Drug Delivery Strategies Research Articles

Ternary Thermosensitive Hydrogel‐Encapsulated Macrolactam Heneicosapeptide Eliminates Epidermal Multidrug‐Resistant Bi‐Microbial Colonization

AbstractSuperbug epidemic has rendered antibiotic therapeutics increasingly ineffective. Worse still, there are few applicable medication regimens for polymicrobial infections caused by two or more multidrug‐resistant bacteria. Herein, a panel of antibacterial cyclic peptides are designed and synthesized and the lead compound cyclo‐zp80r shows favorable activities against a broad spectrum of bacteria. Encouragingly, it exhibited a strong bactericidal effect against two important epidermic species Pseudomonas aeruginosa and Staphylococcus aureus for both single‐ and co‐infections. The peptide cyclo‐zp80r is proposed to destroy the membrane structures of both Gram‐negative and Gram‐positive bacteria, inducing a variety of physiological disorders. To better adapt to topical administration of this novel antibacterial agent, a hydrogel formulation consisting of poloxamer 407, poloxamer 188, and hyaluronic acid is optimized. This ternary hydrogel system is able to form in situ gel at skin temperature. Encapsulated peptide molecules are released steadily in both human skin ex vivo model and mouse wound in vivo model to treat bi‐microbial infection. This work systematically investigates the design, synthesis, antibacterial mechanism of a novel cyclic peptide, and its drug delivery strategy for topical wound infection, offering a promising therapeutics to treat multidrug‐resistant polymicrobial wound infections.

Application of nanoultrasonography in early diagnosis of coronary heart disease.

Coronary heart disease (CHD) remains one of the leading causes of mortality and disability globally. In recent years, nanoultrasonography technology has demonstrated significant potential in both the diagnosis and treatment of CHD. This review summarizes the latest research advancements in nanoultrasonography within the field of coronary heart disease, focusing on its applications in early diagnosis, targeted drug delivery, imaging techniques, and treatment strategies. We explore the working principles of nanoultrasonography, its technological advantages, and the challenges faced in clinical applications. The aim is to provide guidance for future research and clinical practice in this promising area.

Green Synthesis Techniques for Sulphur Nanoparticles: Current Methods and Future Perspectives

Abstract: In recent years, cancer has emerged as a significant public health challenge, prompting extensive research into the development of innovative anticancer therapies capable of selectively inducing cell death or halting the proliferation of cancer cells. Harnessing the distinctive characteristics of nanomaterials, advancements in nanotechnology have played a pivotal role in the progression of nanomedicine for cancer treatment. Various nanomaterials, such as gold, silver, silica, and carbon nanoparticles, have been investigated for their potential in drug delivery systems. Meanwhile, sulfur, with its abundant chemically diverse organic and inorganic compounds exhibiting a range of biological functions from antioxidant properties to antibacterial and anticancer capabilities, has garnered significant attention. Sulphur nanoparticles (SNPs) find widespread application in diverse fields such as lithium sulfur batteries, sulphur-based photocatalysts, and antimicrobial agents. Despite their extensive utilization in non-biomedical domains, such as drug delivery and cancer prevention strategies, SNPs face challenges when employed for biomedical purposes. Concerns include toxicity, limited reactivity, and the substantial particle size of SNPs, which hinder their effectiveness as drug delivery carriers. To overcome these obstacles, surface modifications of SNPs are necessary to enhance their biomedical applicability.

Recent Updates in Inhalable Drug Delivery System against Various Pulmonary Diseases: Challenges and Future Perspectives.

In the current scenario, pulmonary disease has become a prime burden for morbidity and mortality alongside tremendous social and economic crises throughout the world. Numerous conventional drug delivery system and treatment approach targeting the respiratory region has been driven out. However, effective and accurate recovery has not been achieved yet. In this regard, nanotechnological- based inhalable drug delivery strategy including polymeric, lipidic, or metallic-based respirable microparticles plays an indispensable role in circumventing numerous challenges faced during traditional treatment. Excellent aerodynamic performance leads to enhanced lung targetability, reduced dosing frequency and hence systemic toxicities, as well as improved pharmaceutical attributes, and therefore pharmacokinetic profiles are interminable factors associated with nanotechnologicalbased inhalable delivery. In this review, we comprehensively explored recent advancements in nanotechnologically engineered inhalable formulations targeting each of the mentioned pulmonary diseases. Moreover, we systematically discussed possible respiratory or systemic toxicities about the indeterminate and undefined physicochemical characteristics of inhaled particles.

