Search Results (4,031)

Autoimmune diseases are characterized by chronic inflammation, immune dysregulation, and excessive oxidative stress, which collectively contribute to a progressive tissue damage and organ dysfunction. Although conventional immunosuppressive and anti-inflammatory therapies remain the main therapeutic approach, their clinical efficacy is often limited by poor pharmacokinetic properties, low tissue selectivity, systemic toxicity, and adverse effects following long-term administration. In this context, antioxidant-based nanoformulations have emerged as promising multi-target therapeutic strategies for the modulation of oxidative and inflammatory pathways involved in autoimmune disorders. This review focuses on polymeric and non-polymeric nanoformulations designed to improve the solubility, stability, bioavailability, controlled release, and targeted delivery of antioxidant and anti-inflammatory agents for autoimmune disease treatment. Recent advances in nanocarrier systems applications, including nanogels, poly(lactic-co-glycolic acid) (PLGA), polyethylene glycol (PEG), polymethacrylate, chitosan, hyaluronic acid, hydroxyapatite (HAP), lipid-based and ROS-responsive nanosystems, are discussed. The therapeutic potential of nanoencapsulated steroidal and non-steroidal anti-inflammatory drugs, antioxidant compounds, enzymes, inorganic elements, and nucleic acid-binding systems is evaluated through preclinical and limited clinical evidence. Many of these reported nanoformulations exhibit enhanced therapeutic efficacy, improved tissue targeting, reduced systemic toxicity, and the ability to simultaneously modulate oxidative stress and inflammatory signaling pathways. Despite the encouraging findings, important challenges remain regarding clinical translation, long-term safety, reproducibility, and large-scale production. In overall, antioxidant nanoformulations represent a promising and evolving platform for the development of more effective and targeted therapies against autoimmune diseases. Full article

Background/Objectives: This study aimed to develop a novel tumor-associated macrophage (TAM)-targeting nanoplatform to improve the solubility and bioavailability of camptothecin (CPT) and achieve active targeted drug delivery for enhanced anti-tumor immunotherapy. Methods: We constructed a sialic acid-disulfide bond-camptothecin (SA-SS-CPT) nanowire system. Sialic acid was used as a targeting ligand to specifically recognize the overexpressed Siglec-E receptor on TAMs. Upon cellular internalization, the disulfide bond was designed to respond to intracellular glutathione (GSH), enabling controlled drug release. Results: The SA-SS-CPT nanowires significantly improved CPT solubility and enabled targeted delivery to TAMs. Following GSH-responsive cleavage and CPT release, the nanowires induced DNA damage in TAMs, activating the cGAS-STING signaling pathway. This promoted TAM polarization toward the M1 phenotype, enhanced pro-inflammatory and anti-tumor immune responses, and inhibited tumor immune escape. Furthermore, SA-SS-CPT synergistically improved the efficacy of PD-L1 blockade immunotherapy, remodeling the tumor immune microenvironment. Conclusions: The SA-SS-CPT nanoplatform effectively targets TAMs, repolarizes them to an anti-tumor M1 phenotype, and activates the cGAS-STING pathway. It shows strong potential for overcoming tumor immune escape and synergizing with PD-L1 checkpoint blockade to achieve significant tumor clearance. Full article

