Ferroptosis: the potential key roles in idiopathic pulmonary fibrosis

Idiopathic pulmonary fibrosis (IPF) is a chronic progressive interstitial lung disease characterized by recurrent injury to alveolar epithelial cells, epithelial-mesenchymal transition, and fibroblast activation, which leads to excessive deposition of extracellular matrix (ECM) proteins. However, effective preventative and therapeutic interventions are currently lacking. Ferroptosis, a unique form of iron-dependent lipid peroxidation-induced cell death, exhibits distinct morphological, physiological, and biochemical features compared to traditional programmed cell death. Recent studies have revealed a close relationship between iron homeostasis and the pathogenesis of pulmonary interstitial fibrosis. Ferroptosis exacerbates tissue damage and plays a crucial role in regulating tissue repair and the pathological processes involved. It leads to recurrent epithelial injury, where dysregulated epithelial cells undergo epithelial-mesenchymal transition via multiple signaling pathways, resulting in the excessive release of cytokines and growth factors. This dysregulated environment promotes the activation of pulmonary fibroblasts, ultimately culminating in pulmonary fibrosis. This review summarizes the latest advancements in ferroptosis research and its role in the pathogenesis and treatment of IPF, highlighting the significant potential of targeting ferroptosis for IPF management. Importantly, despite the rapid developments in this emerging research field, ferroptosis studies continue to face several challenges and issues. This review also aims to propose solutions to these challenges and discusses key concepts and pressing questions for the future exploration of ferroptosis.

Hypocrellin-Mediated PDT: A Systematic Review of Its Efficacy, Applications, and Outcomes

Photodynamic therapy (PDT) is a light-activated treatment that generates reactive oxygen species (ROS) to induce microbial cell death. As resistance to traditional antibiotics intensifies globally, PDT has emerged as a promising alternative or adjunctive antimicrobial strategy. Among various photosensitizers, Hypocrellin, a perylenequinone compound, has shown high ROS yield and broad-spectrum activity against bacteria and fungi. This systematic review evaluated the efficacy, safety, and therapeutic potential of Hypocrellin-mediated antimicrobial photodynamic therapy. Following PRISMA 2020 guidelines, a comprehensive literature search was conducted in PubMed, Embase, Scopus, and the Cochrane Library for studies published between 2015 and 2025. Eligible studies included in vitro and preclinical in vivo research using Hypocrellin as a photosensitizer. Quality and risk of bias were assessed using a structured nine-item checklist. Ten eligible studies, all conducted in China, were included. Hypocrellin-mediated aPDT significantly reduced microbial loads in both planktonic and biofilm states of resistant pathogens such as Candida albicans, Candida auris, Cutibacterium acnes, and Staphylococcus aureus. The treatment acted via ROS-mediated apoptosis, membrane disruption, and mitochondrial dysfunction, with minimal cytotoxicity to mammalian cells. Studies also reported enhanced efficacy when Hypocrellin was incorporated into nanocarriers, polymeric scaffolds, or combined with chemodynamic or photothermal therapies. However, substantial heterogeneity was observed in Hypocrellin concentrations, irradiation parameters, and outcome measures. Hypocrellin-based PDT exhibits potent antimicrobial activity and favorable safety in preclinical settings, supporting its potential as an alternative to conventional antibiotics. However, standardized treatment protocols and robust clinical trials are urgently needed to validate long-term safety and translational feasibility. These findings underscore the broader promise of PDT in addressing drug-resistant infections through a mechanism unlikely to induce resistance.

Advancements in Nanocarrier Systems for Nose-to-Brain Drug Delivery

In recent decades, nose-to-brain drug delivery has shown effectiveness in treating many central nervous system diseases. Intranasally administered drugs can be delivered to the brain through the olfactory and trigeminal pathways that bypass the blood-brain barrier. However, nose-to-brain drug delivery is challenging due to the inadequate nasal mucosa absorption of drugs and the short retention time of the intranasal formulations. These problems can be minimized through the use of nano-drug delivery systems, such as micelles, polymeric nanoparticles, nanoemulsions, liposomes, solid lipid nanoparticles, and nanostructured lipid carriers. They can enhance the drug's bioavailability in the brain via increases in drug solubility, permeation, and stability. Nose-to-brain nano-drug delivery systems have been evaluated in vivo by a number of research groups. This review aims to provide an overview of nose-to-brain delivery and recent advances in the development of nano-drug delivery systems for delivering drugs from the nose to the brain to improve the treatment of some central nervous system diseases.

Caspase-independent cell death in lung cancer: from mechanisms to clinical applications

Caspase-independent cell death (CICD) has recently become a very important mechanism in lung cancer, in particular, to overcome a critical failure in apoptotic cell death that is common to disease progression and treatment failures. The pathways involved in CICD span from necroptosis, ferroptosis, mitochondrial dysfunction, and autophagy-mediated cell death. Its potential therapeutic applications have been recently highlighted. Glutathione peroxidase 4 (GPX4) inhibition-driven ferroptosis has overcome drug resistance in non-small cell lung cancer (NSCLC). In addition, necroptosis involving RIPK1 and RIPK3 causes tumor cell death and modulation of immune responses in the tumor microenvironment (TME). Mitochondrial pathways are critical for CICD through modulation of metabolic and redox homeostasis. Ferroptosis is amplified by mitochondrial reactive oxygen species (ROS) and lipid peroxidation in lung cancer cells, and mitochondrial depolarization induces oxidative stress and leads to cell death. In addition, mitochondria-mediated autophagy, or mitophagy, results in the clearance of damaged organelles under stress conditions, while this function is also linked to CICD when dysregulated. The role of cell death through autophagy regulated by ATG proteins and PI3K/AKT/mTOR pathway is dual: to suppress tumor and to sensitize cells to therapy. A promising approach to enhancing therapeutic outcomes involves targeting mechanisms of CICD, including inducing ferroptosis by SLC7A11 inhibition, modulating mitochondrial ROS generation, or combining inhibition of autophagy with chemotherapy. Here, we review the molecular underpinnings of CICD, particularly on mitochondrial pathways and their potential to transform lung cancer treatment.

Study of Natural Dyes' Liposomal Encapsulation in Food Dispersion Model Systems via High-Pressure Homogenization

The aim of this study was to investigate the encapsulation of natural food dyes incorporated into liposomes in terms of particle size, rheological and colour properties, zeta potential, and encapsulation efficiency. The liposomes contained dye substances of anthocyanins from freeze-dried raspberry powder (R), copper complexes of chlorophyllins (C), or commercial-grade β-carotene (B). The phospholipid envelope was composed of sunflower lecithin and carboxymethylcellulose sodium salt as a surface stabilizer treated by high-pressure homogenization. The median particle diameter of R and C systems fluctuated around 200 nm, while B systems showed a broader range of 165-405 nm. The rheological results demonstrated a specific flow behaviour pattern dependent on the rotational shear applied, indicating a flow-induced structural change in the dispersions. Samples were characterized by a translucent profile with relatively high lightness, accompanied by a hue angle (h*) typical of the dye encapsulated. The zeta potential was approx. -30 mV, showing electrokinetically stabilized dispersions. The encapsulation efficiency (EE) varied significantly, with the highest EE observed for anthocyanins, ranging from 36.17 to 84.61%. The chlorophyll encapsulation was the least effective, determined in the range between 1.82 and 16.03%. Based on the suitability index, optimal liposomal formulations were evaluated by means of the Central Composite Design (CCD).

Therapeutic prospects and potential mechanisms of Prdx6: as a novel target in musculoskeletal disorders

With the global population aging, musculoskeletal disorders (MSDs) have posed significant physical and psychological health challenges for patients as well as a substantial economic burden on society. The advancements in conservative and surgical interventions for MSDs have been remarkable in recent years; however, the current treatment modalities still fall short of meeting the optimal requirements of patients. Recently, peroxiredoxin 6 (Prdx6) has gained considerable attention from researchers due to its remarkable antioxidative, anti-inflammatory, and anti-apoptotic properties. It has been found that Prdx6 is involved in multiple system diseases, including MSDs; however, the exact role of Prdx6 in MSDs is still lacking. This study aimed to summarize the structure, regulatory mechanism, and potential function of Prdx6. These findings may demonstrate Prdx6 as a novel target for inhibiting the advancement of MSDs.

Are stabilizers, located on the surface of PLGA nanoparticles, able to modify the protein adsorption pattern?