Ultrasound-triggered drug release and cytotoxicity of microbubbles with diverse drug attributes

Ultrasound (US)-triggered cavitation of drug-loaded microbubbles (MBs) represents a promising approach for targeted drug delivery, with substantial benefits attainable through precise control over drug release dosage and form. This study investigates Camptothecin-loaded MBs (CPT-MBs) and Doxorubicin-loaded MBs (DOX-MBs), focusing on how properties such as hydrophilicity, hydrophobicity, and charged functional groups affect their interaction with the lipid surfaces of MBs, thereby influencing the fundamental characteristics and acoustic properties of the drug-loaded MBs. In comparison to DOX-MBs, CPT-MBs showed larger MB size (2.2 ± 0.3 and 1.4 ± 0.1 μm, respectively), a 2-fold increase in drug loading, and an 18 % reduction in leakage after 2 h at 37℃. Under 1 MHz US with a 100 ms pulse repetition interval (PRI), 1000 cycles, 5-minute duration, and 550 kPa acoustic pressure, CPT-MBs undergo inertial cavitation, while DOX-MBs undergo stable cavitation. Drug particles released from these MBs under US-induced cavitation were analyzed using dynamic light scattering, NanoSight, cryo-electron microscopy, and density gradient ultracentrifugation. Results showed that CPT-MBs mainly release free CPT, while DOX-MBs release multilayered DOX-lipid aggregates. The cytotoxicity to C6 cells induced by US-triggered cavitation of these two types of MBs also differed. DOX-lipid aggregates delayed initial uptake, leading to less pronounced short-term (2 h) effects compared to the rapid release of free CPT from CPT-MBs. These findings underscore the need to optimize drug delivery strategies by fine-tuning MB composition and US parameters to control drug release kinetics and achieve the best tumoricidal outcomes.

From Conventional to Cutting-edge: A Comprehensive Review on Drug Delivery Systems

: The essential need for efficacious conveyance of therapeutics to specific tissues or cells, refinement of drug formulations, and the scalability of industrial production drives the pre-sent-day demand for enhanced drug delivery systems (DDS). Newly devised drugs often exhibit suboptimal biopharmaceutical properties, resulting in diminished patient adherence and adverse side effects. The paramount importance of site-specific drug delivery lies in its capacity to facili-tate the targeted administration of diverse therapeutic agents, catering to both localized ailments and systemic treatments. Alongside targeted drug delivery strategies encompassing ligand-based targeting and stimuli-responsive systems, the advent of cutting-edge nanotechnologies such as nanoparticles, liposomes, and micelles has marked a paradigm shift. Additionally, personalized medicines have emerged as a consequential facet of drug delivery, emphasizing the customization of treatment approaches. Researchers have explored an excess of methodologies in the advance-ment of these formulation technologies, including stimuli-responsive drug delivery, 3D printing, gene delivery, and various other innovative approaches. This comprehensive review aims to pro-vide a holistic understanding of the past, present, and future of drug delivery systems, offering in-sights into the transformative potential of emerging technologies.

Atherogenic low-density lipoprotein and cardiovascular risk.

