Search Results (1,209)

Gold nanoparticles (AuNPs) have emerged as versatile antiviral nanoplatforms because their size, morphology, plasmonic properties, and surface chemistry can be precisely engineered. In this review, we summarize the core design principles of antiviral AuNPs from a structure–function–mechanism perspective. We first outline representative synthetic and interface-programming routes for AuNP preparation, including citrate reduction, Brust–Schiffrin synthesis, seed-mediated growth, green synthesis, direct thiol-conjugation, and mixed-ligand shell strategies, emphasizing how these approaches define particle size, morphology, surface accessibility, interfacial composition, and downstream biofunctionalization potential. We then discuss major surface engineering strategies, including polyethylene glycol, nucleic acids, antibodies and nanobodies, peptides, glycans, antiviral drugs, and biomimetic coatings, with particular attention to how ligand density, orientation, flexibility, and interfacial stability determine biological performance. Next, we examine how functionalized AuNPs inhibit different stages of the viral life cycle, including viral attachment and entry, intracellular replication, assembly and egress, photothermal inactivation, and immune modulation or vaccine delivery. Finally, we highlight current challenges, including incomplete structure–activity relationships, dynamic nano–bio interactions under physiological conditions, limited standardization across studies, and translational barriers related to safety, reproducibility, and scale-up. This review provides a conceptual framework for the rational development of next-generation AuNP-based antiviral nanotherapeutics. Full article

Background: The mucosal barrier presents a significant challenge for non-invasive delivery of macromolecular therapeutics, often requiring administration with poor bioavailability and increased toxicity risks. The polymeric immunoglobulin receptor (pIgR) contains an extracellular secretory component (SC) for immunoglobulin binding and a membrane-anchored stem domain capable of apical-to-basolateral transcytosis. We hypothesized that targeting the stem domain could enable active drug transport across mucosal barriers. Methods: Using phage display, we identified four high-affinity nanobodies against human and murine pIgR. Two lead candidates (3LTHMP-4 and 3LTHMP-5) demonstrated efficient apical-to-basolateral transport in vitro (Transwell assays) and in vivo (fluorescence imaging). Engineered bispecific antibodies fusing these nanobodies with anti-IL-5 mAb reslizumab were administered via inhalation in a murine asthma model at one-tenth the intraperitoneal reslizumab dose. Resluts: The bispecific antibodies showed significant therapeutic efficacy, while reslizumab alone at equivalent concentrations failed to demonstrate efficacy. Hydrogen–Deuterium Exchange Mass Spectrometry (HDX-MS) revealed that both 3LTHMP-4 and 3LTHMP-5 specifically bind to the pIgR stem domain (residues 578–612), a region distinct from the dimeric IgA binding site. Conclusions: These findings suggest that stem domain-specific binding may facilitate transport across the mucosal barrier while preserving native receptor physiology, offering a potential strategy for effective transmucosal delivery of biologics. Full article

Head and neck squamous cell carcinoma (HNSCC) remains one of the most aggressive and heterogeneous malignancies worldwide, characterized by high rates of locoregional recurrence, metastatic dissemination, and therapeutic resistance. Angiogenesis plays a central role in tumor progression by supporting vascular remodeling, hypoxia adaptation, invasion, immune evasion, and metastatic spread. In HNSCC, angiogenic activation is regulated through complex interactions involving hypoxia-inducible factors, vascular endothelial growth factor (VEGF) signaling, stromal remodeling, inflammatory pathways, and epigenetic mechanisms within the tumor microenvironment. Recent evidence has also highlighted the role of non-coding RNAs, particularly microRNAs, and exosome-mediated communication in modulating angiogenic and immune-related signaling pathways. Although antiangiogenic therapies, including monoclonal antibodies and tyrosine kinase inhibitors, have demonstrated biological activity in HNSCC, their clinical efficacy remains limited by tumor heterogeneity, adaptive resistance mechanisms, toxicity, and the lack of validated predictive biomarkers. Several emerging therapeutic strategies are under preclinical or early clinical investigation in HNSCC, including miRNA-based approaches, nanoparticle-assisted delivery systems, vascular normalization concepts, and combinations with immune checkpoint inhibitors; however, robust clinical evidence for most of these strategies remains limited, and their translation to routine practice requires further validation. This review provides a comprehensive overview of the molecular mechanisms regulating angiogenesis in HNSCC and critically discusses current and emerging pharmacological strategies targeting these pathways. Particular emphasis is placed on VEGF/VEGFR signaling, the integration of miRNA and exosome biology, resistance mechanisms, and translational perspectives for biomarker-guided personalized therapy. The novelty of this review lies in the systematic integration of miRNA- and exosome-mediated angiogenic regulation, therapeutic resistance pathways, and precision medicine strategies into a unified pharmacological framework, addressing gaps not fully covered by prior reviews focused primarily on VEGF-targeted agents. Full article