Poly(lactic-co-glycolic acid) (PLGA) is an FDA-approved, biodegradable, and biocompatible polymer, which makes it a promising starting material for the development of nanoparticles. However, in vivo studies have revealed a short biological half-life due to recognition and consequently internalization of these nanoparticles by cells of the mononuclear phagocyte system, resulting in their accumulation in the liver and spleen. In this study, we analyzed the adsorption pattern of proteins on PLGA nanoparticles after incubation with human plasma and human serum. For this analysis, different nanoparticle stabilizer systems were manufactured, and the adsorbed protein amounts were determined after incubation. Additionally, the adsorbed proteins were identified and enrichment and depletion processes of specific proteins that take place during protein incubation were measured via LC-MS/MS. The results showed a high enrichment of several opsonins on the nanoparticle surface and a depletion of most dysopsonins. Therefore, we hypothesize that an explanation for the unfavorable in vivo behavior of PLGA nanoparticles could be the formation of a biomolecular corona with a preferential adsorption of opsonins. Furthermore, we aimed to analyze whether different stabilizers, located on the surface of PLGA nanoparticles, were able to modify the protein adsorption pattern. Our findings suggest that the use of different stabilizers can influence the amount of total bound proteins on the nanoparticle surface. However, the change of stabilizers has only a minor impact on the composition of the biomolecular corona.

Strategies to Enhance the Therapeutic Efficacy of GLP-1 Receptor Agonists through Structural Modification and Carrier Delivery

Diabetes is a metabolic disorder characterized by insufficient endogenous insulin production or impaired sensitivity to insulin. In recent years, a class of incretin-based hypoglycemic drugs, glucagon-like peptide-1 receptor agonists (GLP-1RAs), have attracted great attention in the management of type 2 diabetes mellitus (T2DM) due to their benefits, including stable glycemic control ability, a low risk of hypoglycemia, and weight reduction for patients. However, like other peptide drugs, GLP-1RAs face challenges such as instability, susceptibility to enzymatic degradation, and immunogenicity, which severely limit their clinical application. In recent years, various strategies have been developed to improve the bioavailability and therapeutic efficacy of GLP-1RAs, including structural modification and carrier-mediated delivery. This article briefly introduces the research and application status of several common GLP-1RAs and their limitations. Taking exendin-4 as an example, we focus on the research progress of improving bioavailability and therapeutic efficacy based on structural modification and carrier delivery strategies, aiming to provide reference for the development of new GLP-1RAs treatment systems.

Exploring the Mechanism of β-Cyclodextrin-Encased Phenolic Acids Functionalized with TPP for Antioxidant Activity and Targeting

Oxidative stress on the mitochondria in a human cell is attributed to several life-risking conditions, and as such, the importance of molecular structures packed with antioxidant properties and structural characteristics to enter the cell to help prevent such stress has been substantially relevant in recent years. In this study, we investigated the antioxidant properties of triphenylphosphonium (TPP)-conjugated phenolic acids encapsulated in β-cyclodextrin (β-CD). We synthesized TPP conjugates of caffeic, coumaric, and cinnamic acids and formed inclusion complexes with β-CD. Our results showed successful encapsulation of TPP conjugates in β-CD with high efficiency. The TPP conjugates maintained antioxidant activity, with slight reductions observed in β-CD complexes. Furthermore, cell viability studies showed low cytotoxicity of the dds. Computational analyses revealed that TPP conjugation preserved the chemical reactivity of the phenolic acids. Molecular dynamics simulations demonstrated stable inclusion complexes with β-CD and the free energy calculations indicated that TPP conjugation significantly enhanced the ability of caffeic acid to translocate across mitochondrial membranes. These results highlight the potential of TPP-conjugated phenolic acids encapsulated in β-CD as effective antioxidants with improved mitochondrial targeting capabilities.

Inhalable liposomal delivery of osimertinib and DNA for treating primary and metastasis lung cancer

Lung cancer remains one of the most common malignancies, and its brain metastases significantly worsen the prognosis for patients. Current treatments for lung cancer face many challenges, including poor drug accumulation and the inability to simultaneously control primary and metastatic tumors. Here, we show that the mRNA-binding protein insulin-like growth factor 3 is crucial for non-small cell lung cancer progression and metastasis. We construct an inhalable nanoliposome system to co-deliver osimertinib and DNA plasmid for gene knockdown. Upon inhalation, these nanoparticles efficiently penetrate pulmonary barriers and accumulate in lungs by mimicking natural lung surfactants. Within tumor cells, released osimertinib inhibits tumor growth, while the DNA triggers the production of engineered exosomes that can travel to the brain to suppress tumors. This strategy effectively inhibits both primary and metastatic tumors while enhancing antitumor immune responses. This work suggests that this inhalable nanomedicine offers a safe and versatile strategy for cancer therapy.

Nanoparticle-Based Dry Powder Inhaler Containing Ciprofloxacin for Enhanced Targeted Antibacterial Therapy

Background: Ciprofloxacin (CIP) is a poorly water-soluble fluoroquinolone-type antibiotic that can be useful in the treatment of lung infections. When the drugs are delivered directly to the lungs, a smaller dosage is needed to achieve the desired effect compared to the oral administration. Moreover, the application of nanoparticles potentially enhances the effectiveness of the treatments while lowering the possible side effects. Therefore, we aimed to develop a "nano-in-micro" structured dry powder inhaler formulation containing CIP. Methods: A two-step preparation method was used. Firstly, a nanosuspension was first prepared using a high-performance planetary mill by wet milling. After the addition of different additives (leucine and mannitol), the solid formulations were created by spray drying. The prepared DPI samples were analyzed by using laser diffraction, nanoparticle tracking analysis, scanning electron microscopy, X-ray powder diffraction, and differential scanning calorimetry. The solubility and in vitro dissolution tests in artificial lung fluid and in vitro aerodynamic investigations (Spraytec® device, Andersen Cascade Impactor) were carried out. Results: The nanosuspension (D50: 140.0 ± 12.8 nm) was successfully prepared by the particle size reduction method. The DPIs were suitable for inhalation based on the particle diameter and their spherical shape. Improved surface area and amorphization after the preparation processes led to faster drug release. The excipient-containing systems were characterized by large lung deposition (fine particle fraction around 40%) and suitable aerodynamic diameter (between 3 and 4 µm). Conclusions: We have successfully formulated a nanosized antibiotic-containing formulation for pulmonary delivery, which could provide a potential treatment for patients with different respiratory infections.

Second harmonic generation-mediated Photodynamic Therapy for Staphylococcus aureus: A novel approach using Bismuth Ferrite-Protoporphyrin IX conjugates

Photodynamic therapy (PDT) is a minimally invasive treatment modality that utilizes photosensitizing agents, light, and molecular oxygen to produce cytotoxic reactive oxygen species (ROS) to treat cancerous cells and bacterial infections. However, the effectiveness of PDT is often limited by the penetration depth of the light used to activate the photosensitizer (PS). We propose an effective method to address this challenge using Second Harmonic Generation (SHG), a nonlinear optical process in which two identical photons combine to form a new photon with double the frequency. This technique enables the utilization of longer wavelengths for enhanced tissue penetration, subsequently converting them into shorter wavelengths that align with the absorption characteristics of the photosensitizer. Thus, to achieve a highly effective production of SHG, we successfully synthesized the Harmonic Nanoparticle (HNP), Bismuth Ferrite (BFO). Subsequently, BFO was conjugated with Protoporphyrin IX (PPIX) to get BFO-PPIX conjugates for PDT treatment. These were exposed to Near Infrared (NIR) femtoseconds pulsed laser with a wavelength of 798 nm. PDT experiments using BFO-PPIX conjugates and an 8-minute irradiation by a 798 nm pulse laser reduced the survival rate of cultured Staphylococcus aureus (S. aureus) bacterial cells to 44.5 % ± 3.4 %. To the best of our knowledge, BFO and BFO-PPIX conjugates have not been used previously for advancing the conventional PDT treatment using SHG for deeper and precise treatment in S. aureus.

Enhanced rivastigmine delivery through nanoemulsion and pyridoxine supplementation: An in-vivo study on Alzheimer's disease intervention

Nanoemulsions are nanostructured material and stabilized colloidal in nature evolved as a highly desirable mechanism for the delivery of drugs. Our objective of the study deals with a successful Rivastigmine (RSG) loaded nanoemulsion which can effectively progress the treatment of AD patients. We developed nanoemulsion containing RSG by combining pyridoxine, an essential vitamin supplement for central nervous system development, with linseed oil, which functioned as the lipophilic phase in the nanoemulsion formulation. The optimal formulation having globular size of 202.3 nm was further evaluated by various analytical techniques, including zeta potential analysis, ATR, DSC, and XRD study. The study utilized the Morris Water Maze (MWM) model to assess the cognitive abilities of Long-Evans rats. The current investigation establishes that the utilization of RSG nanoemulsion incorporating blend of linseed oil and pyridoxine which reduced travel distance in animal mode and can be successfully contribute to therapeutic advancements in patients with AD.