Despite reductions in low-density lipoprotein (LDL) cholesterol (LDLc), residual cardiovascular risk remains due to factors beyond lipoprotein levels, such as LDL particle count, size, electronegativity and modifications. Technological advances allow detailed profiling of LDL particles, offering potential biomarkers for diagnosis, prognosis, and treatment of cardiovascular disease (CVD). The aim of this review is to provide an updated overview of the state of knowledge in the field of LDL atherosclerotic role, which is evolving rapidly due to technological advances in biomarker measurement and applications. While small dense LDL has been linked to increased CVD risk, current approaches favor a comprehensive evaluation of all lipoprotein subtypes, as this is a more feasible and standardized method. The atherogenic potential of circulating oxidized LDL (oxLDL) may be the key factor in the onset and progression of atherosclerosis. Thus, elevated oxLDL levels are recognized as a marker of increased CVD risk in both general and high-risk populations, although further research is needed to clarify some conflicting findings. The oxidized LDL receptor 1 (LOX-1) has emerged as a promising target for immunotherapy and innovative drug delivery strategies to modulate atherosclerosis. A panel of biomarkers related to LDL atherogenicity may help predict future ischemic events. An atheroprotective diet and increased physical activity could improve LDL oxidation. OxLDL has become a target for immunomodulatory antiatherosclerosis therapy and delivering LDL-based nanocarriers holds promise for both imaging and therapeutics.

Based on sodium alginate coatings and dendritic copolymeric modification of curcumin delivery system: pH-sensitive nanospheres and strong tumor cytotoxicity

This study aims to construct a novel drug delivery strategy to address the poor bioavailability and biostability of curcumin. A curcumin delivery strategy, basing on post-polymerization modification of poly(2-vinyl-4,4-dimethyl azlactone) to obtain conjugates of curcumin and dendritic polymers, combined with sodium alginate coating is reported. The curcumin-polymer conjugates were shown to have good fluorescence properties with fluorescence quantum yields of 0.486 and 0.470, respectively. The composites were characterized as spherical nanoparticles with a desirable particle size of 221.7 nm and massive negatively charged surfaces. These aesthetic properties make it an acceptable drug delivery and release vehicle. In vitro release experiments showed that release of curcumin from the conjugates was controllable and acid-sensitive, which is expected to guide delivery targeting to cancer sites. In addition, biodistribution studies of the gastrointestinal tract of mice showed high levels of exposure. The results of cell imaging showed that conjugates have strong permeability to cancer cell membranes. They have been shown to have strong targeting and inhibitory effects on a variety of cancer cells, with an inhibition rate of up to about 90 %. Therefore, such novel vector designs show great potential in drug delivery mechanism research and cancer therapy.

Palindrome-mediated DNA nanotubes with cell-specific aptamers to improve targeted antitumor effects and reduce toxicity on non-small cell lung cancer.

Chemotherapy is regarded as a widely used and effective treatment strategy for lung cancer, although most conventional chemotherapeutics cause severe toxic side-effects due to their indiscriminate attacks on both cancerous and normal cells. Although nucleic acid nanomaterials are emerging as a promising drug delivery strategy, their clinical applications are limited by rapid degradation by nucleases and difficulties in targeting cancer cells. In this study, we have developed a Rhein-loaded aptamer-based DNA nanotube (DNT-S6@Rhein) for the targeted and efficient therapy of non-small cell lung cancer. Through the palindrome segments, two specified oligonucleotides were hybridized and folded into the well-defined nanotubes (DNT-S6), with the S6 aptamer distributed outside. The obtained nanotubes exhibited excellent serum stability and targeting ability towards A549 cells due to the firm structure and decoration of the S6 aptamer. Rhein, as an antitumor drug and DNA intercalator, can be effectively inserted into the DNT-S6. The drug-loaded nanotubes rapidly disassembled in intracellular environment and then the released Rhein was found to activate cellular apoptotic process and significantly suppress proliferation, migration and invasion of A549 cells. Moreover, DNT-S6@Rhein could efficiently accumulate in tumor regions, offering compelling therapeutic efficacy and biocompatibility under both in vitro and in vivo settings. These findings of this study provide a promising strategy for mitigating the inevitable systemic side-effects of chemotherapy and expand the potential application of DNA nanostructure on targeted drug delivery.

Assessing Therapeutic Nanoparticle Accumulation in Tumors Using Nanobubble-Based Contrast-Enhanced Ultrasound Imaging.