Radiometabolic therapy is a mechanistically plausible but clinically underused strategy in lymphoma. Its rationale is based on the selective delivery of cytotoxic radiation to malignant lymphoid cells through antibodies, peptides, or small molecules directed against tumor-associated targets. Radioimmunotherapy with anti-CD20 agents, including 90Y-ibritumomab tiuxetan and 131I-tositumomab, demonstrated meaningful efficacy in B-cell non-Hodgkin lymphoma, particularly in indolent and relapsed/refractory settings. However, despite encouraging clinical results, its use progressively declined because of logistical, regulatory, commercial, and multidisciplinary barriers. More recently, renewed interest has emerged with the development of novel antibody–radionuclide conjugates and radioligand-based theranostic strategies targeting CD22, CD37, CD45, and CXCR4. Among these, CXCR4-directed imaging and therapy with 68Ga-pentixafor and 177Lu/90Y-pentixather illustrate image-guided patient selection and targeted radionuclide treatment in advanced hematologic malignancies. This narrative review summarizes evidence retrieved from Scopus and PubMed on radiometabolic therapy in lymphoma, with particular attention paid to established radioimmunotherapy, emerging targets, radioligand therapy, dosimetry, toxicity, and combination strategies with chemotherapy, immunotherapy, and hematopoietic stem cell transplantation. Available evidence supports the plausibility and possible clinical utility of these approaches, but remains heterogeneous and, for several newer targets, preliminary. Future development will require prospective trials, standardized imaging-based selection, individualized dosimetry, and integration within multidisciplinary lymphoma treatment pathways. Full article

Gastric cancer remains a major clinical challenge, underscoring the need for more effective drug delivery strategies. Approximately 10–20% of gastric cancers overexpress HER2, conferring aggressive tumor characteristics and poor survival, yet resistance to trastuzumab-based targeted therapy and limited intratumoral antibody penetration continue to restrict clinical outcomes. This study evaluated HER2-targeted exosomes as a delivery platform. Exosomes were engineered to express the p51 peptide, a high-affinity HER2-binding ligand, and loaded with 17-dimethylaminoethylamino-17-demethoxygeldanamycin (17-DMAG), a potent HSP90 inhibitor. The cellular uptake and antitumor efficacy of p51-Exo^17-DMAG were assessed in vitro using NCI-N87 and AGS cells and in vivo using a mouse xenograft model. p51-modified exosomes exhibited superior HER2 specific uptake. Treatment with p51-Exo^17-DMAG significantly increased apoptosis, as demonstrated by elevated PARP and caspase3 cleavage, and downregulated oncogenic signaling molecules, including p-AKT, CDK2, VEGF, and c-Myc. Furthermore, p51-Exo^17-DMAG increased the number of TUNEL-positive cells. In the NCI-N87 xenograft model, systemic administration of p51-Exo^17-DMAG significantly inhibited tumor growth without toxicity or histological damage to major organs. Tumor analysis confirmed increased apoptosis and reduced proliferation in vivo. These findings demonstrate that p51-engineered exosomes provide an efficient, selective, and safe platform for HER2-targeted delivery of 17-DMAG, offering a promising precision medicine strategy for HER2-positive gastric cancer. Full article