Eupatilin unveiled: An in-depth exploration of research advancements and clinical therapeutic prospects

Eupatilin, a flavonoid found in Artemisia argyi (Compositae) leaves, exhibits robust anti-inflammatory, antioxidant, and anti-tumor properties. Numerous investigations have demonstrated remarkable efficacy of eupatilin across various disease models, spanning digestive, respiratory, nervous, and dermatological conditions. This review aims to provide an overview of recent studies elucidating the mechanistic actions of eupatilin across a spectrum of disease models and evaluate its clinical applicability. The findings herein provide valuable insights for advancing the study of novel Traditional Chinese Medicine compounds and their clinical utilization.

Lipid core-chitosan shell hybrid nanoparticles for enhanced oral bioavailability of sorafenib

Limited aqueous solubility is a major hurdle resulting in poor and variable oral bioavailability, high doses, side effects, and the suboptimal therapeutic efficacy of sorafenib (SRF). In this study, we developed SRF-loaded solid lipid nanoparticles (SRF-SLNs) and lipid core-chitosan shell hybrid nanoparticles (CS-SRF-SLNs) to improve the oral absorption of SRF. SRF-SLNs were prepared using a stearyl alcohol core stabilized with a surfactant mixture, followed by surface decoration with chitosan to form CS-SRF-SLNs. The developed SRF-SLNs and CS-SRF-SLNs displayed uniform and well-separated spherical particles with small particle size (112.2 and 124.6 nm), low PDI (0.114 and 0.148), adequate zeta potential (-18.6 and +21.2 mV) and high encapsulation efficiency (92.0 and 91 %). Thermal and crystallinity studies (DSC and PXRD) confirmed the successful incorporation of SRF into the lipid matrix and its conversion to the amorphous state. The CS-SRF-SLNs demonstrated sustained SRF release in simulated gastric and intestinal fluids with improved aqueous solubility. Following oral administration to rats, CS-SRF-SLNs significantly improved SRF bioavailability compared with SRF-SLNs and SRF dispersion. Collectively, CS-SRF-SLNs were found to be superior to SRF-SLNs owing to their better sustained-release profile and pharmacokinetic parameters, thereby demonstrating their usefulness for oral delivery by minimizing the solubility-related issues of SRF.

Pulmonary delivery of dual-targeted nanoparticles improves tumor accumulation and cancer cell targeting by restricting macrophage interception in orthotopic lung tumors

Despite the recognized potential of inhaled nanomedicines to enhance and sustain local drug concentrations for lung cancer treatment, the influence of macrophage uptake on targeted nanoparticle delivery to and within tumors remains unclear. Here, we developed three ligand-coated nanoparticles for pulmonary delivery in lung cancer therapy: phenylboronic acid-modified nanoparticles (PBA-NPs), PBA combined with folic acid (FA-PBA-NPs), and PBA with mannose (MAN-PBA-NPs). In vitro, MAN-PBA-NPs were preferentially internalized by macrophages, whereas FA-PBA-NPs exhibited superior uptake by cancer cells compared to macrophages. Following intratracheal instillation into mice with orthotopic Lewis lung carcinoma tumors, all three nanoparticles showed similar lung retention. However, MAN-PBA-NPs were more prone to interception by lung macrophages, which limited their accumulation in tumor tissues. In contrast, both PBA-NPs and FA-PBA-NPs achieved comparable high tumor accumulation (∼11.3% of the dose). Furthermore, FA-PBA-NPs were internalized by ∼30% of cancer cells, significantly more than the 10-18% seen with PBA-NPs or MAN-PBA-NPs. Additionally, FA-PBA-NPs loaded with icaritin effectively inhibited the Wnt/β-catenin pathway, resulting in superior anti-tumor efficacy through targeted cancer cell delivery. Overall, FA-PBA-NPs demonstrated advantageous competitive uptake kinetics by cancer cells compared to macrophages, enhancing tumor targeting and therapeutic outcomes.

Lessons learned from the COVID-19 pandemic: the intranasal administration as a route for treatment - a patent review

The COVID-19 pandemic exposed the fragility of today's marketed treatments for respiratory infections. As a primary site of infection, the upper airways may represent a key access route for the control and treatment for these conditions. The present study aims to explore and identify, through a patent review, the novelty of therapies for COVID-19 that use the intranasal route for drug administration. A search was carried out in Wipo and Espacenet, using the descriptors 'COVID-19 OR SARS-CoV 2' AND 'treatment OR therapy' AND NOT 'vaccine OR immunizing' and the classification 'A61K9/0043'. Of the 151 patents identified, we excluded 73 duplicates, and 36 documents that meet the criteria adopted for exclusion (not nasally administered formulations, vaccines, post COVID-19 treatments, uncertain route of administration or form). We identified 78 unique patents on patent databases, of which 42 were selected for this review. The documents revealed the use of the intranasal pathway not only for drug repositioning but also for using plant-derived and biological molecules. Overall, the new formulations explore a variety of known drugs and natural products incorporated in drug carrier systems and devices for drug delivery and administration. Thus, the intranasal route remains a promising strategy for drug delivery, offering direct access to the primary infection site and warranting further exploration.

Donor-Acceptor (Perylenethienyl)Ethylenes as Singlet Oxygen-Photogenerating Viral Inhibitors

The development of broad-spectrum antiviral drugs effective against a wide range of viruses is of significant practical importance. Derivatives of perylene, a pentacyclic aromatic hydrocarbon, demonstrate pronounced antiviral activity. These compounds act primarily as membrane-active singlet oxygen photogenerators, disrupting virions and inhibiting their fusion with the host cell membrane. Modification of the perylene core allows for chemical diversification of antiviral photosensitizers. Additionally, achieving a bathochromic shift of the absorption band is crucial for effective treatment of superficial lesions, as it facilitates deeper tissue penetration of therapeutic light. In this work, donor-acceptor perylenylethylenes and (perylenethienyl)ethylenes were synthesized and evaluated for their spectral properties, singlet oxygen photogeneration, and inhibitory activity against vesicular stomatitis virus (VSV), a representative enveloped virus. Incorporation of a thiophene moiety into the molecule significantly enhanced both the singlet oxygen generation ability and the antiviral activity. These findings provide useful insights into the relationship between the structure, spectral/photochemical properties, and biological activity of perylene-based photosensitizers.

Advancements in nanotechnology for targeted drug delivery in idiopathic pulmonary fibrosis: a focus on solid lipid nanoparticles and nanostructured lipid carriers

OBJECTIVE

This review aims to explore innovative therapeutic strategies, with a particular focus on recent advancements in drug delivery systems using bioinspired nanomaterials such as solid lipid nanoparticles (SLNs) and nanostructured lipid carriers (NLCs) for the idiopathic pulmonary fibrosis (IPF).

SIGNIFICANCE OF THE REVIEW

Current treatments for IPF, including the FDA-approved anti-fibrotic agents pirfenidone and nintedanib, primarily aim to slow disease progression rather than reverse fibrosis. Bioinspired nanomaterials like SLNs and NLCs have shown promise in enhancing the efficacy of anti-fibrotic agents by improving drug solubility, stability, and targeted delivery. These systems not only minimize systemic side effects but also maximize therapeutic impact in lung tissues, offering a new hope for improved patient management and outcomes in this debilitating disease.

KEY FINDINGS

SLNs facilitate sustained drug release and have demonstrated potential in delivering phosphodiesterase type 5 inhibitors effectively to lung cells. NLCs, on the other hand, exhibit superior biocompatibility and controlled release properties, making them suitable for pulmonary applications. Studies indicate that both SLNs and NLCs can enhance the bioavailability of drugs like ciprofloxacin and montelukast, thereby improving treatment outcomes in pulmonary conditions.

CONCLUSION

The integration of nanotechnology into anti-fibrotic therapy represents a significant advancement in addressing the challenges posed by IPF. By leveraging the unique properties of SLNs and NLCs, there is potential to overcome the limitations of current treatments and provide new therapeutic options that offer better management and improved outcomes for patients suffering from this debilitating disease.