This study explores the challenges associated with nanoparticle-based drug delivery to the tumor parenchyma, focusing on the widely utilized enhanced permeability and retention effect (EPR). While EPR has been a key strategy, its inconsistent clinical success lacks clear mechanistic understanding and is hindered by limited tools for studying relevant phenomena. This work introduces an approach that employs multiparametric dynamic contrast-enhanced ultrasound (CEUS) with a nanoscale contrast agent for noninvasive, real-time examination of tumor microenvironment characteristics. We demonstrate that CEUS imaging can: (1) evaluate tumor microenvironment features, (2) be used to help predict the distribution of doxorubicin-loaded liposomes in the tumor parenchyma, and (3) be used to predict nanotherapeutic efficacy. CEUS using nanobubbles (NBs) was carried out in two tumor types of high (LS174T) and low (U87) vascular permeability. LS174T tumors consistently showed significantly different time intensity curve (TIC) parameters, including area under the rising curve (AUCR, 2.7×) and time to peak intensity (TTP, 1.9×) compared to U87 tumors. Crucially, a recently developed decorrelation time (DT) parameter specific to NB CEUS dynamics successfully predicted the distribution of doxorubicin-loaded liposomes within the tumor parenchyma (r = 0.86 ± 0.13). AUCR, TTP, and DT were used to correlate imaging findings to nanotherapeutic response with 100% accuracy in SKOV-3 tumors. These findings suggest that NB-CEUS parameters can effectively discern tumor vascular permeability, serving as a biomarker for identifying tumor characteristics and predicting the responsiveness to nanoparticle-based therapies. The observed differences between LS174T and U87 tumors and the accurate prediction of nanotherapeutic efficacy in SKOV-3 tumors indicate the potential utility of this method in predicting treatment efficacy and evaluating EPR in diseases characterized by pathologically permeable vasculature. Ultimately, this research contributes valuable insights into refining drug delivery strategies and assessing the broader applicability of EPR-based approaches.

Cholesterol Conjugated Elastin-like Recombinamers: Molecular Dynamics Simulations, Conformational Changes, and Bioactivity.

Current models for elastin-like recombinamer (ELR) design struggle to predict the effects of nonprotein fused materials on polypeptide conformation and temperature-responsive properties. To address this shortage, we investigated the novel functionalization of ELRs with cholesterol (CTA). We employed GROMACS computational molecular dynamic simulations complemented with experimental evidence to validate the in silico predictions. The ELRCTA was biosynthesized and characterized by using fluorescence assays, circular dichroism, dynamic light scattering, and differential scanning calorimetry. The in silico and in vitro data showed that CTA promotes the formation of intramolecular hydrogen bonds that favor β-sheet secondary structures. Compared with an unmodified ELRVKV, CTA enhanced the hydrophobicity and stability of the system, allowing the formation of monodisperse nanoaggregates at physiologically relevant temperatures. Importantly, calorimetry assays revealed that ELRCTA interacted and intercalated with the lipid bilayers of the DPPC liposomes. To demonstrate the implications of these changes for biomedical applications, ELRCTA and DPPC-ELRCTA hybrid nanoparticles were tested with cancer and immune cell lines. Interactions with the cell membranes demonstrated a synergistic effect of the composition and size of the modified recombinamer aggregates on the internalization. The results indicated the potential use of ELR-based nanoparticles for localized and systemic drug delivery. This work sets a new precedent to design elastin-inspired biomaterials with predictable self-assembly properties and develop novel drug delivery strategies.

The Application of Nano Drug Delivery Systems in Female Upper Genital Tract Disorders.

The prevalence of female reproductive system disorders is increasing, especially among women of reproductive age, significantly impacting their quality of life and overall health. Managing these diseases effectively is challenging due to the complex nature of the female reproductive system, characterized by dynamic physiological environments and intricate anatomical structures. Innovative drug delivery approaches are necessary to facilitate the precise regulation and manipulation of biological tissues. Nanotechnology is increasingly considered to manage reproductive system disorders, for example, nanomaterial imaging allows for early detection and enhances diagnostic precision to determine disease severity and progression. Additionally, nano drug delivery systems are gaining attention for their ability to target the reproductive system successfully, thereby increasing therapeutic efficacy and decreasing side effects. This comprehensive review outlines the anatomy of the female upper genital tract by highlighting the complex mucosal barriers and their impact on systemic and local drug delivery. Advances in nano drug delivery are described for their sustainable therapeutic action and increased biocompatibility to highlight the potential of nano drug delivery strategies in managing female upper genital tract disorders.

