Search Results (115)

Botrytis cinerea is a highly versatile pathogenic fungus, causing significant damage across a wide range of plant species. A central focus of this review is the recent advances made through proteomics, an advanced molecular tool, in understanding the mechanisms of B. cinerea infection. Recent advances in mass spectrometry-based proteomics—including LC-MS/MS, iTRAQ, MALDI-TOF, and surface shaving—have enabled the in-depth characterization of B. cinerea subproteomes such as the secretome, surfactome, phosphoproteome, and extracellular vesicles, revealing condition-specific pathogenic mechanisms. Notably, in under a decade, the proportion of predicted proteins experimentally identified has increased from 10% to 52%, reflecting the rapid progress in proteomic capabilities. We explore how proteomic studies have significantly enhanced our knowledge of the fungus secretome and the role of extracellular vesicles (EVs), which play key roles in pathogenesis, by identifying secreted proteins—such as pH-responsive elements—that may serve as biomarkers and therapeutic targets. These technologies have also uncovered fine regulatory mechanisms across multiple levels of the fungal proteome, including post-translational modifications (PTMs), the phosphomembranome, and the surfactome, providing a more integrated view of its infection strategy. Moreover, proteomic approaches have contributed to a better understanding of host–pathogen interactions, including aspects of the plant’s defensive responses. Furthermore, this review discusses how proteomic data have helped to identify metabolic pathways affected by novel, more environmentally friendly antifungal compounds. A further update on the advances achieved in the field of proteomics discovery for the organism under consideration is provided in this paper, along with a perspective on emerging tools and future developments expected to accelerate research and improve targeted intervention strategies. Full article

This research demonstrates the potential of plant waste cellulose as a remarkable biomaterial for multilayer tablet formulation. Rice husks (RC) and orange peels (OC) were used as cellulose sources and characterized for a comparison with commercial cellulose. The FTIR characterization shows minimal differences in their chemical components, making them equivalent for compression into tablets containing ibuprofen. TGA measurements indicate that the RC is slightly better for multilayer formulations due to its favorable degradation profile. This is corroborated by an XRD analysis that reveals its higher crystalline fraction (~55%). The use of a heat press at combined high pressures and temperatures allows the layer-by-layer tablet formulation of ibuprofen, taken as a model drug. Additionally, this study compares the release profile of three types of tablets compressed with cellulose: mixed (MIX), two-layer (BL), and three-layer (TL). The MIX tablet shows a profile like that of conventional ibuprofen tablets. Although both BL and TL tablets significantly reduce their release percentage in the first hours, the TL ones have proven to be better in the long run. In fact, formulations made of extracted cellulose sandwiching ibuprofen display a zero-order release profile and prolonged release since the drug release amounts to ~70% after 120 h. This makes the TL formulations ideal for maintaining the therapeutic effect of the drug and improving patients’ wellbeing and compliance while reducing adverse effects. Full article

Objective: To systematically review the scientific literature on lysergic acid amide (LSA), focusing on its physical, neurobiological, and social effects, as well as its potential risks and therapeutic uses. Methods: A systematic review was conducted across PubMed, Google Scholar, and Web of Science up to December 2023, using keywords such as “ergine,” “lysergic acid amide,” and “legal high.” Studies were included if they reported original human data on the physical, neurobiological, psychological, or social effects of LSA; seventeen studies were included. Animal studies, in vitro research, and non-original articles were excluded. Two independent reviewers screened and selected the studies, with a third resolving discrepancies. Data were extracted using a standardized form. The review followed PRISMA guidelines and was prospectively registered on the Open Science Framework. Results: LSA is primarily consumed through preparations made from the seeds of Convolvulaceae plants. Reported effects include euphoria, hallucinations, nausea, and anxiety. Severe adverse outcomes, such as psychosis, hypertension, and hospitalization, have also been documented. Some evidence suggests its potential therapeutic application for cluster headaches. However, variability in dosing and misinformation on digital platforms heighten the risks associated with LSA use. Conclusions: LSA poses significant health risks, exacerbated by online misinformation and variability in its effects, and a lack of scientific studies. Further research is essential to clarify its pharmacological profile, establish guidelines for safe use, and raise public awareness about its dangers. Full article