Background/Objectives: Andrographolide (ADG) is a plant-derived compound with promising anticancer properties, but its medical use is limited due to poor water solubility and low bioavailability. This study proposes developing a gold-based nanocomposite drug delivery system, using a simplified synthesis method, to improve ADG’s hydrophilicity and enhance its delivery efficiency. Methods: A one-step method was used to synthesize gold nanocomposites with carbon quantum dots (CBQDs) and doped CBQDs acting as reducing and stabilizing agents. These nanocomposites were then conjugated with ADG and thoroughly characterized using multiple structural and spectroscopic techniques such as X-ray diffraction (XRD), Fourier transform infrared spectroscopy (FTIR), ultraviolet–visible spectroscopy (UV–Vis), transmission electron microscopy (TEM), Raman spectroscopy, and nuclear magnetic resonance (NMR) spectroscopy. Hydrophilicity enhancement was evaluated using NMR-based log P measurements. Biological assessment involved cell viability assays and confocal microscopy studies in PC3 prostate cancer cells, along with the morphological evaluation of human red blood cells. Results: XRD confirmed the formation of crystalline, face-centered cubic gold nanoparticles, while spectroscopic analyses verified successful nanocomposite formation and ADG conjugation. NMR results showed enhanced hydrophilicity of ADG. Biological tests demonstrated that the nanocomposites were compatible with cells. Conclusions: This study presents a straightforward strategy for synthesizing gold-based nanocomposites that enhance the hydrophilicity and delivery potential of andrographolide, supporting their applicability as nanocarrier platforms for anticancer drug delivery. Full article

Cannabidiol (CBD), a major non-psychoactive phytocannabinoid, has attracted considerable attention owing to its broad therapeutic potential. Its anti-inflammatory, antimicrobial, and antitumor properties make it a promising candidate for the treatment of mucosa-associated diseases. However, the clinical translation of CBD is significantly hindered by its unfavorable physicochemical properties, particularly high lipophilicity and poor aqueous solubility, which result in low bioavailability. To overcome these limitations, the rational selection of administration routes in combination with advanced drug delivery systems tailored to disease pathophysiology is essential. Such strategies are critical for improving the stability of CBD, enhancing mucosal permeation, and enabling controlled and targeted release at diseased sites. Nevertheless, a systematic review focusing on these aspects is still lacking. This review first summarizes the relationship between CBD and the mucosal endocannabinoid system, together with its pharmacological effects. It then discusses the therapeutic potential of CBD in mucosal disorders of the digestive and respiratory systems. In addition, current administration routes and advanced delivery systems for CBD are reviewed to provide insights for future research and clinical translation. Finally, the remaining challenges associated with the clinical application of CBD and future development directions are discussed. Full article

Background: Oral delivery of chemotherapeutic agents remains challenging due to gastrointestinal degradation, poor intestinal permeability, and extensive first-pass metabolism, which collectively limit bioavailability. Lipid-based drug delivery systems offer a promising strategy to overcome these barriers. This study aimed to develop a freeze-dried, solid-dispersible self-emulsifying drug delivery system (SEDDS) using a water-in-oil-in-water (w/o/w) double emulsion approach for the co-encapsulation of hydrophilic (doxorubicin) and lipophilic (ellipticine) agents to enhance oral delivery. Methods: Double-emulsion SEDDS were prepared via a two-stage emulsification process to enable compartmentalized drug loading within aqueous and oil phases. The formulations were freeze-dried to improve stability and storage. Physicochemical properties were characterized using dynamic light scattering for droplet size and polydispersity index (PDI), zeta potential analysis for colloidal stability, and differential scanning calorimetry for thermal behavior. Drug encapsulation efficiency was determined, and cellular uptake was evaluated in breast cancer cells using fluorescence microscopy. Results: Optimized SEDDS exhibited droplet sizes of 90–347 nm with low PDI values (0.005–0.336), indicating uniform and stable dispersions. Zeta potential values (−10.64 to 2.38 mV) supported colloidal stability, while freeze-dried formulations retained dispersion characteristics upon reconstitution over extended storage. Both drugs demonstrated high encapsulation efficiency (>97%), and thermal analysis confirmed the formation of stable amorphous systems. Fluorescence imaging revealed enhanced intracellular uptake of both agents. Conclusions: This study demonstrates that freeze-dried double-emulsion SEDDS enable efficient co-delivery of hydrophilic and lipophilic drugs, improving stability and cellular uptake. This platform shows strong potential for overcoming key barriers in oral chemotherapy and provides a promising strategy for combination drug delivery. Full article