Pioneering Advances and Innovative Applications of Mesoporous Carriers for Mitochondria-Targeted Therapeutics.

Mitochondria, known as the cell's powerhouse, play a critical role in energy production, cellular maintenance, and stemness regulation in non-cancerous cells. Despite their importance, using drug delivery systems to target the mitochondria presents significant challenges due to several barriers, including cellular uptake limitations, enzymatic degradation, and the mitochondrial membranes themselves. Additionally, barriers in the organs to be targetted, along with extracellular barriers formed by physiological processes such as the reticuloendothelial system, contribute to the rapid elimination of nanoparticles designed for mitochondrial-based drug delivery. Overcoming these challenges has led to the development of various strategies, such as molecular targeting using cell-penetrating peptides, genomic editing, and nanoparticle-based systems, including porous carriers, liposomes, micelles, and Mito-Porters. Porous carriers stand out as particularly promising candidates as drug delivery systems for targeting the mitochondria due to their large pore size, surface area, and ease of functionalisation. Depending on the pore size, they can be classified as micro-, meso-, or macroporous and are either ordered or non-ordered based on both size and pore uniformity. Several methods are employed to target the mitochondria using porous carriers, such as surface modifications with polyethylene glycol (PEG), incorporation of targeting ligands like triphenylphosphonium, and capping the pores with gold nanoparticles or chitosan to enable controlled and triggered drug delivery. Photodynamic therapy is another approach, where drug-loaded porous carriers generate reactive oxygen species (ROS) to enhance mitochondrial targeting. Further advancements have been made in the form of functionalised porous silica and carbon nanoparticles, which have demonstrated potential for effective drug delivery to mitochondria. This review highlights the various approaches that utilise porous carriers, specifically focusing on silica-based systems, as efficient vehicles for targeting mitochondria, paving the way for improved drug delivery strategies in mitochondrial therapies.

Chitosan nanoparticle encapsulation improves the effect of donepezil on impaired memory in an amnesia mouse model

ObjectiveAmnesia is one of the most important parts of Alzheimer’s disease (AD). Among the conventional and controlled drug delivery strategies for the pharmacological treatment of AD, nanotechnology-based systems targeting pharmacologically active molecules near their site of action seem to be the most effective. So, this study aimed to investigate the nano-chitosan encapsulated Donepezil on impaired memory in a mouse model of AD.MethodThis study was conducted on 232 male NMRI mice (30–35 mg) and carried out in three phases to identify the optimal ethanol dose for amnesia induction; to evaluate the effect of donepezil alone and donepezil enclosed in chitosan nano-particles after ethanol-induced amnesia. The effect of treatment was evaluated in an inhibitory passive avoidance apparatus. The data was recorded and analyzed in GraphPad Prism software using ANOVA and Tukey post hoc test. p < 0.05 was considered as the first significant level.ResultsIntraperituneally (IP) injection of 0.25, 0.5, 0.75, or 1 mg/kg non-capsulated or chitosan-encapsulated donepezil significantly improved impaired memory compared to that of the controls. However, at doses of 0.25 and 0.5 mg/kg, nano-chitosan-encapsulated donepezil had significantly greater effects than non-encapsulated donepezil (p < 0.0001 and p < 0.05, respectively).ConclusionEncapsulation could reduce the required dose to achieve the desired memory improvement effect. Further studies are required to understand the efficiency of nano-chitosan-encapsulated donepezil administered via different delivery routes and the underlying mechanism of its improved effect on impaired memory.

Inflammation-Responsive Functional Core-Shell Micro-Hydrogels Promote Rotator Cuff Tendon-To-Bone Healing by Recruiting MSCs and Immuno-Modulating Macrophages in Rats.