Background: Monoclonal antibodies (mAbs) initially played a major role in outpatient COVID-19 management by providing rapid passive immunity and reducing progression to severe disease. However, continuous SARS-CoV-2 evolution progressively compromised the effectiveness of several anti-spike products. This narrative review summarizes the trajectory of COVID-19 mAbs across three phases: early clinical efficacy, loss of efficacy due to immune escape, and future directions. Methods: We conducted a narrative review focusing on mechanisms of action, pivotal clinical trials, and real-world effectiveness of neutralizing anti-spike mAbs and host-directed immunomodulatory mAbs. Emphasis was placed on the impact of variants—especially Omicron—on susceptibility and clinical use, as well as on emerging next-generation platforms. Results: First-generation neutralizing mAbs substantially reduced the hospitalization rates during the Alpha and Delta waves, while immunomodulatory mAbs became standard options for the hyperinflammatory phase in hospitalized patients. With the emergence of Omicron and its sub-lineages, extensive immune escape led to marked reductions in neutralization for many earlier anti-spike agents and consequent restrictions in use. Later-generation approaches targeting more conserved epitopes provided temporary solutions but were also challenged by ongoing antigenic drift. Host-directed immunomodulators retained clinical relevance because their mechanism is independent of viral spike mutations. Conclusions: The clinical role of monoclonal antibodies in COVID-19 has been dynamic and increasingly constrained by viral evolution. Future strategies should prioritize broadly neutralizing antibodies targeting conserved epitopes, innovative delivery platforms, and integration with real-time surveillance to preserve clinical utility in the endemic phase and improve preparedness for future outbreaks. Full article

Background: This study aimed to construct a recombinant Pseudomonas aeruginosa outer membrane vesicle (OMV) vector vaccine delivering pcrV and compare the immunological impacts of OMVs as carriers versus as adjuvants. Methods: The recombinant plasmid pBBRMCS5-pcrV was constructed and transformed into P. aeruginosa. Recombinant OMVs (OMV_PcrV) were prepared via ultracentrifugation and characterized in terms of their morphology and particle size by means of transmission electron microscopy (TEM) and nanoparticle tracking analysis (NTA). After a biosafety evaluation, mice were intramuscularly immunized with PcrV or OMV_PcrV, followed by a booster immunization on day 21. On day 42, the mice were challenged subcutaneously and intranasally with PAO1. Bacterial loads in tissues and blood, pulmonary T-cell subsets, and serum antibody levels were assessed. Results: The recombinant plasmid was successfully constructed, and Western blotting confirmed the delivery of PcrV into OMVs. TEM revealed typical spherical nanostructures, and NTA showed a median particle size of 127.4 ± 5.3 nm. Upon subcutaneous challenge, the OMV, OMV_PcrV, and OMV + PcrV groups all achieved 100% protection. Both the OMV_PcrV and OMV + PcrV groups exhibited increased CD4⁺ and CD8⁺ T-cell counts and higher induction levels of specific IgM, IgG1, and IgG2a antibodies. The OMV_PcrV group showed superior clearance of respiratory bacterial colonization and reduced inflammatory injury compared with the PBS control group. Conclusions: The constructed vector successfully delivered the PcrV antigen, and the OMVPcrV vaccine induced effective immune responses. Compared with wild-type outer membrane vesicles (OMVs) and the strategy of directly mixing free PcrV antigen with OMVs (OMV + PcrV), the recombinant OMV_PcrV vaccine exhibited superior immunoprotective efficacy in terms of bacterial clearance and tissue protection, providing experimental evidence for the development of a Pseudomonas aeruginosa vaccine. Full article