Doxycycline (DOX) is a well-characterized antibiotic, and its pharmacokinetic behavior has recently attracted renewed scientific interest. Its absorption occurs mainly in the small intestine, while ions such as Fe³⁺ and Al³⁺ readily form complexes, particularly under acidic conditions, thereby reducing the fraction of free drug available for absorption. The present study provides a systematic investigation of how such interactions influence the dissolution and intestinal permeability of DOX. A dynamic in vitro protocol was implemented, incorporating an online transition from gastric to intestinal conditions in combination with Franz diffusion cells. This integrated system enables real-time monitoring of early DOX absorption-related processes, providing a more comprehensive understanding of potential pharmacokinetic interactions during its coadministration with iron or aluminum supplements. To ensure reliable quantification, a rapid, economical, and environmentally compatible HPLC-FLD method was developed and validated, employing a Hypersil Gold C18 column (50 mm × 4.6 mm, 5 μm; Thermo) and a mobile phase consisting of acetonitrile—20 mM NaH₂PO₄ (pH 2) 15:85 v/v. Overall, a practical and efficient framework was established for investigating factors that influence the bioavailability of doxycycline, supporting the broader evaluation of drug, excipient, and drug supplement interactions. Full article

Dihydromyricetin (DHM), a naturally occurring flavanonol predominantly found in medicinal plants like Ampelopsis grossedentata, has emerged as a promising source of natural antioxidants with multi-target pharmacological activities relevant to drug discovery. DHM exhibits a strong redox-modulating capacity, effectively attenuating oxidative stress and inflammation central drivers of chronic disease pathogenesis. Beyond direct radical scavenging, DHM regulates multiple redox-sensitive and kinase-mediated signalling pathways, thereby influencing key cellular processes involved in disease initiation and progression. This review synthesizes current evidence on the therapeutic potential of DHM, critically evaluating its mechanistic basis and translational prospects, with emphasis on its dual redox-driven and kinase-mediated modes of action. We detail its roles in metabolic disorders such as diabetes, obesity, and liver diseases, neuroprotection, cardio protection, and cancer prevention, focusing on the modulation of critical networks such as AMPK, PI3K/Akt, MAPK, NF-κB, and Nrf2. The interplay between these pathways underpins DHM’s efficacy across disease models. Furthermore, we highlight structure–activity relationship (SAR) analyses and molecular modelling studies that elucidate how the flavanonol scaffold, hydroxylation pattern, and stereochemistry of DHM govern its biological activities and target engagement. Key pharmacokinetic limitations, advances in extraction techniques, bioavailability challenges, and emerging formulation strategies including advanced delivery systems are discussed to address translational hurdles. Despite compelling preclinical data, the clinical translation of DHM remains constrained by limited human studies and incomplete mechanistic resolution. This review underscores the need for integrated pharmacological studies and innovative delivery approaches to translate the multifaceted promise of DHM into viable clinical interventions. Full article

Pharmacomicrobiomics is the study of drug–microbiome interactions. It examines the dynamic relationship between the drug, the host, and the microbiome, and has become a rapidly evolving area in the realm of pharmacology and personalized medicine. Emerging evidence demonstrates that the gut microbiome can influence the pharmacodynamics and pharmacokinetics of drugs through various mechanisms, while drugs can simultaneously alter microbial composition. Treatment approaches include regular targeted pharmaceutical therapies (e.g., antibiotics, antidepressants) and alternative treatment approaches (e.g., CAM treatments such as supplements and herbs). Microbiome-based medication treatment is an alternative treatment approach that has been studied extensively in the last decade. This article reviews the current knowledge on drug–microbiome interactions across multiple therapeutic systems, including cardiovascular, central nervous system, gastrointestinal, respiratory, endocrine, oncologic, musculoskeletal, anti-infective therapies, and supplements (such as melatonin). We also highlight the various pathways by which microbes can alter the mechanisms (such as drug absorption), bioavailability, efficacy, and incidence of adverse effects, along with highlighting the clinical implications of drug-induced dysbiosis. Full article