Advances in metal-organic framework-based drug delivery systems

Metal-organic frameworks (MOFs) are emerging crystalline porous materials with significant potential in biomedical applications, particularly as drug delivery systems (DDS). MOFs, composed of metal ions or clusters linked by organic ligands, feature large surface areas, adjustable pores, and diverse functionalities. This review comprehensively examines MOFs as advanced DDS, detailing their structures, synthesis, and drug loading mechanisms. We highlight high drug loading capacity and controlled release capabilities of MOF. Developments of design strategies for MOF-based DDS, namely, surface functionalization for targeted delivery and stimuli-responsive MOFs for controlled release, have been discussed and explored. The use of MOFs for delivering therapeutic agents such as small molecules, peptides, proteins, nucleic acids, and cancer drugs is discussed. Challenges addressed include stability, degradation in biological environments, potential toxicity, and scalability. Advances in hybrid MOF-based DDS, integrating MOFs with polymers, lipids, or nanoparticles for improved delivery, are also examined.

Comprehensive Aerodynamic and Physicochemical Stability Evaluations of Nanocrystal-Based Dry Powder Inhalers: The Role of Mannitol and Leucine in Enhancing Performance

Background: Nanocrystals, a carrier-free nanotechnology, offer significant advantages for pulmonary drug delivery by enhancing the dissolution and solubility of poorly soluble drugs while maintaining favorable biological properties and low toxicity. This study aims to investigate the aerodynamic performance and stability of nanocrystal-based dry powders (NC-DPs). Methods: Nanocrystalline suspensions were produced via wet media milling and subjected to stability studies before undergoing nano spray drying. A factorial design was employed to optimize the process parameters. The influence of mannitol and leucine, individually and in combination, was evaluated in terms of aerodynamic properties (Aerodynamic Particle Sizer (APS), in silico modeling) and the physicochemical stability at room temperature (in a desiccator) and accelerated conditions (40 ± 2 °C, 75 ± 5% relative humidity). Results: APS analysis revealed that leucine-containing powders (K-NC-Ls) exhibited the smallest median (1.357 µm) and geometric mean (1.335 µm) particle sizes, enhancing dispersibility. However, in silico results indicated the highest exhaled fraction for K-NC-L, highlighting the need for optimized excipient selection. Although mannitol showed the lowest exhaled fraction, it was mainly deposited in the extra-thoracic region in silico. The mannitol/leucine combination (K-NC-ML) revealed a low exhaled fraction and high lung deposition in silico. Also, K-NC-ML demonstrated superior stability, with a 6% reduction in D[0.5] and a 5% decrease in span overtime. Furthermore, no significant changes in crystallinity, thermal behavior, drug release, or mass median aerodynamic diameter were observed under stress conditions. Conclusions: These findings confirm that combined incorporation of mannitol and leucine in NC-DP formulations enhances stability and aerodynamic performance, making it a promising approach for pulmonary drug delivery.

In silico screening and validation of natural compounds with fabrication and characterization of a lead compound-loaded chitosome for targeting lung fibrosis

Lung fibrosis (LF) is a serious complication with very limited therapeutic options. This study aimed to find a potential compound for targeting LF and develop a chitosome formulation to minimize any inherent drawbacks of the compound and achieve effective drug delivery. In total, 79 natural compounds were screened using an in silico approach against five targeted proteins (3HMG, 6B8Y, 2FAP, 3CQU, and 3DK9). Amongst these, quercetin (QER) exhibited the best efficacy (-14.725 kcal mol-1) and ΔG average (-86.45 ± 6.24) kcal mol-1 against the TGF-β receptor (PDB ID: 6B8Y). In vitro studies revealed that bleomycin-challenged A549 cells showed a fibrosis-like behaviour. Upon treatment with QER, the cell viability decreased owing to a reduction in the mitochondrial membrane potential and increased apoptosis. Furthermore, cell migration was inhibited with an improvement in cellular morphology. A QER-loaded chitosome formulation (QCF) was prepared through modified thin-film hydration. Variables were optimized using a response surface methodology Box-Behnken design. The QCF was further characterized on the basis of microscopic observation, zeta potential, entrapment efficiency, drug release and kinetics and by evaluating the effect of temperature on the QCF. Its zeta potential was +24.83 ± 0.32 mV, while microscopic observation showed that it had a spherical morphology with slightly rough surfaces after chitosan coating. Furthermore, the EE% was determined to be 81.75 ± 0.46%. The QCF also demonstrated a 74.23 ± 1.01% release of QER till 24 h, following Higuchi model kinetics. In conclusion, the in silico and in vitro cell line studies provided evidence for QER as a lead molecule for targeting LF. Moreover, the prepared QCF demonstrated sustained release with prospective QER targeted delivery. However, further extensive research is required to provide a promising strategy for the management of LF in the future.

Incorporation of human β-defensin-1 into immunoliposomes to facilitate targeted autophagy therapy of colon carcinoma

Based on the discovery that human β-defensin-1 (hBD-1) triggers autophagy in colon cancer cells and inhibits proliferation, we proposed the consideration of its druggability. As a protein, its stability, targetability and bioavailability must be improved. Compared with the traditional medicinal chemistry technology, nanotechnology is more economical for increasing the druggability of hBD-1 and can be readily scaled up. Here, we propose an immunoliposome system containing hBD-1 to improve its stability and bioavailability. To enhance its targetability, anti-epidermal growth factor receptor (EGFR) antibodies were conjugated to the liposomal bilayer to produce immunoliposomes that can target EGFR, which is highly expressed in colon cancer cells. Although more studies are needed to support clinical trials and large-scale manufacturing, these immunoliposomes have great potential as therapeutics. Thus, immunoliposomes are suitable nanovesicles to improve the druggability of hBD-1; however, additional basic and translational research of these systems is warranted.

Mannosamine-Engineered Nanoparticles for Precision Rifapentine Delivery to Macrophages: Advancing Targeted Therapy Against Mycobacterium Tuberculosis

Background

Tuberculosis, caused by Mycobacterium tuberculosis (Mtb), remains one of the leading causes of death among infectious diseases. Enhancing the ability of anti-tuberculosis drugs to eradicate Mycobacterium tuberculosis within host cells remains a significant challenge.

Methods

A mannosamine-modified nanoparticle delivery system was developed using poly(lactic-co-glycolic acid) (PLGA) copolymers to enhance the targeted delivery of rifapentine (RPT) to macrophages. D-mannosamine was conjugated to PLGA-polyethylene glycol (PLGA-PEG) copolymers through EDC/NHS coupling chemistry, and the resultant RPT-MAN-PLGA-PEG nanoparticles (NPs) were prepared through a combination of phacoemulsification and solvent evaporation methods. The physicochemical properties, toxicity, in vitro drug release profiles, stability, cellular uptake, and anti-TB efficacy of the NPs were systematically evaluated.

Results

The RPT-MAN-PLGA-PEG NPs had a mean particle size of 108.2 ± 7.2 nm, with encapsulation efficiency and drug loading rates of 81.2 ± 6.3% and 13.7 ± 0.7%, respectively. RPT release from the NPs was sustained for over 60 hours. Notably, the phagocytic uptake of the MAN-PLGA NPs by macrophages was significantly higher compared to PLGA-PEG NPs. Both NPs improved pharmacokinetic parameters without inducing significant organ toxicity. The minimum inhibitory concentration for the NPs was 0.047 μg/mL, compared to 0.2 μg/mL for free RPT.

Conclusion

The engineered RPT-MAN-PLGA-PEG NPs effectively enhanced macrophage uptake in vitro and facilitated the intracellular clearance of Mtb. This nanoparticle-based delivery system offers a promising approach for improving the precision of anti-TB therapy, extending drug release, optimizing pharmacokinetic profiles, augmenting antimicrobial efficacy, and mitigating drug-related toxicities.

Burst-Free Sustained Release of Proteins from Thermal Gelling Polymer Solutions

Objectives: Thermo-gelling hydrophilic polymers like PLGA-PEG-PLGA are known as injectable sustained-release depots for biologics, but they face challenges due to the occurrence of severe burst release. This study aimed to develop a strategy to avoid the initial burst release by pre-encapsulating proteins in polysaccharide microparticles through an aqueous-aqueous emulsion mechanism, thereby enhancing therapeutic retention and linear release kinetics. Methods: Five model proteins (G-CSF, GM-CSF, IGF-1, FVIII, BSA) were encapsulated in dextran microparticles, using an organic solvent-free aqueous-aqueous emulsion method. These particles were dispersed in a 23% (w/w) PLGA-PEG-PLGA solution and injected into a 37 °C release buffer to form a gel depot. The in vitro release profiles were quantified using ELISA and MicroBCA assays over 9-42 days. The bioactivity of the proteins was validated using cell proliferation assays (NFS-60, TF-1, MCF-7) and chromogenic kits. The in vivo pharmacokinetics of the FVIII-loaded formulations were evaluated in Sprague-Dawley rats (n = 5/group) over 28 days. Results: Protein-loaded dextran particles retained their structural integrity within the hydrogel and exhibited minimal burst release (≤5% within 30 min vs. >25% for free proteins). Sustained near-linear release profiles were observed for all the proteins, with complete release by day 9 (G-CSF, GM-CSF, BSA) or day 42 (FVIII). Rats administered with the thermal gel with FVIII-dextran particles showed a significantly lower peak plasma concentration (Cmax: 88.25 ± 30.21 vs. 132.63 ± 66.67 ng/mL) and prolonged therapeutic coverage (>18 days vs. 15 days) compared to those administered with the thermal gel with the FVIII solution. The bioactivity of the released proteins remained at ≥90% of the native forms. Conclusions: Pre-encapsulation in dextran microparticles effectively mitigates burst release from thermosensitive hydrogels, while preserving protein functionality.

