SCWO as a pretreatment (which significantly reduces COD load), followed by BAC polishing, results in superior detoxification compared to individual processes. However, three barriers hinder scale-up: (i) chloride ion corrosion in real effluents; (ii) irreversible collapse of BAC pores after multiple regeneration cycles; and (iii) absence of standardized ecotoxicity data for hybrid-treated streams. This work outlines a technological roadmap for integrated supercritical water oxidation and biological activated carbon (SCWO-BAC) systems, targeting economically viable operational parameters for industrial-scale implementation. Full article

This study aimed to manufacture and characterize highly porous dressings based on gellan gum (GG) and sodium alginate (Alg) hydrogels modified with zinc oxide (ZnO) and bacitracin (BAC) intended for infected and exuding wounds. ZnO nanoparticles (ZnO(n)) were 26 ± 4 nm in size according to atomic force microscopy (AFM), while the size of the microparticles (ZnO(m)) was 1.02 ± 0.01 µm according to laser diffraction measurements. Their relative surface areas were 39.16 m²/g and 4.56 m²/g, respectively. Microbiological studies showed that ZnO(n) exhibited antibacterial activity in contact with the Gram+ Staphylococcus aureus; thus, they were selected for embedding in a hydrogel matrix. Four types of composite hydrogel samples were manufactured: GG/Alg, GG/Alg+ZnO, GG/Alg+BAC, and GG/Alg+ZnO+BAC, which were subjected to freeze drying. The water absorption of all materials exceeded 4000%, showing excellent liquid absorbability. Burst release of BAC was found at a level of 90% in the first 2 h. In vitro cytotoxicity studies on L929 fibroblasts did not show a toxic effect of extracts from the GG/Alg and GG/Alg+BAC samples, contrary to samples supplemented with ZnO(n). In microbiological studies, the enhanced antibacterial effect of ZnO(n) and BAC was observed in contact with Staphylococcus aureus and Staphylococcus epidermidis strains. Therefore, GG/Alg+BAC+ZnO is the most promising dressing system for the treatment of infected and exuding wounds. Full article

Background: Vaginal infections often present with overlapping symptoms and involve single or multiple pathogens. However, the relationship between clinical symptoms and molecularly defined vaginal pathogen profiles, especially in multi-pathogen infections, remains poorly characterized in a routine care setting. This study exams the connection between vaginal symptoms and pathogen profiles among women with vaginitis in Northern Vietnam. Methods: We conducted a multicenter cross-sectional study of women with vaginitis at Bac Ninh CDC and Hanoi Obstetrics and Gynecology Hospital between December 2023 and December 2024. Baseline demographics and clinical symptoms were assessed by physicians. Vaginal swabs were collected for pH measurement and pathogen detection using multiplex real-time PCR. The correlation was analyzed using logistic regression in GraphPad Prism v10.1.1. Results: Among 289 symptomatic women, abnormal vaginal discharge and itching were the most common symptoms. Gardnerella vaginalis was the most commonly detected pathogen, occurring alone or in combination with Candida albicans, Mycoplasma hominis, and other genital pathogens. Multi-pathogen infection was associated with abnormal vaginal discharge (OR = 5.44), itching (OR = 2.13), and elevated vaginal pH (OR = 4.70). Women at the tertiary hospital showed greater symptom burden (OR = 1.75) and higher prevalence of multi-pathogen infections (OR = 9.75) than those attending the provincial CDC. Conclusions: Multiplex real-time PCR combined with simple clinical indicators (symptom clustering and vaginal pH) provides practical diagnostic value for identifying multi-pathogen infections in symptomatic women. This integrated approach may support more accurate etiologic diagnosis and guide rational testing strategies, particularly in resource-limited settings. Full article