Rotator cuff injuries often necessitate surgical intervention, but the outcomes are often unsatisfactory. The underlying reasons can be attributed to multiple factors, with the intricate inflammatory activities and insufficient presence of stem cells being particularly significant. In this study, an innovative inflammation-responsive core-shell micro-hydrogel is designed for independent release of SDF-1 and IL-4 within a single delivery system to promote tendon-to-bone healing by recruiting MSCs and modulating M2 macrophages polarization. First, a MMP-2 responsive hydrogel loaded with IL-4 (GelMA-MMP/IL-4) is synthesized by cross-linking gelatin methacrylate (GelMA) with MMP-2 substrate peptide. Then, the resulting core particles are coated with a shell of chitosan /SDF-1/hyaluronic acid (CS/HA/SDF-1) using the layer-by-layer electrostatic deposition method to form a core-shell micro-hydrogel composite. The core-shell micro-hydrogel shows sustained release of SDF-1 and MMP-2-responsive release of IL-4 associated in situ MSCs homing and smart inflammation regulation by promoting M2 macrophages polarization. Additionally, by injecting these micro-hydrogels into a rat rotator cuff tear and repair model, notable improvements of fibrocartilage layer are observed between tendon and bone. Notably, this study presents a new and potentially powerful environment-responsive drug delivery strategy that offers valuable insights for regulating the intricate micro-environment associated with tissue regeneration.

Effect of Microbubble Size, Composition, and Multiple Sonication Points on Sterile Inflammatory Response in Focused Ultrasound-Mediated Blood-Brain Barrier Opening.

Blood-brain barrier opening (BBBO) using focused ultrasound (FUS) and microbubbles (MBs) has emerged as a promising technique for delivering therapeutics to the brain. However, the influence of various FUS and MB parameters on BBBO and subsequent sterile inflammatory response (SIR) remains unclear. In this study, we investigated the effects of MB size and composition, as well as the number of FUS sonication points, on BBBO and SIR in an immunocompetent mouse model. Using MRI-guided MB + FUS, we targeted the striatum and assessed extravasation of an MRI contrast agent to assess BBBO and RNaseq to assess SIR. Our results revealed distinct effects of these parameters on BBBO and SIR. Specifically, at a matched microbubble volume dose (MVD), MB size did not affect the extent of BBBO, but smaller (1 μm diameter) MBs exhibited a lower classification of SIR than larger (3 or 5 μm diameter) MBs. Lipid-shelled microbubbles exhibited greater BBBO and a more pronounced SIR compared to albumin-shelled microbubbles, likely owing to the latter's poor in vivo stability. As expected, increasing the number of sonication points resulted in greater BBBO and SIR. Furthermore, correlation analysis revealed strong associations between passive cavitation detection measurements of harmonic and inertial MB echoes, BBBO, and the expression of SIR gene sets. Our findings highlight the critical role of MB and FUS parameters in modulating BBBO and subsequent SIR in the brain. These insights inform the development of targeted drug delivery strategies and the mitigation of adverse inflammatory reactions in neurological disorders.

Evolutionary Dynamics-Driven Learning of Optimal Decisions for Nonlinear System: Extend-Policy Iterative Algorithm.

An extend-policy iterative algorithm is proposed for solving the ecological evolving-lung cancer cells growth inhibition optimal drug delivery scheme. With the analysis of the cell proliferation-apoptosis process of lung cancer cells with primitive immune system and external drug interventions, such as chemotherapeutic drugs and immunological agents, a model of ecological containment of lung cancer cells mimicking injection labeling is constructed. The HJB equation for biological tissue damage has also been established by considering the concentration of lung cancer cells in the blood and the amount of drug administered. The final simulation experiment proved the effectiveness of the drug delivery scheme.

Advancing Polyphenol-Based Nanomedicine for Inflammatory Bowel Disease: Challenges and Opportunities.