Dysphania ambrosioides, commonly known as epazote, is a medicinal plant of great relevance in traditional Latin American medicine. Its cultural roots and pharmacological properties have made it an object of study for phytochemical research. An artificial intelligence (AI) tool was utilized to assist in reviewing scientific information regarding D. ambrosioides. An initial search was conducted in the Scopus database using the keywords epazote, D. ambrosioides, anti-helminthic, antioxidant, and antimicrobial, which yielded a total of 814 publications. To select the most relevant articles, this AI tool based on natural language processing (available online and free of charge) was applied, which analyzed the keywords that appeared in the titles and abstracts of the works and clustered them, leading to a reduction of 86.73% in the number of studies. D. ambrosioides stands out for its rich composition of bioactive compounds, which give the plant a wide range of therapeutic properties, including antiparasitic activity, through which it is effective against several parasites, such as helminths and protozoa, due to its schistosomicidal, nematocidal and antimalarial action. Additionally, it has shown antimicrobial, antioxidant, and anticancer properties as it contains compounds that help fight cell damage caused by free radicals. Epazote represents a rich source of compounds with a wide therapeutic range. However, much research is required to understand the mechanisms of action of these compounds and to evaluate their safety and efficacy in clinical trials. Full article

Ptaeroxylon obliquum (Thunb.) Radlk. (Rutaceae) is traditionally used for a range of purposes, including ethnoveterinary medicine and to treat various human ailments such as tuberculosis, inflammatory diseases, and bacterial and fungal infections. This review aims to comprehensively summarize the traditional uses, phytochemistry, toxicology, in silico, and pharmacological activities of P. obliquum and discuss the advances made to date. The phytochemistry of P. obliquum revealed the abundance of secondary metabolites such as coumarins and chromones, essential oils, and several other classes of bioactive compounds. A total of 80 secondary metabolites have been reported from this plant species. In vitro studies on P. obliquum explored its therapeutic potential and reported pharmacological properties such as antifungal, antibacterial, antiparasitic, antimycobacterial, anti-inflammatory, and antiproliferative activities. This review highlights the diversity of the medicinal use of P. obliquum and encourages its preservation. Future research should focus on the efficacy of P. obliquum’s most promising bioactive compounds, and the ADME (absorption, distribution, metabolism, and excretion) pharmacological activities may help determine therapeutic potential in in vivo animal models and validate the wide range of traditional uses of P. obliquum. Full article

The use of plant extracts and the compounds isolated from them for the treatment of cancer is an area of active research, given their therapeutic potential. This work focused on evaluating the literature related to the antiproliferative activity of extracts obtained from plants of the genus Tabebuia and molecules isolated in vitro or in vivo. For the search, MeSH and DECS terms were employed in the PubMed, Scopus, and SciELO databases. Research has shown that plant extracts derived from plants of the genus Tabebuia exhibit potential applications in the search for new molecules with antiproliferative activity. Among the isolated molecules, the most evaluated correspond to β-lapachone (naphthoquinone); however, molecules with antiproliferative potential belonging to groups such as iridoids, flavonoids, quinones, furanonaphthoquinones, triterpenes, and polysaccharides have also been isolated and reported. Additionally, synthesized molecules have been evaluated on the basis of the modifications made to the structures of molecules isolated from the plant extracts to increase their activity, aiming to develop more potent antitumor agents for future clinical use. Full article

The growing field of nanotechnology has recently given much attention to nanogels, which are versatile formulas and have promising biomedical applications. Nanogels or nanohydrogels have undergone significant development in various fields of biomedical and industrial research to meet increasing demands, such as in pharmaceuticals, cosmetics, food, and genetic engineering. Nanogels that contain flavonoids, which are secondary metabolites found in plants, are starting to become distinctive and reveal their unique characteristics. The objective of the article is to provide a comprehensive overview of recent research articles on flavonoid-based nanogels, emphasizing the general aspects regarding nanogel formulation and structural characterization, as well as the advancements made in the biomedical field. In conclusion, this article outlines up-to-date developments in the synthesis, formulation, structural characterization, and therapeutic applications of flavonoid-based nanogels, emphasizing their important role in the field of nanotechnology. Full article