Interaction of solid lipid nanoparticles with bovine serum albumin: physicochemical mechanistic insights

This study investigates the interaction of solid lipid nanoparticles (SLNs) with the transport protein bovine serum albumin (BSA) in terms of thermodynamic signatures, employing both spectroscopic and calorimetric techniques. When nanoparticles are exposed to biological media, proteins are adsorbed on their surfaces, leading to protein corona formation. Therefore, controlling the formation of the protein corona is essential for in vivo therapeutic efficacy. Although SLNs have previously been explored solely as potential nano-carriers for drug delivery, no prior efforts have been made to study their interactions with biomolecules from a biophysical and mechanistic perspective. SLNs are colloidal dispersions of the solid lipid in an aqueous solution stabilized by surfactants. Herein, a hot emulsification methodology was employed to formulate SLNs, and their interactions with BSA were analyzed. The SLNs were characterized using transmission electron microscopy (TEM) and dynamic light scattering (DLS) techniques to obtain information on their size, zeta potential, and shape. Fluorescence data suggested the presence of weak interactions between the SLNs and BSA. Static quenching is confirmed using time-correlated single-photon counting (TCSPC) experiments. Differential scanning calorimetric (DSC) and fluorescence spectroscopic experiments suggest the thermal stabilization of BSA by the SLNs. This stabilization results from the enhancement of the secondary structure of the protein without significantly altering the tertiary structure. Isothermal calorimetry (ITC) results suggest weak interactions between the SLNs and BSA, although not in a site-specific manner. Overall, mechanistic insights into lipid nanoparticle-protein interactions obtained from such studies efficiently overcome the hurdles associated with targeted drug delivery.

The (re)emergence of aerosol delivery: Treatment of pulmonary diseases and its clinical challenges

Aerosol delivery represents a rapid and non-invasive way to directly reach the lungs while escaping the hepatic first-pass effect. The development of pulmonary drugs for respiratory diseases such as cystic fibrosis, lung infections, pulmonary fibrosis or lung cancer requires an enhanced understanding of the relationships between the natural physiology of the respiratory system and the pathophysiology of these conditions. This knowledge is crucial to better predict and thereby control drug deposition. Moreover, aerosol administration faces several challenges, including the pulmonary tract, immune system, mucociliary clearance, the presence of fluid on the airway surfaces, and, in some cases, bacterial colonisation. Each of them directly influences on the bioavailability of the active molecule. In addition to these challenges, particle size and the device used to administer the treatment are critical factors that can significantly impact the biodistribution of the drugs. Nanoparticles are very promising in the development of new formulations for aerosol drug delivery, as they can be fine-tuned to reach the entire pulmonary tract and overcome the difficulties encountered along the way. However, to properly assess drug delivery, preclinical studies need to be more thorough to efficiently enhance drug delivery.

Landscape of small nucleic acid therapeutics: moving from the bench to the clinic as next-generation medicines

The ability of small nucleic acids to modulate gene expression via a range of processes has been widely explored. Compared with conventional treatments, small nucleic acid therapeutics have the potential to achieve long-lasting or even curative effects via gene editing. As a result of recent technological advances, efficient small nucleic acid delivery for therapeutic and biomedical applications has been achieved, accelerating their clinical translation. Here, we review the increasing number of small nucleic acid therapeutic classes and the most common chemical modifications and delivery platforms. We also discuss the key advances in the design, development and therapeutic application of each delivery platform. Furthermore, this review presents comprehensive profiles of currently approved small nucleic acid drugs, including 11 antisense oligonucleotides (ASOs), 2 aptamers and 6 siRNA drugs, summarizing their modifications, disease-specific mechanisms of action and delivery strategies. Other candidates whose clinical trial status has been recorded and updated are also discussed. We also consider strategic issues such as important safety considerations, novel vectors and hurdles for translating academic breakthroughs to the clinic. Small nucleic acid therapeutics have produced favorable results in clinical trials and have the potential to address previously "undruggable" targets, suggesting that they could be useful for guiding the development of additional clinical candidates.

Pharmaceutical 3D Printing Technology Integrating Nanomaterials and Nanodevices for Precision Neurological Therapies

Pharmaceutical 3D printing, combined with nanomaterials and nanodevices, presents a transformative approach to precision medicine for treating neurological diseases. This technology enables the creation of tailored dosage forms with controlled release profiles, enhancing drug delivery across the blood-brain barrier (BBB). The integration of nanoparticles, such as poly lactic-co-glycolic acid (PLGA), chitosan, and metallic nanomaterials, into 3D-printed scaffolds improves treatment efficacy by providing targeted and prolonged drug release. Recent advances have demonstrated the potential of these systems in treating conditions like Parkinson's disease, epilepsy, and brain tumors. Moreover, 3D printing allows for multi-drug combinations and personalized formulations that adapt to individual patient needs. Novel drug delivery approaches, including stimuli-responsive systems, on-demand dosing, and theragnostics, provide new possibilities for the real-time monitoring and treatment of neurological disorders. Despite these innovations, challenges remain in terms of scalability, regulatory approval, and long-term safety. The future perspectives of this technology suggest its potential to revolutionize neurological treatments by offering patient-specific therapies, improved drug penetration, and enhanced treatment outcomes. This review discusses the current state, applications, and transformative potential of 3D printing and nanotechnology in neurological treatment, highlighting the need for further research to overcome the existing challenges.

Nanomedicine Innovations for Lung Cancer Diagnosis and Therapy

Lung cancer remains a challenge within the realm of oncology. Characterized by late-stage diagnosis and resistance to conventional treatments, the currently available therapeutic strategies encompass surgery, radiotherapy, chemotherapy, immunotherapy, and biological therapy; however, overall patient survival remains suboptimal. Nanotechnology has ushered in a new era by offering innovative nanomaterials with the potential to precisely target cancer cells while sparing healthy tissues. It holds the potential to reshape the landscape of cancer management, offering hope for patients and clinicians. The assessment of these nanotechnologies follows a rigorous evaluation process similar to that applied to chemical drugs, which includes considerations of their pharmacokinetics, pharmacodynamics, toxicology, and clinical effectiveness. However, because of the characteristics of nanoparticles, standard toxicological tests require modifications to accommodate their unique characteristics. Effective therapeutic strategies demand a profound understanding of the disease and consideration of clinical outcomes, physicochemical attributes of nanomaterials, nanobiointeractions, nanotoxicity, and regulatory compliance to ensure patient safety. This review explores the promise of nanomedicine in lung cancer treatment by capitalizing on its unique physicochemical properties. We address the multifaceted challenges of lung cancer and its tumor microenvironment and provide an overview of recent developments in nanoplatforms for early diagnosis and treatment that can enhance patient outcomes and overall quality of life.

Luteolin-Manganese Nanozyme Induces Apoptosis and Ferroptosis for Enhanced Cancer Therapy

Cancer presents a significant global public health challenge that impacts millions of individuals worldwide. The incorporation of natural products into cancer treatment has the potential to mitigate many of the side effects commonly associated with chemotherapy. This study builds on the advantages of enhancing the anticancer activity of natural flavonoids through metal chelation by synthesizing a natural antioxidant flavonoid complex, termed Lu-Mn nanozyme, which involves the chelation of luteolin with manganese ions. In vitro experiments demonstrated that Lu-Mn exhibits a strong affinity for hydrogen peroxide (H2O2) and effectively catalyzes the generation of hydroxyl radicals (•OH) from H2O2 within the tumor microenvironment. The administration of the Lu-Mn nanozyme not only induced apoptosis in tumor cells by upregulating the expression of cleaved caspase3 and caspase9 but also activated ferroptosis through downregulation of the NRF2-GPX4 signaling pathway. Furthermore, animal studies have shown that Lu-Mn possesses significant antitumor efficacy and a favorable safety profile. Collectively, these findings suggest that luteolin, through its chelation with metal ions, has considerable potential for application in cancer treatment.