Background/Objectives: BPC-157 (body protection compound 157) is a synthetic pentadecapeptide derived from a gastric protein fragment with reported cytoprotective and regenerative properties across multiple organ systems. Despite over three decades of preclinical research demonstrating consistent biological activity, its pharmaceutical development remains rudimentary, with no approved formulation, no validated dosing regimen, and no completed Phase II clinical trial. This review critically evaluates BPC-157 from a biopharmaceutical and drug development perspective, examining its physicochemical and pharmacokinetic properties, formulation challenges across routes of administration, the pharmacokinetic–pharmacodynamic disconnect that characterizes its preclinical profile, and the regulatory and translational barriers that currently preclude clinical advancement. Methods: A narrative review of the literature was conducted using PubMed/MEDLINE, Embase, and Cochrane Library from database inception to April 2026. Search terms included “BPC-157”, “BPC157”, “body protection compound 157”, “pentadecapeptide”, and “GEPPPGKPADDAGLV”, each combined with “pharmacokinetics”, “formulation”, “biopharmaceutics”, “drug delivery”, “clinical trial”, “toxicology”, and “regulatory”. Patent databases (Espacenet, Google Patents) and regulatory agency websites (FDA, EMA, WADA) were searched independently. Searches were supplemented by forward and backward citation tracking of key references. Articles were selected based on relevance to biopharmaceutical characterization, pharmacokinetics, formulation science, clinical evidence, and regulatory status; pharmacodynamic studies were included insofar as they inform translational development. Evidence was synthesized with emphasis on pharmaceutical characterization, formulation science, and translational feasibility; no formal quality assessment instrument was applied, consistent with the narrative review design. Results: BPC-157 exhibits unusual stability in gastric juice and demonstrates activity via oral, parenteral, and topical routes, yet its human pharmacokinetic profile remains critically undercharacterized despite a recently published formal preclinical ADME study in two species confirming a sub-30-min plasma half-life, linear dose-proportional kinetics, and intramuscular bioavailability of 14–51% depending on species. A plasma half-life of under 30 min—confirmed preclinically and in a preliminary two-subject human pilot—contrasts with prolonged biological effects lasting hours to days—a disconnect with significant implications for dosing strategy and formulation design. No pharmaceutical-grade formulation has been developed or validated. The peptide lacks bcs classification data, permeability characterization, and formal excipient compatibility studies. Available clinical data derive from fewer than 30 subjects across three uncontrolled pilot studies, none of which employed standardized pharmaceutical preparations. Conclusions: BPC-157 presents a compelling but pharmaceutically underdeveloped profile. The primary barrier to clinical translation is not the absence of biological activity, but the absence of fundamental pharmaceutical science: characterized formulations, validated pharmacokinetics, and a coherent drug development strategy. Addressing these biopharmaceutical gaps is a prerequisite for any meaningful clinical program. Full article

Influenza A virus (IAV) remains a major global health threat despite available vaccines and antiviral agents, while current therapies are limited by drug resistance and safety concerns. Curcuminoids exhibit antiviral and anti-inflammatory activities but are constrained by poor water solubility and low bioavailability. To address these limitations, we investigated the antiviral and immunomodulatory properties of a water-solubilized curcuminoid nanoparticle formulation (C–S/M) in both in vitro and in vivo models of IAV infection. To evaluate the potential antiviral and anti-inflammatory effects of C–S/M, we performed a cytopathic effect (CPE) reduction assay in triplicate at 0.001 MOI and quantitative real-time PCR (qRT-PCR) targeting viral NS1 transcripts in MDCK cells. C–S/M suppressed viral NS1 vRNA levels in MDCK cells at lower curcuminoid-equivalent concentrations than native curcuminoids and attenuated IAV-induced TNF-α, IL-6, and IL-8 production. Furthermore, in vivo antiviral efficacy was evaluated in female C57BL/6 mice intranasally infected with IAV and treated orally with C–S/M. Survival, lung viral loads, pulmonary cytokine levels, and splenic immune cell phenotypes were analyzed. In IAV-infected mice, oral administration of C–S/M modestly improved survival and significantly reduced lung viral burden and pulmonary proinflammatory cytokine levels. In addition, in vivo C–S/M treatment was associated with recovery of virus-suppressed T-cell immune responses, including increased Th1 and activated CD8⁺ T cells, reduced regulatory T-cell expansion, and restoration of multifunctional CD4⁺ and CD8⁺ T cells. These findings suggest that C–S/M exerts antiviral and immunomodulatory effects in experimental IAV infection and may serve as a potential adjunctive candidate for further investigation against influenza-associated inflammation. Full article