The conversion of low-cost, widely available, and renewable agricultural and forestry biomass waste into high-performance electrode materials for supercapacitors has attracted significant research interest. In this study, bamboo was used as a raw material to prepare bamboo-derived activated carbon (BAC) and nitrogen-doped biomass activated carbon (N-BAC) via a two-step process involving carbonization and KOH activation. The obtained materials were subsequently evaluated as electrode materials for supercapacitors. The effects of carbonization temperature and time, activation temperature and time, and impregnation ratio on the structural properties and iodine adsorption capacity of the activated carbons were systematically examined. The results revealed that all process parameters influenced the iodine adsorption value of the samples in a volcano-type trend. The BAC prepared under optimized conditions (carbonization at 600 °C for 60 min, activation at 850 °C for 60 min, and an impregnation ratio of 6:1) exhibited the highest specific surface area (3013.30 m²/g), a total pore volume of 1.5813 cm³/g, and an average pore diameter of 2.0992 nm. Although nitrogen doping slightly reduced the specific surface area and pore volume of BAC, the introduced nitrogen-containing functional groups participated in redox reactions with the electrolyte, leading to a significant enhancement in the electrochemical performance of N-BAC. In a 6.0 M KOH electrolyte at a scan rate of 0.01 V/s, the specific capacitance of N-BAC reached 288.8 F/g, exceeding that of the optimized BAC (180.85 F/g). The supercapacitor assembled with N-BAC demonstrated a high energy density of 14.4 Wh/kg at a power density of 73.1 W/kg in aqueous electrolyte, the specific capacitance retention rate is about 90.3% after 5000 cycles between −1.2 V and 0 V at a scan rate of 10 mV/s. Overall, this work successfully developed high-performance supercapacitor electrode materials, providing a promising approach for the high-value utilization of biomass resources. Full article

Electronic Medical Records (EMRs) are mandatory in Indonesia following the Ministry of Health regulation, which raises significant challenges in data security and patient-centric access control. Current implementations rely on centralized healthcare systems or third-party vendors, creating risks of unauthorized access, data leakage, and uncertain data integrity. To address these issues, this study proposes DecMed, a decentralized EMR management framework built on IOTA Distributed Ledger Technology (DLT). DecMed integrates Capability-Based Access Control (CapBAC), Proxy Re-Encryption (PRE), and the InterPlanetary File System (IPFS) to enforce patient ownership of medical data. Patients actively grant or revoke access, define access duration, and selectively share data with healthcare personnel. The system is implemented using smart contracts in the Move programming language on the IOTA ledger, while encrypted clinical data is stored on IPFS. Evaluation through unit testing of various unauthorized access scenarios demonstrates that DecMed effectively enforces fine-grained access rules, preserves data confidentiality and integrity, and ensures compliance with national healthcare requirements. Full article

The salivary gland is a key organ in insects that plays essential roles in food digestion, nutrient absorption, and energy metabolism, thereby highlighting the importance of studying salivary gland function for gaining a better understanding of nutritional utilization and insect–plant interactions. To date, however, a lack of salivary gland-specific promoters has limited functional analyses of salivary gland genes in Lepidoptera. In this study, based on microarray and salivary gland transcriptome data, we identified nine candidate genes characterized by high salivary gland expression. Semi-quantitative PCR analysis confirmed cholinesterase (BmCe, BGIBMGA010988) as the optimal candidate for promoter cloning. Temporal expression analysis revealed that the expression of BmCe reaches a peak during days 2–4 of the fifth larval instar. A 2152 bp fragment upstream of the transcription initiation site of BmCe was selected as the putative promoter sequence (designated BmCeP) and cloned to construct a piggyBac transgenic vector driving DsRed expression. Transgenic silkworms were obtained via embryonic microinjection and tissue expression analysis on day three of fifth-instar larvae revealed the predominant localization of DsRed expression in the salivary glands. In this study, we thus identified a gene promoter characterized by salivary gland-predominant expression in Bombyx mori, which we believe could serve as a valuable genetic tool for investigating the molecular mechanisms underlying silkworm nutritional utilization and interactions with its host plant, mulberry. Full article

Tomato is the most widely consumed vegetable worldwide and serves as an important source of vitamins and minerals. Using the Bacillus species as biocontrol agents and plant growth promoters is a sustainable approach to optimize production and mitigate the effects of root-infecting phytopathogenic fungi, thereby reducing reliance on chemical inputs. This study evaluated the effectiveness of a Bacillus sp.-based bioinoculant, produced in a 7 L bioreactor, for controlling root phytopathogens and enhancing tomato yields under field conditions. The trial was conducted at an experimental field of the Universidad Nacional Agraria La Molina (Lima, Peru) using a randomized complete block design with four blocks. Treatment means were compared using Tukey’s multiple range test (α = 0.05) to evaluate treatment effects. The treatments included three concentrations of the bioinoculant (10%, 20%, and 30%) derived from an initial concentration of 1 × 10⁸ CFU/mL of a Bacillus halotolerans IcBac2.1 strain sourced from the LEMyB laboratory strain collection, a commercial biological product (1 × 10⁹ CFU/g), and uninoculated control. Applications were made for the following four key stages of crop development: 10 days after germination, when transplanting through root dipping, 7 days after transplanting, and at the onset of flowering. In all treated groups, applications were directed to the plant crown, whereas the control group received no treatment. The evaluated variables included plant height (cm), stem diameter (mm), root disease incidence (%), chlorophyll index (SPAD), °Brix, pH, vitamin C (mg/100 g), total protein (mg/100 g) and crop yield (t/ha). The greatest plant growth-promoting effects were observed in plants inoculated with the 20% bioinoculant and in the commercial product treatment, as evidenced by increased plant height, greater fruit diameter, caliber, and length, as well as lower root disease incidence (2.86% and 1.43%, respectively). In addition, yields were highest in these treatments (29.9 and 25.2 t ha⁻¹, respectively) compared with 14.5 t ha⁻¹ in the control. These results indicate that a 20% B. halotolerans-based bioformulation, similar to the commercial formulation, promotes plant growth, improves agronomic performance, and reduces root disease incidence in tomato crops. Full article