Effects of Surface Charge of Inhaled Liposomes on Drug Efficacy and Biocompatibility

Objectives: Liposomes are a promising drug carrier for inhaled delivery systems and their physical parameters could influence therapeutic efficacy significantly. This study was designed to answer the specific question of the proper surface charge of liposomes in pulmonary inhalation, as well as to study the synergistic anti-inflammation efficacy between drugs. Methods: In this work, a series of drug-loaded liposomes with different surface charges (from negative to positive) were prepared, and several in vitro and in vivo assays, including cytotoxicity, hemolysis assay, mucus penetration and lipopolysaccharide (LPS)-induced pneumonia model test, were adopted to evaluate the anti-inflammation efficacy and biocompatibility of the above liposomes. Results: Compared with cationic liposomes, anionic liposomes are capable of better mucus penetration and good biocompatibility (low cytotoxicity, better blood compatibility and mild tissue inflammation), but with poor cellular uptake by immune cells. In specific, even when the liposome surface charge was only +2.6 mV, its cytotoxicity and blood hemolysis reached around 20% and 15%, respectively. Furthermore, there was no significant difference in biocompatibility between anionic liposomes (-25.9 vs. -2.5 mV), but a slightly negative-charged liposome exhibited better cellular uptake. Conclusions: Thus, slightly negative-charged liposomes (-1~-3 mV) could be a well inhaled drug carrier considering both efficacy and biocompatibility. In an LPS-induced pneumonia mouse model, the drug-loaded liposomes achieved better anti-inflammatory efficacy compared with free drugs.

Biomineralized and metallized small extracellular vesicles encapsulated in hydrogels for mitochondrial-targeted synergistic tumor therapy

Targeted organelle therapy is a promising therapeutic method for significantly regulating the tumor microenvironment, yet it often lacks effective strategies for leveraging synergistic enhancement effect. Engineered small extracellular vesicles (sEVs) are expected to address this challenge due to their notable advantages in drug delivery, extended circulation time, and intercellular information transmission. Herein, we prepare sEVs with pH and photothermal dual-responsiveness, which are encapsulated with hydrogels for a quadruple-efficient synergistic therapy. M1-phenotype macrophages-derived sEVs, which carry cytokines that inhibit tumor progression, were separately encapsulated with calcium phosphates (CaPs) and Au@Pt nanoparticles (Au@Pt NPs), endowing them with pH and photothermal dual-responsiveness. Subsequently, they were assembled into sEV-Au@Pt NPs/CaPs nanohybrids, and functionalized with mitochondria-targeting peptides. Within tumor cells, mitochondrial targeting enhances Ca2+ accumulation, resulting in mitochondrial homeostasis imbalance. The release of Pt2+ causes nuclear damage and exacerbates mitochondrial dysfunction. Furthermore, under laser irradiation, the sEV-Au@Pt NPs absorb light, generating hyperthermia that promotes the release of Ca2+ and Pt2+ from the hydrogel and cytokines from the sEVs, thereby achieving a quadruple-efficient synergistic therapy. The hydrogel effectively prolongs the retention time of nanohybrids, aiding in the prevention of tumor recurrence. These nanohybrids exhibit favorable mitochondrial targeting ability, with a Pearson's co-localization coefficient of 0.877. In experimental trials, tumor growth was significantly inhibited after only five treatments, with the tumor volume reduced to 0.16-fold that of the control group. This strategy presents a potential tailored platform for engineered sEVs in mitochondrial-targeted therapy and holds great promise for advancing organelle-targeted therapeutic strategies. STATEMENT OF SIGNIFICANCE: Engineering small extracellular vesicles (sEVs) can significantly enhance the synergistic effects of organelle-targeted therapy, thereby improving therapeutic efficacy and reducing side effects. However, their full development is still pending. In this study, we present a promising strategy that involves engineering sEVs with pH and photothermal dual-responsiveness through biomineralization and metallization, enabling quadruple synergistic tumor therapy. Our study demonstrates the remarkable synergistic effects of mitochondrial homeostasis imbalance caused by Ca2+ bursts and nuclear damage due to Pt2+ release. After five treatments, the tumor volume in the experimental group was reduced to 0.16-fold that of the control group. This strategy holds great promise for the design of engineered sEVs as organelle-targeted therapeutic systems.

Preparation of dried nanoemulsion formulation by electrospinning

Dry eye disease is a multifactorial condition characterized by a loss of homeostasis of the tear film. Among the various treatment approaches, the application of ophthalmic oil-in-water nanoemulsions with incorporated anti-inflammatory drugs represents one of the most advanced approaches. However, the liquid nature of nanoemulsions limits their retention time at the ocular surface. Transforming the nanoemulsions into a dry form that would disperse rapidly in the tear fluid would improve the retention of the drug at the ocular surface. The aim of this study was to investigate electrospinning as a method for the preparation of a solid eye preparation based on nanoemulsion loaded with the anti-inflammatory drug loteprednol etabonate. Four nanoemulsions differing in oil-to-surfactant ratios were incorporated in hydrophilic nanofibers based on polyethylene oxide, poloxamer 188, and Soluplus®. The dried nanoemulsions in the form of nanofibers dispersed readily on contact with aqueous medium, resulting in a dispersion of nanometre-sized droplets with average size comparable to the average droplet size of the initial nanoemulsions. A rheological study revealed the predominant elastic behavior of the dispersed nanofibers, which indicates the formation of a weak gel after the dispersion of the dried nanoemulsion in tear fluid at the ocular surface. The biocompatibility of the dried nanoemulsions in the form of nanofibers after a single and multiple-dose application was confirmed using the 3D HCE-T model of the stratified epithelium of the human cornea, suggesting that this innovative solid eye preparation could represent a new approach to the treatment of dry eye disease.

Exploring the physicochemical interactions and loading strategies of mesoporous silicon dioxide nanoparticles for drug delivery

Mesoporous silica nanoparticles play an important role in drug delivery due to their high surface area, porous structure, tunable pore size, chemical stability and functionalization capability. Such properties make them a good candidate for drug encapsulation. However, molecular binding is another parameter that govern drug loading apart of pores' structure and size. There is a lack of comprehensive reviews on that topic nowadays. This paper overviews the latest publications on the physicochemical aspects of the interaction of mesoporous silica nanoparticles with drugs. The review is focused primarily on a such parameters of the intermolecular binding between a drug and silica nanoparticle as a binding constant, enthalpy and entropy changes and experimental methods with the emphasis on the principles of thermodynamic parameters characterization. Such information would be very important for the development and optimization of drug delivery strategies based on mesoporous silica nanoparticles.

Nanomaterial-Triggered Ferroptosis and Cuproptosis in Cancer Therapy

Cancer remains one of the leading causes of the death of individuals globally. Conventional treatment techniques like chemotherapy and radiation often suffer various drawbacks like toxicity and drug resistance. The study of cell death has been predominantly focused on classical forms like apoptosis, but the role of metal ions in governing controlled cell death is a fascinating and less explored area. Metal-mediated controlled cell death is a process where metal triggers cell death via a unique mechanism. Nanomaterial-based strategies have gained attention for their ability to deliver precise therapeutic agents while also triggering Regulated Cell Death (RCD) mechanisms in cancer cells. The recently discovered metal-mediated controlled cell death techniques like cuproptosis and ferroptosis can be used in cancer treatment as they can be used selectively for the treatment of drug-resistant cancer. Nano material-based delivery system can also be used for the precise delivery of the drug to the targeted sites. In this review, we have given some idea about the mechanism of metal-mediated controlled cell death techniques (ferroptosis and cuproptosis) and how we can initiate controlled cell deaths using nanomaterials for cancer treatment.

Perturbing Organelle-Level K+/Ca2+ Homeostasis by Nanotherapeutics for Enhancing Ion-Mediated Cancer Immunotherapy

Intracellular ions are involved in numerous pivotal immune processes, but the precise regulation of these signaling ions to achieve innovative immune therapeutic strategies is still a huge challenge. Here, an ion-mediated immunotherapy agent (IMIA) is engineered to achieve precise spatiotemporal control of perturbing K+/Ca2+ homeostasis at the organelle-level, thereby amplifying antitumor immune responses to achieve high-performance cancer therapy. By taking in intracellular K+ and supplying exogenous Ca2+ within tumor cells, K+/Ca2+ homeostasis is perturbed by IMIA. In parallel, perturbing K+ homeostasis induced endoplasmic reticulum (ER) stress triggers the release of Ca2+ from ER and causes a decreased concentration of Ca2+ in ER, which further accelerates ER-mitochondria Ca2+ flux and the influx of extracellular Ca2+ (store-operated Ca2+ entry (SOCE)) via opening Ca2+ release-activated Ca2+ (CRAC) channels, thus creating a self-amplifying ion interference loop to perturb K+/Ca2+ homeostasis. In this process, the elevated immunogenicity of tumor cells would evoke robust antitumor immune responses by driving the excretion of damage-associated molecular patterns (DAMPs). Importantly, this ion-immunotherapy strategy reshapes the immunosuppressive tumor microenvironment (TME), and awakens the systemic immune response and long-term immune memory effect, thus effectively inhibiting the growth of primary/distant tumors, orthotopic tumors as well as metastatic tumors in different mice models.