Lymphomas represent a heterogeneous group of blood tumors, generally divided into non-Hodgkin lymphoma (NHL) (90% of all lymphomas) and Hodgkin lymphoma (HL). High-grade NHL can rapidly progress so that new strategies and potentially therapeutical options are needed. Recently, it was shown that Vitamin D (VitD) inhibits the growth of cancer cells, controls their invasion and metastasis, and strengthens the antitumor activity of various types of chemotherapeutic anticancer agents. Therefore, we reviewed the recent literature about the influence of VitD and its analogues (VDAs) on the treatment and the prognosis of B-cell lymphomas. As to the in vitro studies in different cell lines, VitD3 and VDAs enhanced the anti-proliferative efficacy of various chemotherapeutics and increased the expression of VitD receptor. In in vivo studies, blood levels of VitD were considered: higher values of plasma bioavailable VitD were correlated with better progression-free survival (PFS) and overall survival (OS), while an unfavorable PFS and OS were observed in VitD deficient groups. No clinical trial was made on the analogs, thus confirming the absence of in vivo positive role of these synthetic drugs. In conclusion, higher levels of circulating VitD are related to improved OS, reduced cancer-specific mortality, and better disease-free survival. VitD and analogs showed also positive effects in in vitro studies, while only VitD was able to improve clinical parameters. Furthermore, a complex approach with plant-based diet, adequate levels for motor exercise, and/or eventual VitD supplementation could be a valuable strategy to challenge lymphomas. Full article

Background/Objectives: The skin is an important barrier that protects against invasion by foreign substances and retains water in the body. Several skin diseases involve dry skin due to a disrupted skin barrier, and most skin diseases that appear on dry skin are accompanied by itch. Dry skin-induced itch and mechanical alloknesis reduce quality of life. Sulfated hemicellulose (i.e., pentosan polysulfate sodium), similar to heparin, is a compound belonging to the sulfated polysaccharide family; however, in contrast to heparin, it is derived from plant materials. We herein investigate the effects of the topical application of OJI-204, a sulfated hemicellulose made by purifying and chemically synthesizing hemicellulose, on dry skin in a mouse model. Methods: The mouse model of dry skin was generated using a mixture of acetone and ether with water. Either OJI-204 (3% or 10%) or 0.3% heparinoid, PBS (control), was applied twice a day to the acetone and diethyl ether/water (AEW)-treated area. The degree of skin dryness was evaluated by measuring transepidermal water loss and stratum corneum hydration. Scratching behavior was recorded the day before AEW treatment and the day after the final day, and an alloknesis assay was performed on the day after the final day. Results: We found that 3% or 10% OJI-204 attenuated dry skin conditions (erythema/hemorrhage, scarring/dryness, edema, and excoriation/erosion) and itchiness more effectively than 0.3% heparinoid. Furthermore, the degree of dryness improved to the same degree as that with heparinoid. OJI-204 also significantly reduced dry skin-induced spontaneous itch and mechanical alloknesis. Conclusions: These results suggest the potential of OJI-204 as a therapeutic or preventive agent for dry skin. Full article