Background: Alcohol is associated with increased mortality and morbidity globally. Pulmonary infections with opportunistic pathogens can occur in healthy humans; however, binge alcohol intoxication (≥0.08% BAC) is a major risk factor. We have previously shown that a single dose of alcohol comparable to binge alcohol intoxication increases infection by reducing alveolar macrophage function in vivo. Sulforaphane (SFN), a phytonutrient, is a potent inducer of antioxidant production through the induction of nuclear factor erythroid 2-related factor 2 (Nrf2) and inhibition of the nuclear factor kappa-light-chain-enhancer (NF-kB) pathway. The aim of this study was to test the therapeutic potential of SFN given as a pretreatment to prevent alcohol-induced phagocytic dysfunction. Methods: Intracellular phagocytic killing was measured via colony-forming units (CFU) and cytokine expression via ELISA. G. mellonella survival was used to determine the therapeutic potential of SFN in vivo. Results: Dose–response curves indicated that SFN concentrations of less than 20 µM were not cytotoxic in either MH-S (murine) or THP-1 (human) cells. Live infection assay results showed that MH-S and THP-1 cells pretreated with SFN (5 µM) and challenged with 0.2% (v/v) alcohol for 3 or 8 h prior to live B. thailandensis or S. epidermidis infection improved intracellular pathogen killing between 12- and 20-fold compared to macrophages treated with alcohol alone. ELISA analysis indicated that SFN significantly reduced levels of Tumor necrosis factor-alpha (TNF-α) expression at 3 and 8 h compared to controls. Additionally, a Galleria mellonella larvae model demonstrated greater survivability in the prophylaxis group compared to larvae exposed to either Gram-positive or Gram-negative pathogens, as well as in groups that received alcohol prior to pathogen inoculation. Conclusions: Taken together, SFN-induced cytoprotection was extended beyond in vitro cell culture to include an in vivo G. mellonella model demonstrating protection against Gram-positive and negative opportunistic pathogens. These data demonstrate that SFN may be an effective pretreatment option to prevent alcohol-mediated innate immune dysfunction and restore macrophage phagocytic killing. Full article

Catheter-associated urinary tract infections are often caused by biofilm formation on device surfaces. This paper presents an antimicrobial catheter-coating hydrogel comprising p(HEMA) and carboxyl-functionalized p(HEMA-co-MA), loaded with benzalkonium chloride (BAC) to increase hydrophilicity, pH responsiveness, and antibiofilm activity. Hydrogels were prepared by free-radical polymerization, loaded with BAC via swelling, and their physicochemical properties were characterized. Furthermore, microbiological assessment focused on the detection of MIC/MBC/MFC, disk diffusion, biofilm assays, SEM imaging, and RT-qPCR sequencing were used to determine the impact on biofilm-related gene expression to evaluate antimicrobial activity against major catheter-associated urinary tract infection (CAUTI)-associated pathogens and identify the higher BAC loading p(HEMA) and enhanced hydrophilicity and pH-responsive swelling (p(HEMA-co-MA)). The two hydrogels exhibited a wide range of antimicrobial activity and provided lasting inhibition for up to 8 days. It is worth noting that the MA-functionalized hydrogel exhibited a high intrinsic antifouling property, and biofilm development was reduced by more than 85% in BAC-loaded formulations. SEM and gene-expression studies showed reduced microbial adhesion and substantial repression of virulence and biofilm-associated genes. In summary, BAC-loaded p(HEMA) and p(HEMA-co-MA) coatings exhibit strong antimicrobial and antiadhesive properties, and the incorporation of MA results in more effective biofilm suppression, which supports their future use as advanced catheter coatings to prevent the development of device-related infections. Full article