Alzheimer’s disease (AD) is a complex neurodegenerative disorder with features of amyloid-beta (Aβ) accumulations, tau hyperphosphorylation, oxidative stress, neuroinflammation, and synaptic losses. Despite extensive therapeutic investigations for many decades, the clinical treatment options remained largely symptomatic, while anti-amyloid antibody therapies were expensive and had limited accessibility. A subclass of triterpenoids generated from plants, pentacyclic triterpenic acids (PTAs), exhibited a variety of pharmacological properties. The neuroprotective effects of some important PTAs in AD models were reviewed in this study. These phytochemicals displayed a multimodal neuroprotection by lowering amyloid and tau, improving mitochondrial function, inhibiting inflammation, and improving synaptic plasticity and cognition. However, the neuroprotective mechanisms of several PTAs remained poorly characterized. In addition, most evidence were preclinical, while poor bioavailability and the limited clinical validation hindered the therapeutic translation. Studies were needed to evaluate these phytochemicals in AD, improve their pharmacokinetics, and enhance brain delivery. Their diverse bioactivities and encouraging preclinical findings suggest these compounds may serve as promising lead candidates for future drug development in neurodegenerative diseases. Full article

Antibody-drug conjugates (ADCs) have transitioned from clinically marginal agents into a defining therapeutic class for solid tumor oncology. In DESTINY-Breast03, trastuzumab deruxtecan achieved a four-fold progression-free survival advantage over trastuzumab emtansine, attributable not to antibody engineering but to the linker-payload axis: a cleavable peptide linker and a topoisomerase I payload with bystander activity. Sacituzumab govitecan extends the same logic to Trop-2-positive disease via extracellular payload release, and the framework now spans breast, urothelial, gynecologic, lung, gastric, and colorectal cancers, with enfortumab vedotin plus pembrolizumab displacing platinum chemotherapy as first-line therapy for urothelial cancer in EV-302 (median overall survival 31.5 versus 16.1 months). This review synthesizes ADC biology along three analytical axes. The mechanistic axis links each linker-payload-DAR configuration to a specific tumor-biology barrier: vascular limitation, which delivers approximately 0.1% of the administered dose to tumor tissue; the binding-site barrier, which concentrates exposure at the perivascular margin; and antigen mosaicism, which defeats internalization-dependent killing. The translational axis examines resistance as a coordinated failure across antigen modulation, trafficking, efflux, apoptotic execution, and lysosomal processing. The clinical axis traces the platform’s migration toward earlier-line and curative-intent settings. We close by examining whether the ADC delivery architecture translates to precision immunosuppression in autoimmune disease, where the glucocorticoid receptor modulator ADC ABBV-154 met placebo-controlled efficacy endpoints in rheumatoid arthritis but was discontinued because its benefit-risk profile did not differentiate it from existing biologic therapies. Full article

Non-Hodgkin lymphoma (NHL) encompasses a biologically diverse group of malignancies for which the integration of precision medicine has markedly reshaped therapeutic strategies. Recent advances in molecular profiling, target identification, and drug development have led to the introduction of highly selective agents capable of overcoming resistance mechanisms and improving outcomes in relapsed or refractory disease. This review highlights three targeted therapies—pirtobrutinib, brentuximab vedotin, and belinostat—and their evolving roles in modern NHL management. Pirtobrutinib, a next-generation, non-covalent Bruton tyrosine kinase (BTK) inhibitor, demonstrates preserved activity in patients previously treated with covalent BTK inhibitors (BTKi), addressing a critical unmet need in B-cell lymphomas. Brentuximab vedotin, an antibody–drug conjugate targeting CD30, has significantly improved therapeutic precision by delivering cytotoxic agents directly to lymphoma cells and has become a central component of treatment for CD30-expressing NHL subtypes. Belinostat, a broad-spectrum histone deacetylase (HDAC) inhibitor, offers a mechanistically distinct epigenetic approach, particularly in peripheral T-cell lymphomas (PTCL), where conventional chemotherapy has limited efficacy. Together, these agents exemplify three complementary paradigms of precision oncology in NHL: kinase signaling inhibition, antigen-directed cytotoxic delivery, and epigenetic modulation. This review synthesizes current evidence, clinical trial data, and future perspectives regarding the integration of pirtobrutinib, brentuximab vedotin, and belinostat into evolving treatment paradigms. Cumulatively, these therapies illustrate both the progress and the ongoing challenges of biomarker-driven treatment in NHL, including resistance mechanisms, toxicity management, optimal therapeutic sequencing, and variability in evidence maturity across targeted strategies. While pirtobrutinib and brentuximab vedotin are supported by increasingly robust clinical evidence in selected lymphoma subtypes, the role of belinostat remains constrained by modest response rates and limited randomized data, underscoring the continued need for biomarker refinement and more precisely individualized therapeutic approaches in NHL precision medicine. Full article