Oxidative stress, characterized by excessive production of reactive oxygen species (ROS), is a critical factor in the progression of inflammatory bowel disease (IBD) and presents a potential therapeutic target. Anti-oxidant therapy, aimed at mitigating excessive ROS, is emerging as a cornerstone in IBD treatment. Nanomaterials with robust anti-oxidant properties offer promise by inhibiting inflammation through ROS scavenging, enhancing IBD therapeutic efficacy. Recent focus in ROS scavenging has centered on metal oxide nanoenzymes and polyphenol-based nanomaterials. The primary challenges are the catalytic efficiency of nanoenzymes and the functional integration of these nanomaterials with therapeutic agents. Polyphenols, natural plant extracts, have garnered significant interest due to their potent anti-oxidant properties and unique catechol groups that interact with biomolecules such as proteins and nucleic acids. The strong metal ion chelating ability of catechols enriches the structure and functionality of nanomaterials, improving the physicochemical properties of nanocarriers and enabling innovative designs of multifunctional drug delivery systems (DDSs). Research on polyphenol-based DDSs has expanded to include agents like epigallocatechin gallate, curcumin, resveratrol, tannic acid, and polydopamine. These nanocarriers and anti-oxidants, which incorporate polyphenols, have demonstrated potential anti-oxidant properties in novel DDSs as therapeutic agents to reduce inflammation and as essential components of drug carriers. This review focuses on the design and application of natural polyphenol-based anti-oxidant nanomaterials for IBD treatment, offering a comprehensive discussion on the use of polyphenols in DDSs and the potential challenges posed by their diverse roles in innovative drug delivery strategies, including their impact on the physical and chemical properties of DDSs.

Application of Polymers as Drug Nanocarriers in the Oral Treatment of Ulcerative Colitis

AbstractUlcerative colitis (UC) is a chronic non‐specific inflammatory disease of the intestines with a high prevalence. Polymer‐prepared nanoparticles are well‐targeted, highly biocompatible, and have high potential for personalized therapy. Polymer nanoparticles are able to achieve localized therapy through their unique design. First, this review compares the advantages and disadvantages of natural and synthetic polymeric materials as well as describes the application of polymeric nanoparticles in UC therapy. Then, the preparation, characterization methods, and current challenges of common polymer nanoparticles are presented. Next, one‐by‐one examples of polymer nanoparticle‐targeted drug delivery strategies for the treatment of UC are presented. In addition, polymer nanoparticle‐based therapeutic approaches for UC, including anti‐inflammatory therapies, reactive oxygen species scavenging therapies, and intestinal flora modulation therapies, are presented. Finally, future research directions for polymer nanoparticles in UC therapy are discussed and current challenges are identified. The aim of this paper is to provide valuable references and guidance for researchers to design and develop novel UC therapies.

Targeting the undruggable in glioblastoma using nano-based intracellular drug delivery.

Glioblastoma (GBM) is a highly prevalent and aggressive brain tumor in adults with limited treatment response, leading to a 5-year survival rate of less than 5%. Standard therapies, including surgery, radiation, and chemotherapy, often fall short due to the tumor's location, hypoxic conditions, and the challenge of complete removal. Moreover, brain metastases from cancers such as breast and melanoma carry similarly poor prognoses. Recent advancements in nanomedicine offer promising solutions for targeted GBM therapies, with nanoparticles (NPs) capable of delivering chemotherapy drugs or radiation sensitizers across the blood-brain barrier (BBB) to specific tumor sites. Leveraging the enhanced permeability and retention effect, NPs can preferentially accumulate in tumor tissues, where compromised BBB regions enhance delivery efficiency. By modifying NP characteristics such as size, shape, and surface charge, researchers have improved circulation times and cellular uptake, enhancing therapeutic efficacy. Recent studies show that combining photothermal therapy with magnetic hyperthermia using AuNPs and magnetic NPs induces ROS-dependent apoptosis and immunogenic cell death providing dual-targeted, immune-activating approaches. This review discusses the latest NP-based drug delivery strategies, including gene therapy, receptor-mediated transport, and multi-modal approaches like photothermal-magnetic hyperthermia combinations, all aimed at optimizing therapeutic outcomes for GBM.