Advanced drug delivery systems for the management of local conditions

Localized disorders, even though originally confined to a specific body part, can progress into potentially life-threatening systemic disorders if treated inappropriately. Local treatment is often highly challenging due to poor penetration of therapeutic agents from their vehicles into the affected body site. Systemic treatment on the other hand often comes with unspecific side effects. The skin is the largest organ of the body, and conditions such as wounds and bacterial or fungal infections disrupt its natural barrier properties, important for the homeostasis of the human body. Advanced drug delivery systems for treating these conditions could greatly improve the treatment outcome and patient compliance. Other parts of the body that are of interest regarding localized treatment are, for example, the eyes along with mucosal tissues which are present in the vagina and lungs. Rather than focusing on specific diseases or parts of the body, this review provides an overview of the different drug delivery platforms that have been employed for enhanced local treatment. The following systems will be discussed: nanoparticle-based systems, such as nanocrystals, polymeric, lipidic, and inorganic nanoparticles, and nanogels; cyclodextrin inclusion complexes; and several devices like microarray patches, wound dressings, and films.

Ferroptosis in Pulmonary Disease and Lung Cancer: Molecular Mechanisms, Crosstalk Regulation, and Therapeutic Strategies

Ferroptosis is a distinct form of iron-dependent programmed cell death characterized primarily by intracellular iron accumulation and lipid peroxidation. Multiple cellular processes, including amino acid metabolism, iron metabolism, lipid metabolism, various signaling pathways, and autophagy, have been demonstrated to influence the induction and progression of ferroptosis. Recent investigations have elucidated that ferroptosis plays a crucial role in the pathogenesis of various pulmonary disorders, including lung injury, chronic obstructive pulmonary disease, pulmonary fibrosis, and asthma. Ferroptosis is increasingly recognized as a promising novel strategy for cancer treatment. Various immune cells within the tumor microenvironment, including CD8+ T cells, macrophages, regulatory T cells, natural killer cells, and dendritic cells, have been shown to induce ferroptosis in tumor cells and modulate the process through the regulation of iron and lipid metabolism pathways. Conversely, ferroptosis can reciprocally alter the metabolic environment, leading to the activation or inhibition of immune cell functions, thereby modulating immune responses. This paper reviews the molecular mechanism of ferroptosis and describes the tumor immune microenvironment, discusses the connection between ferroptosis and the tumor microenvironment in lung cancer and pulmonary diseases, and discusses the development prospect of their interaction in the treatment of lung cancer and pulmonary diseases.

PCR array analysis reveals a novel expression profile of ferroptosis-related genes in idiopathic pulmonary fibrosis

BACKGROUND

Idiopathic pulmonary fibrosis (IPF) is a chronic, irreversible, and fatal disease characterized by progressive interstitial lung fibrosis. Given its insidious onset and poor outcome, there is an urgent need to elucidate the molecular mechanisms underlying IPF and identify effective therapeutic targets and diagnosis and prognosis biomarkers. Ferroptosis is an iron-dependent form of programmed cell death that occurs as lipid peroxides accumulate. Growing evidence suggests that ferroptosis is important in IPF.

METHODS

Human ferroptosis PCR array was performed on IPF and control lung tissue. The differentially expressed ferroptosis-related genes (DE-FRGs) were identified, underwent functional enrichment analyses, protein-protein interaction network construction, and potential drug target prediction. The DE-FRGs were validated and their value as diagnostic and prognostic blood biomarkers were evaluated using the Gene Expression Omnibus dataset GSE28042.

RESULTS

The array identified 13 DE-FRGs. Gene Ontology enrichment and Kyoto Encyclopedia of Genes and Genomes pathway analyses revealed that the DE-FRGs were mainly related to iron ion transport, blood microparticles, and oxidoreductase activity, and were involved in porphyrin metabolism, necroptosis, and the p53 signaling pathway in addition to ferroptosis. The 13 DE-FRGs were analyzed using the Drug-Gene Interaction Database to explore novel IPF therapeutic agents, yielding 42 potential drugs. Four DE-FRGs (BBC3, STEAP3, EPRS, SLC39A8) in the peripheral blood of IPF patients from the GSE28042 dataset demonstrated the same expression pattern as that observed in the lung tissue array. The receiver operating characteristic analysis demonstrated that the area under the curve of STEAP3 and EPRS were > 0.75. The survival analysis demonstrated that STEAP3 and EPRS were significantly different between the IPF and control groups.

CONCLUSIONS

The FRG expression profiles in IPF and control lung tissue were characterized. The findings provided valuable ideas to elucidate the role of ferroptosis in IPF and aided the identification of novel IPF therapeutic targets and biomarkers.

Advances in Ferroptosis Research: A Comprehensive Review of Mechanism Exploration, Drug Development, and Disease Treatment

In recent years, ferroptosis, as an emerging modality of programmed cell death, has captured significant attention within the scientific community. This comprehensive review meticulously canvasses the pertinent literature of the past few years, spanning multiple facets. It delves into the intricate mechanisms underpinning ferroptosis, tracks the evolution of its inducers and inhibitors, and dissects its roles in a diverse array of diseases, as well as the resultant therapeutic implications. A profound exploration is conducted of the functional mechanisms of ferroptosis-related molecules, intracellular pathways, metabolic cascades, and signaling transduction routes. Novel ferroptosis inducers and inhibitors are introduced in detail, covering their design blueprints, synthetic methodologies, and bioactivity profiles. Moreover, an exhaustive account is provided regarding the involvement of ferroptosis in malignancies, neurodegenerative disorders, cardiovascular ailments, and other pathologies. By highlighting the pivotal status and potential therapeutic regimens of ferroptosis in various diseases, this review aspires to furnish a thorough and profound reference framework for future investigations and clinical translations in the ferroptosis domain.

Interaction between pristine nC60 and bovine serum albumin by fluorimetry: assessment of inner filter effect corrections

Introduction

Fluorescence spectrometry is widely used to investigate nanomaterial-protein interactions, a crucial component of nanomaterial safety evaluation. However, the inner filter effect (IFE) significantly distorts fluorescence data during the analysis of fullerene (nC60) -protein interactions. Systematic correction methods for this system are rarely reported.

Methods

In this study, bovine serum albumin (BSA) served as the protein model, four mathematical formulas (Lakowicz, Gauthier, Tucker, and Chen models) were comparatively evaluated for IFE correction in fluorescence analysis. The correction results were compared to propose an optimal correction method for the interaction between nC60 and BSA. Binding parameters were calculated from corrected data, and quenching mechanisms were analyzed using Stern-Volmer equations.

Results

At room temperature with low nC60 concentrations (<2.0 × 10-5 mol/L), Chen's model demonstrated optimal IFE correction accuracy. Corrected data indicated static quenching between nC60 and BSA, with a binding constant of K = 2.95 × 109 L/mol and approximately two binding sites.

Discussion

This study offers methodological guidance for IFE correction and accurate fluorescence analysis in the investigation of interactions between nanomaterials and biomolecules. Thus, it provides a reliable analytical method for the bio-safety assessment of nanomaterials.