Extracellular vesicles (EVs) have attracted considerable attention as natural nanocarriers for immune modulation owing to their intrinsic biocompatibility, nanoscale size, and capacity to transport diverse bioactive cargos. In inflammatory diseases, EV-based therapeutics provide unique opportunities to regulate dysregulated immune responses; however, their clinical translation remains constrained by limited cell-specific targeting efficiency and uncontrolled biodistribution. Achieving precise and selective delivery to immune cells and other inflammation-associated cellular components within diseased tissues is therefore critical for maximizing therapeutic efficacy while minimizing off-target effects. This review comprehensively summarizes recent advances in cell-specific EV-targeting strategies for immune modulation in inflammatory diseases, with a particular focus on active targeting approaches enabled by EV surface engineering. A range of targeting ligands, including antibodies, peptides, aptamers, glycans, and membrane proteins, is discussed in the context of enhancing selective interactions between EVs and specific immune cell subsets. Special emphasis is placed on cell-directed targeting strategies toward diverse immune cell populations, including macrophages and T cells, highlighting how rational control of EV–cell interactions can be utilized to reprogram immune phenotypes, suppress pathological inflammation, and restore immune homeostasis. Accordingly, this review integrates recent progress in cell-specific EV targeting into a coherent conceptual framework, which may assist researchers in the rational design of EV-based immunomodulatory therapeutics. Full article

Porcine enteric coronaviruses (PECs), including porcine epidemic diarrhea virus (PEDV), transmissible gastroenteritis virus (TGEV), porcine deltacoronavirus (PDCoV), and swine acute diarrhea syndrome coronavirus (SADS-CoV), remain major causes of neonatal diarrhea, dehydration, mortality, and economic loss in swine production. Despite substantial progress in vaccine development, durable field protection is still inconsistent. In this narrative review, this narrative review synthesizes current knowledge on PEC vaccine design from three connected perspectives: antigenic breadth, mucosal immunity, and translational evaluation. The economic and virological context of PEC vaccine development is first summarized, including the recurrent production burden of PECs, coronavirus genome organization, structural proteins, and the central role of the spike protein in receptor engagement, membrane fusion, and neutralizing antibody induction. Key issues are then discussed, including how spike diversity, conformational stability, epitope accessibility, glycan shielding, and antigen matching influence protective breadth; why intestinal secretory IgA, mucosal immune-cell trafficking, local memory responses, and lactogenic immunity should be prioritized as biologically relevant endpoints; and how delivery route, adjuvant selection, and platform design shape response quality. Current evidence on recombinant protein, viral-vectored, nanoparticle, virus-like particle, probiotic, plant-derived, and mRNA-based approaches is compared with attention to both promise and current evidentiary and translational limitations. The available literature suggests that future progress in PEC vaccinology is likely to depend less on platform novelty alone than on integrated vaccine designs that align antigen selection, mucosal delivery, maternal–neonatal protection, heterologous challenge, manufacturability, and field applicability. Full article