The occurrence and development of metabolic dysfunction-associated steatotic liver disease (MASLD) are closely related to intestinal flora imbalance, intestinal barrier damage, and gut-liver axis dysfunction. Due to their multi-target regulatory effects and advantages in intestinal microecological intervention, Chinese herbal monomers have shown promising application prospects in the prevention and treatment of MASLD. However, basic research on their toxicity still lags behind, and issues related to safety and clinical translation urgently need attention. This article systematically reviews the research progress on how flavonoids, triterpenoids, alkaloids, and polysaccharides improve hepatic steatosis, inflammatory responses, and metabolic disorders from a toxicological perspective by reshaping the intestinal microbiota, repairing the intestinal mucosal barrier, regulating short-chain fatty acid and bile acid metabolism, and synergistically acting on signaling pathways such as TLR4/NF-kB, FXR, TGR5, SIRT1, and the NLRP3 inflammasome. Furthermore, by combining methods such as 16S rRNA sequencing, metagenomics, metabolomics, and multi-omics integration, the article analyzes their application value and limitations in toxicological mechanism research, and discusses the translational bottlenecks faced by Chinese herbal monomers in pharmacokinetics, bioavailability, quality standardization, targeted delivery, and toxicological safety. Existing evidence indicates that Chinese herbal monomers have a three-in-one intervention advantage of microecological remodeling-metabolic regulation-inflammation inhibition, but their long-term medication safety, toxic target organs, dose-effect/toxicity relationships, and potential drug interactions still need further clarification. This article aims to provide a systematic reference for the safety evaluation and clinical translational research of Chinese herbal monomers in the prevention and treatment of MASLD. Full article

Depression is one of the most common mental disorders in modern society, and it has become a serious threat to human health. The limitations of existing antidepressant drugs have prompted people to turn to the multi-target, low-toxic side effects of natural products. This article reviews the conventional nutrients (omega-3 fatty acids, folic acid, and mineral elements) and functional active ingredients (flavonoids, polysaccharides, saponins, and terpenoids) in medicinal and food homologous substances (MFHs). They show antidepressant potential by regulating neurotransmitters, improving hypothalamic–pituitary–adrenal (HPA) axis function, promoting neuroplasticity, inhibiting neuroinflammation, regulating ferroptosis, and interfering with the gut–brain axis. In addition, this paper discusses the application prospects of modern technologies such as microbial fermentation and nano-delivery in improving the bioavailability of MFHs and product development. In summary, MFHs have potential application value in dietary intervention and adjuvant therapies for depression; in the future, randomized controlled clinical trials should be strengthened, and multi-omics technology should be combined to promote the development of precision products so as to provide a new perspective for the development of new antidepressant drugs. Full article