Detailed Profiling of Protein Corona Formed by Polydopamine Nanoparticles in Human Plasma

The term protein corona (PC) indicates proteins adsorbed onto the surface of nanostructures exposed to biological media such as blood or serum. The analysis of the composition, evolution, and effect of the PC complexed with nanomaterials gained attention in recent years due to the importance of these parameters in determining the biological fate of nanostructures. In particular, the PC represents the first component of a nanomaterial interfacing with biological structures, dictating parameters such as nanoparticle internalization, immune response, bioavailability, and even toxicity. Polydopamine nanoparticles (PDNPs), obtained through the polymerization of dopamine, are "smart" materials characterized by high biocompatibility, high antioxidant capacities, high tunability and surface reactivity, biodegradability, and the ability to act as photothermal conversion agents when irradiated with a near-infrared (NIR) light source. Despite many interesting applications of PDNPs are currently described in the scientific literature, there is still no comprehensive analysis of the phenomenon of PC formation consequent to the exposure of these nanomaterials to biological media. Moreover, to date, the investigation of the effects of light irradiation of photothermally active nanomaterials on the composition and evolution of the associated PC has been extremely limited. With this work, we aim to provide for the first time an analysis of the phenomenon of PC formation associated with PDNPs, before and after NIR light stimulation. We characterized the PC formed following exposure to human plasma and analyzed the effects of several parameters on the overall PC composition and quantity, such as the PDNP size, presence of a surface functionalization, exposure time, and irradiation with an NIR laser, demonstrating that these parameters play a pivotal role in the resulting PC composition. Eventually, we showed that PDNPs exposed to human plasma have significantly different properties with respect to bare PDNPs, showing higher internalization rates in human glioblastoma cells, a higher light absorption value, and enhanced photothermal conversion abilities.

Mixed dry reverse micelles: potential carriers for oral protein delivery via SEDDS

The aim of this study was to evaluate the potential of mixed dry reverse micelles (dRMs) to increase the lipophilicity of therapeutic proteins and allow their incorporation into self-emulsifying drug delivery systems (SEDDS). Horseradish peroxidase (HRP) was incorporated in mixed dRMs, forming HRP-dRMs, using soybean phosphatidylcholine (SPC) and sodium docusate (SD) as surfactants. HRP-dRMs were characterized with respect to their distribution coefficient and stability in simulated physiological fluids. Moreover, HRP-dRMs were loaded in SEDDS, which were characterized for their payload, stability, distribution coefficients between the lipophilic phase of SEDDS and release medium and their ability to protect the incorporated protein towards enzymatic degradation in aqueous media containing trypsin and chymotrypsin. The synergistic effect of two surfactants to form dRMs led to a payload of 3% (w/v) for the model protein in a lipophilic phase without the use of organic cosolvents. Moreover, the HRP-dRMs incorporation increased the LogD n-octanol/water value of HRP from - 3.36 to 3.10. This increment in lipophilicity provided a higher retention of the protein within the oily droplets, and correled with enzymatic degradation studies, where > 95% of the incorporated protein remained intact. This study provided first evidence for unprecedented amount of a model protein of high molecular weight loaded in SEDDS through dRMs incorporation as a possible tool for their oral delivery, with a 15-fold increment compared to the previously achieved results.

An oxidation-reduction-triggered thiamine disulfide-based prodrug of 10-hydroxycamptothecin for selective tumor cell locking and therapeutic delivery

Chemotherapy, a primary method of cancer treatment, has been limited in clinical application due to its lack of specificity and tumor multidrug resistance, resulting in numerous undesired side effects. Herein, a small molecule conjugate, TDK-HCPT, was designed and synthesized, which could target tumor cells and prolong the retention of chemotherapy agents within tumor cells. Moreover, a similarly designed control system, TDK-Nap, has been developed as well to enable cancer cell imaging. Two design elements are incorporated into TDK-HCPT: the thiamine disulfide (TDS) and the thioketal subunit (tk). TDS can be reduced in the high glutathione (GSH) conditions within cancer cell to form thiazolium salt, and the resulting enhanced positive charge and lipophobicity make the system difficult to be pumped out of tumor cells, thereby effectively "locking" the chemotherapy drug HCPT inside the tumor cells. Additionally, the tk subunit serves as a ROS trigger, within the tumor cells, the "locked" HCPT were then released and activated by the high ROS conditions, optimizing its targeted potential. This allows TDK-HCPT to serve as a redox-liable molecular platform that targets cancer cells selectively which decreases cancer cell migration, retards tumor growth, and lowers tumorigenesis rates as evidenced by a combination of in vitro and in vivo studies. To the best of our knowledge, this is the first time a cancer cell "lock in" has been shown to prevent tumorigenesis in an animal model.

Gels as Promising Delivery Systems: Physicochemical Property Characterization and Recent Applications

Gels constitute a versatile class of materials with considerable potential for applications in both technical and medical domains. Physicochemical property characterization is a critical evaluation method for gels. Common characterization techniques include pH measurement, structural analysis, mechanical property assessment, rheological analysis, and phase transition studies, among others. While numerous research articles report characterization results, few reviews comprehensively summarize the appropriate numerical ranges for these properties. This lack of standardization complicates harmonized evaluation methods and hinders direct comparisons between different gels. To address this gap, it is essential to systematically investigate characterization methods and analyze data from the extensive body of literature on gels. In this review, we provide a comprehensive summary of general characterization methods and present a detailed analysis of gel characterization data to support future research and promote standardized evaluation protocols.

Hybrid Nanoplatforms Based on Photosensitizers and Metal/Covalent Organic Frameworks for Improved Cancer Synergistic Treatment Nano-Delivery Systems

Researchers have extensively investigated photosensitizer (PS) derivatives for various applications due to their superior photophysical and electrochemical properties. However, inherent problems, such as instability and self-quenching under physiological conditions, limit their biological applications. Metal-organic frameworks (MOFs) and covalent organic frameworks (COFs) represent two relatively new material types. These materials have high surface areas and permanent porosity, and they show a tremendous deal of potential for applications like these. This review summarizes key synthesis processes and highlights recent advancements in integrating PS-based COF and MOF nanocarriers for biomedical applications while addressing potential obstacles and prospects.

Microneedle-Mediated Treatment of Obesity

Obesity has become a major public health threat, as it can cause various complications such as diabetes, cardiovascular disease, sleep apnea, cancer, and osteoarthritis. The primary anti-obesity therapies include dietary control, physical exercise, surgical interventions, and drug therapy; however, these treatments often have poor therapeutic efficacy, significant side effects, and unavoidable weight rebound. As a revolutionized transdermal drug delivery system, microneedles (MNs) have been increasingly used to deliver anti-obesity therapeutics to subcutaneous adipose tissue or targeted absorption sites, significantly enhancing anti-obese effects. Nevertheless, there is still a lack of a review to comprehensively summarize the latest progress of MN-mediated treatment of obesity. This review provides an overview of the application of MN technology in obesity, focusing on the delivery of various therapeutics to promote the browning of white adipose tissue (WAT), suppress adipogenesis, and improve metabolic function. In addition, this review presents detailed examples of the integration of MN technology with iontophoresis (INT) or photothermal therapy (PTT) to promote drug penetration into deeper dermis and exert synergistic anti-obese effects. Furthermore, the challenges and prospects of MN technology used for obesity treatment are also discussed, which helps to guide the design and optimization of MNs. Overall, this review provides insight into the development and clinical translation of MN technology for the treatment of obesity.

Capturing the dynamic integrity of carbocyanine fluorophore-based lipid nanoparticles using the FRET technique

Nanoparticles capable of dynamically reporting their structural integrity in real-time are a powerful tool to guide the design of drug delivery technologies. Lipid nanoparticles (LNPs) offer multiple important advantages for drug delivery, including stability, protection of active substances, and sustained release capabilities. However, tracking their structural integrity and dynamic behaviour in complex biological environments remains challenging. Here, we report the development of a Förster resonance energy transfer (FRET)-enabled LNP platform that achieves unprecedented sensitivity and precision in monitoring nanoparticle disintegration. The FRET-based LNPs were prepared using nanoprecipitation, encapsulating high levels of 3,3'-dioctadecyloxacarbocyanine perchlorate (DiO) and 1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate (DiI) fluorophores as the donor and acceptors, respectively. The resulting LNPs had a mean diameter of 114 ± 19 nm with a distinct FRET signal. An optimal energy transfer efficiency of 0.98 and an emission quantum yield of 0.13 were achieved at 11.1% fluorophore loading in the LNPs, balancing efficient energy transfer and minimal aggregation-induced quenching. Using the FRET reporting, three dissociation stages of FRET LNPs were observed: solvation, indicated by an increased emission intensity; swelling and partial dissolution, evidenced by changes in emission maxima and mean size; and complete dissociation, confirmed by emission solely from DiO and the absence of particles. Testing the nanoparticles in live cells (telomerase-immortalised human corneal epithelial cells, hTCEpi cells) revealed a direct link to the disappearance of the FRET signal with the dissociation of FRET NPs. The nanoparticles initially exhibited a strong extracellular FRET signal, which diminished after cellular internalisation. This suggests that the LNPs disintegrate after entering the cells. These findings establish FRET-based LNPs as a robust tool for real-time nanoparticle tracking, offering insights into their integrity and release mechanisms, with potential applications in advanced drug delivery and diagnostics.