Background/Objectives: For several decades, protein drugs (biologics) made in cell cultures have been delivered as sterile injections, decreasing their affordability and patient preference. Angiotensin Converting Enzyme 2 (ACE2) gum is the first engineered human blood protein expressed in plant cells approved by the FDA without the need for purification and is a cold-chain and noninvasive drug delivery. This biologic is currently being evaluated in human clinical studies to debulk SARS-CoV-2 in the oral cavity to reduce coronavirus infection/transmission (NCT 0543318). Methods: Chemistry, manufacturing, and control (CMC) studies for the ACE2/Ang(1–7) drug substances (DSs) and ACE2 gum drug product (DP) were conducted following USP guidelines. GLP-compliant toxicology studies were conducted on Sprague Dawley rats (n = 120; 15/sex/group) in four groups—placebo, low (1.6/1.0 mg), medium (3.2/2.0 mg), and high (8.3/5.0 mg) doses IP/kg/day. Oral gavage was performed twice daily for 14 days (the dosing phase) followed by the recovery phase (35 days). Plasma samples (n = 216) were analyzed for the product Ang(1–7) by ELISA. Results: The ACE2 protein was stable in the gum for at least up to 78 weeks. The toxicology study revealed the dose-related drug delivery to the plasma and increases in the AUC (56.6%) and Cmax (52.9%) after 28 high-dose gavages (95% C.I.), although this quantitation excludes exogenously delivered membrane-associated ACE2/Ang(1–7). Vital biomarkers and organs were not adversely affected despite the 10-fold higher absorption in the tissues, demonstrating the safety for the first in-human clinical trials of ACE2/Ang(1–7). The NOAEL observed in the rats was 2.5–7.5-fold higher than that of the anticipated efficacious therapeutic dose in humans for the treatment of cardiopulmonary disorders, and it was 314-fold higher than the NOAEL for topical delivery via chewing gum. Conclusions: This report lays the foundation for the regulatory process approval for noninvasive and affordable human biologic drugs bioencapsulated in plant cells. Full article

Human skin fibroblasts are an excellent in vitro model for tracking the processes occurring in human skin and studying the potential impact of various biologically active substances on these processes. Two plant hormones, which are included in the cytokinins group—kinetin (K) and N-6-benzyladenine (BA)—have a positive effect on human skin. Therefore, an attempt was made to examine the effect they have on key skin functions, cell proliferation, and migration, as well as collagen synthesis in them. The effect of phytohormones was studied at selected concentrations for kinetin—10 μM and 1 μM—and for N-6-benzyladenine—1 μM and 0.1 μM. A wound-healing assay was used in order to analyze cell migration and proliferation. The content of total protein and collagen in cells and culture medium was determined. The obtained results confirm that the studied compounds induce cell migration and proliferation, as well as collagen biosynthesis. The positive effect of kinetin and N-6-benzyladenine on fibroblast metabolism that we have demonstrated allows us to indicate them as compounds with potentially therapeutic properties. Therefore, we conclude that they should be subjected to further molecular and in vivo studies focusing on pathologies connected with skin diseases and aging. Full article

Therapeutic treatment of nervous system disorders has represented one of the significant challenges in medicine for the past several decades. Technological and medical advances have made it possible to recognize different neurological disorders, which has led to more precise identification of potential therapeutic targets, in turn leading to research into developing drugs aimed at these disorders. In this sense, recent years have seen an increase in exploration of the therapeutic effects of various metabolites extracted from Maca (Lepidium meyenii), a plant native to the central alpine region of Peru. Among the most important secondary metabolites contained in this plant are macamides, molecules derived from N-benzylamides of long-chain fatty acids. Macamides have been proposed as active drugs to treat some neurological disorders. Their excellent human tolerance and low toxicity along with neuroprotective, immune-enhancing, and and antioxidant properties make them ideal for exploration as therapeutic agents. In this review, we have compiled information from various studies on macamides, along with theories about the metabolic pathways on which they act. Full article