Icariin (ICA), a prenylated flavonoid glycoside from Epimedium (Yin Yang Huo), exhibits multi-organ pharmacological effects and has emerged as a promising candidate for osteoporosis therapy and bone tissue regeneration because of its capacity to modulate diverse osteogenic, anti-inflammatory, and angiogenic signaling pathways. Preclinical studies in osteoporotic models suggest that ICA improves trabecular microarchitecture and increases bone mineral density. Mechanistically, ICA modulates bone remodeling bidirectionally: it promotes osteoblast differentiation and extracellular matrix mineralization via activation of pro-osteogenic pathways, including Wnt/β-catenin and PI3K/Akt signaling, while simultaneously inhibiting osteoclastogenesis and bone resorption by suppressing RANKL-mediated NF-κB activation, thus reestablishing remodeling equilibrium. Despite these benefits, clinical advancement is hindered by the suboptimal oral bioavailability of ICA, stemming from poor intestinal absorption and extensive first-pass metabolism. To address this, innovative delivery systems have been engineered to enhance localized bioavailability and sustain therapeutic efficacy, such as hydrogel depots, nanoparticle formulations, and 3D-printed scaffolds enabling precise, controlled release. In bone tissue engineering applications, ICA-incorporated biomaterials—either standalone or in combination with osteogenic factors or exosomes—foster a regenerative niche by mitigating inflammation and oxidative stress, while synergistically promoting osteogenesis and angiogenesis, thereby expediting bone defect healing and osseointegration. Overall, these mechanistic elucidations and delivery advancements underscore ICA’s potential as a translational candidate for osteoporosis treatment and bone regenerative therapies. This review aims to critically and systematically synthesize current evidence on ICA-mediated bone repair and regeneration, with a particular emphasis on the molecular regulation of osteogenic signaling, the restoration of bone-remodeling homeostasis, and delivery-system-enabled strategies that may facilitate translational application. Full article

Tauopathies, including Alzheimer’s disease (AD), progressive supranuclear palsy (PSP), corticobasal degeneration (CBD), and frontotemporal lobar degeneration with tau pathology, are unified by pathogenic tau misfolding, post-translational modification, aggregation, and network-level spread. Yet decades of drug development that predominantly pursued single nodes (e.g., one kinase, one aggregation inhibitor, one monoclonal antibody epitope) have repeatedly delivered late-stage disappointments, underscoring a central lesson: tauopathy behaves less like a linear pathway and more like a coupled system of proteostasis failure, neuroinflammation, synaptic-mitochondrial stress, and metabolic dysregulation. This review examines rhizomes (notably Zingiberaceae genera such as Curcuma, Zingiber, Alpinia, Kaempferia, and Boesenbergia) as chemically diverse “multi-target platforms” whose bioactives can engage several tau-relevant nodes simultaneously. We synthesise evidence across tau phosphorylation (GSK-3β/CDK5 and upstream stress signalling), tau aggregation and seeding, autophagy-lysosome and proteasome pathways, redox-mitochondrial resilience, neuroinflammatory circuits (NF-κB/NLRP3), and neuro-metabolic signalling (insulin-PI3K-AKT, AMPK-mTOR). A translational lens is applied throughout, focusing on drug-likeness and CNS multiparameter optimisation; BBB permeability and efflux; metabolism and bioavailability constraints; and formulation strategies (nanoparticles, phytosomes, engineered exosomes) that may render rhizome-derived scaffolds more clinically plausible. We conclude that rhizomes offer credible mechanistic hypotheses for tau modulation, but progress depends on rigorous standardisation, realistic exposure matching, biomarker-driven study design, and a shift from “single-compound optimism” to network pharmacology with translational discipline. Full article

Bringing a new drug to market is a complex, costly, and lengthy process, averaging $2.6 billion and about ten years of research and development. It involves multiple stages, from target discovery to post-approval monitoring, and relies heavily on innovation driven by collaboration among pharmaceutical sciences, biology, biochemistry, engineering, and artificial intelligence. Drug discovery can be divided into four main stages: target selection and validation; compound screening and optimization; preclinical studies; and clinical trials. First, researchers identify and validate a biological target associated with a disease using genomic, proteomic, and bioinformatic approaches. Next, potential compounds (“hits”) are identified through methods such as high-throughput and virtual screening, followed by iterative chemical optimization and functional testing. Promising candidates undergo preclinical in vivo studies to assess pharmacokinetics, pharmacodynamics, and toxicity. Clinical development proceeds in three phases: Phase I evaluates safety in healthy volunteers; Phase II assesses efficacy in patients; and Phase III confirms efficacy and safety in larger populations. After successful trials, regulatory agencies review the data for approval. While small molecules have long dominated due to their stability and oral bioavailability, biologics—such as monoclonal antibodies and mRNA-based therapies—have grown rapidly, highlighted by COVID-19 vaccine development and increasing FDA approvals. Full article