Systemic administration of antibodies that target immune checkpoint inhibitor pathways is a highly effective approach to cancer immunotherapy, but systemic toxicity can limit clinical utility. In preclinical testing, a peri-tumor injection of a low dose of hydrogel-encapsulated cytotoxic T-lymphocyte-associated antigen 4 (CTLA-4) antibody was shown to selectively activate T cells in tumor-draining lymph nodes, induce tumor infiltration by cytotoxic T cells, and result in tumor regression, protective immunity, and long-term survival. In contrast to systemic therapy, there was limited systemic exposure or risk for autoimmune toxicity. The current study focuses on translating this platform into a biocompatible human therapeutic. The hydrogel matrix was reformulated using a low-molecular-weight hyaluronic acid. A recombinant human hyaluronidase (rHuPH20) was incorporated to promote lymph node targeting and self-resorbing features. Formulations were optimized to operate at neutral pH and with gelation kinetics allowing a 5 to 10 min administration window. Performance features were assessed including the capacity to encapsulate human IgG or ipilimumab antibody at proposed therapeutic doses (1–15 mg/mL), impact of rHuPH20 and antibody on rheologic properties and three-dimensional microstructure, and payload delivery profiles in vitro and in vivo. Results confirm the capacity for this unique hydrogel platform to be adapted for human testing. Full article

Background/Objectives: Immune checkpoint inhibitors targeting the PD-1/PD-L1 axis have transformed cancer treatment, yet therapeutic responses remain limited in many solid tumors due to poor and uneven drug distribution within the tumor microenvironment (TME). Here, we evaluated whether co-formulation of an anti-PD-1 antibody (RMP1-14, murine surrogate for pembrolizumab) with Imagent^® microbubble/liposome (MBLP) complexes and ultrasound activation could enhance tumor-specific delivery while reducing systemic exposure. Methods: Immunocompetent MC-38 colorectal tumor-bearing mice (B6(Cg)-Tyrc-2J/J, 7-week-old females) received isotype control, isotype/MBLP/US, RMP1-14 alone, RMP1-14/MBLP, or RMP1-14/MBLP/US. Survival was analyzed by Kaplan–Meier curves, tumor necrosis by H&E staining, antibody biodistribution by immunohistochemistry, and tumor perfusion by laser speckle imaging. Results: No significant differences in tumor size or body weight were observed between groups. Survival analysis showed significant improvements in the RMP1-14 (p = 0.013) and RMP1-14/MBLP/US (p = 0.047) groups versus isotype controls, with the RMP1-14/MBLP/US group achieving the longest mean survival (57.8 days vs. 26.5 days for RMP1-14 alone) and complete tumor regression in 2/8 mice. The RMP1-14/MBLP/US group demonstrated significantly greater tumor necrosis than all other groups. Immunohistochemical analysis confirmed a 6.1-fold increase in intratumoral antibody accumulation with MBLP/US versus RMP1-14 alone (p = 0.0003), alongside significantly reduced off-target exposure in spleen, liver, kidney, and heart. Laser speckle imaging revealed a transient ~30% increase in tumor perfusion during MBLP/US treatment, consistent with cavitation-mediated hemodynamic effects. Conclusions: These findings demonstrate that MBLP/US co-formulation enhances intratumoral delivery of checkpoint inhibitors, improves survival, and reduces systemic organ exposure, representing a promising platform to improve the efficacy and safety profile of antibody-based immunotherapy. Full article

Antibody–drug conjugates (ADCs) are a pivotal technology for precision cancer therapy, harnessing the synergistic effects of antibody targeting and toxin delivery. However, traditional ADCs encounter limitations in efficacy that stem from tumor resistance, heterogeneity, and intense target competition. Dual-payload ADCs (DP-ADCs) represent a promising solution to these challenges, as they leverage dual mechanisms of action that mitigate acquired drug resistance and enhance adaptability to tumor heterogeneity. The complex structure of DP-ADCs presents substantial quality control hurdles. In this manuscript, we review the current payload selection and conjugation strategies of DP-ADCs and examine recent advances in quality control research. Specifically, we analyze the analytical challenges related to the quantification of free toxins, the determination of the total antibody content, and the characterization of the drug-to-antibody ratio and its distribution. Ultimately, the aim of this work is to provide valuable guidance for future DP-ADC quality control analyses to facilitate their clinical translation and application. Full article