Animal venom and plant extracts have been used since ancient times in traditional medicine worldwide. Natural components, valued for their safety and effectiveness, have been consistently used in cosmetic and pharmaceutical applications. We propose a journey along the boulevard of active compounds from natural sources, where bee venom (BV), cobra venom (CV), and Ficus carica reveal their individual therapeutic and cosmetic properties. The originality of this review lies in exploring the synergy of these bioactive sources, an approach that has not been presented in the literature. Although BV, CV, and Ficus carica have different origins and compositions, they have multiple common pharmacological and cosmetic actions, which make them ideal for inclusion in various products that can be used for skin care and health in general. Their anti-inflammatory, antioxidant, immunomodulatory, antimicrobial, neuroprotective, and regenerative properties give them an essential role in the creation of potential innovative and effective products in the pharmaceutical and cosmetics industry. Although many plant extracts have antioxidant and anti-inflammatory properties, Ficus carica was chosen due to its complex biochemical composition, which provides valuable benefits in skin regeneration and protection against oxidative stress. According to the International Nomenclature of Cosmetic Ingredients (INCI), Ficus carica is used in the form of an extract of fruits, leaves, juice, bark or stem, each having specific applicability in topical formulations; due to the diversity of bioactive compounds, it can amplify the effectiveness of BV and CV, helping to enhance their beneficial effects and reducing the risk of adverse effects, due to its well-tolerated nature. Thus, this combination of natural ingredients opens up new perspectives in the development of innovative products, optimizing efficiency and maintaining a favorable safety profile. In this context, due to the reported experimental results, the three natural sources caught our attention, and we conceived the present work, which is a review made following the analysis of the current progress in the study of the bioactive compounds present in BV, CV, and Ficus carica. We focused on the novelties regarding pharmacological and cosmetic actions presented in the literature, and we highlighted the safety profile, as well as the modern approaches regarding the delivery and transport systems of the active substances from the three natural sources, and we evaluated their prospects in therapeutic and cosmetic use. This paper not only expands our knowledge of bioactive compounds, but it can also generate new ideas and motivations for the research and development of innovative treatments and skincare methods. Full article

Ginkgo (Ginkgo biloba L.) is a widely used medicinal plant, with its green spring leaves commonly utilized for preparing extracts with various therapeutic properties, and leaf infusions also frequently employed. This study aimed to evaluate the in vitro neuroprotective, anti-hyperpigmentation, anti-diabetic, and antioxidant activities, as well as the flavonoid content and its bioaccessibility, of ginkgo leaf infusions, comparing leaves collected in spring and autumn. Infusions made from yellow leaves, both those collected directly from the tree and fallen leaves, exhibited significantly higher total polyphenol content (3.2-fold and 2.5-fold, respectively) and flavonoid content (3.1-fold and 2.4-fold, respectively), along with greater flavonoid bioaccessibility in the salivary phase. These infusions also demonstrated enhanced tyrosinase inhibition (6.0-fold and 5.7-fold, respectively) and antioxidant activity (4.8-fold and 3.5-fold, respectively). Notably, infusions from fallen yellow leaves showed 2.5-fold higher acetylcholinesterase inhibition compared to spring leaf infusions, while α-glucosidase inhibition remained comparable across all samples. These findings suggest that yellow ginkgo leaves, including those that have fallen, could be considered a valuable material for making infusions with potential neuroprotective, anti-hyperpigmentation, and anti-diabetic properties. Full article

Liver disease is a global public problem, and the cost of its therapy is a large financial burden to governments. It is well known that drug therapy plays a critical role in the treatment of liver disease. However, present drugs are far from meeting clinical needs. Lots of efforts have been made to find novel agents to treat liver disease in the past several decades. Acacetin is a dihydroxy and monomethoxy flavone, named 5,7-dihydroxy-4′-methoxyflavone, which can be found in diverse plants. It has been reported that acacetin exhibits multiple pharmacological activities, including anti-cancer, anti-inflammation, anti-virus, anti-obesity, and anti-oxidation. These studies indicate the therapeutic potential of acacetin in liver disease. This review discussed the comprehensive information on the pathogenesis of liver disease (cirrhosis, viral hepatitis, drug-induced liver injury, and hepatocellular carcinoma), then introduced the biological source, structural features, and pharmacological properties of acacetin, and the possible application in preventing liver disease along with the pharmacokinetic and toxicity of acacetin, and future research directions. We systemically summarized the latest research progress on the potential therapeutic effect of acacetin on liver disease and existing problems. Based on the present published information, the natural flavone acacetin is an anticipated candidate agent for the treatment of liver disease. Full article