Reactive Oxygen Species-Regulating Strategies Based on Nanomaterials for Disease Treatment

A photothermal-responsive multi-enzyme nanoprobe for ROS amplification and glutathione depletion to enhance ferroptosis

Ferroptosis therapy employs reactive oxygen species (ROS) generated via Fenton or Fenton-like reactions. However, the antioxidant system associated with the tumor microenvironment (TME) exhibits high levels of glutathione (GSH) that significantly restrict the therapeutic efficacy of ferroptosis. In this study, we propose a near-infrared (NIR)-responsive hollow mesoporous manganese dioxide (HM-MnO2) nanoprobe with multi-enzyme-like activity for enhanced ROS generation and GSH depletion that can efficiently promote ferroptosis. The ferroptosis inducer RSL3 is encapsulated within HM-MnO2 with a loading capacity of 67 %, while iron-doped dopamine (Fe-PDA) and cRGD tumor-targeting peptides are conjugated on the surface. The resultant MnO2R@FePDA-cRGD nanocomposite delivers a photothermal conversion efficiency of 39.1 % under 808 nm irradiation, which can effectively trigger structural degradation of the nanoplatform and the rapid release of RSL3. The photothermal effects significantly augment catalytic activity, enabling a multi-enzyme mimicking that includes peroxidase (POD), oxidase (OXD), GSH peroxidase (GPx), and NADH oxidase (NOx) functions, generating significant ROS radicals and an efficient depletion of intracellular GSH. These cascade reactions contribute to an optimal TME for inducing "explosive" ferroptosis with a synergistic inhibition of tumor growth in vitro and in vivo. The proposed strategy represents a potent approach to amplifying ferroptosis through the photothermal-driven rapid release of RSL3 and enhanced multi-enzyme mimetic activities with significant potential in nanomedicine-based cancer therapy.

Precisely edited gut microbiota by tungsten-doped Prussian blue nanoparticles for the treatment of inflammatory bowel disease

Inflammatory bowel disease (IBD) is characterized by recurring gastrointestinal inflammation, accompanied by a significant rise in global prevalence and disease severity. The overaccumulation of reactive oxygen and nitrogen species (RONS) in the intestinal environment disrupts redox homeostasis and drives pathological overgrowth of Escherichia coli, which are central to IBD pathogenesis. Herein, we designed a multifunctional nanozyme (W-PB) to enable sustained and targeted regulation of intestinal homeostasis through dual mechanisms: specific inhibition of E. coli overgrowth during colitis and efficient RONS clearance. To ensure colon-specific delivery, W-PB was encapsulated in an electrostatically crosslinked hydrogel composed of alginate and chitosan. This formulation protects W-PB from degradation in harsh gastrointestinal conditions and releases the nanoparticles selectively under weakly alkaline intestinal pH. The released tungsten ions suppress E. coli growth via competitive displacement of molybdenum in the molybdopterin cofactor, while W-PB simultaneously neutralizes excess RONS to shield intestinal cells from oxidative damage. In DSS-induced colitis models, the W-PB gel demonstrated significant therapeutic efficacy, achieved through intestinal microbiota remodeling and oxidative stress mitigation.

Thermo-responsive and biodegradable MoS2-based nanoplatform for tumor therapy and postoperative wound management

Inorganic nanoparticles serve as versatile nanoplatforms for efficient cancer diagnosis and therapy. However, their limited in vivo degradability and excretion rates may lead to various adverse effects. Furthermore, the cascade-controlled release of drugs remains a challenge. In this study, we developed a free-radical triggered degradable MoS2-AIPH@LA nanoplatform for tumor photothermal and oxygen-independent thermodynamic therapy. This was achieved by loading the free radical initiator (2,2'-azobis[2-(2-imidazolin-2-yl) propane] dihydrochloride (AIPH)) onto MoS2 nanoparticles and encapsulating them with thermo-responsive lauric acid (LA). Upon laser irradiation, the hyperthermia generated by MoS2 induces cancer cell death and releases AIPH, an oxygen-independent and thermal-responsive radical initiator capable of producing toxic alkyl free radicals for tumor therapy and inhibiting bacterial growth. Importantly, these free radicals promote the degradation rate of MoS2-AIPH@LA, further facilitating a rapid AIPH release and improving the biocompatibility of the MoS2-AIPH@LA nanoplatform. In particular, the thermo-responsive nature of LA in this formulation effectively regulates the release of AIPH, thus reducing potential AIPH leakage into the bloodstream and minimizing safety risks. With its free-radical-triggered degradation and cascade-controlled release capabilities, MoS2-AIPH@LA shows significant promise for inhibiting tumor proliferation and managing postoperative bacterial infection.

Optimization of trace metal composition utilizing Taguchi orthogonal array enhances biomass and superoxide dismutase production in Tetraselmis chuii under mixotrophic condition: implications for antioxidant formulations

The natural ageing process in all organisms is majorly influenced by the production rate and dismutation of reactive oxygen species (ROS) within cells. Certain microalgae, such as Tetraselmis chuii, possess the ability to produce superoxide dismutase (SOD), a powerful antioxidant enzyme that mitigates oxidative damage caused by ROS during oxygen metabolism. This study investigated the impact of trace elements (nickel, manganese, copper, zinc, and iron) and nitrogen sources in the growth medium on both the biomass and SOD synthesis of T. chuii under mixotrophic conditions. Initially, the one-factor-at-a-time (OFAT) approach was employed to filter out the most significant factors in the production medium. Next, Taguchi orthogonal array method, known for its robustness in experimental design, was employed to analyse the effects of various media components on algal biomass and SOD production. Using only a few well-defined experimental sets, Taguchi's L18 orthogonal array facilitated a 1.21-fold increase in biomass yield, reaching a maximum of 0.643 g/L. Furthermore, SOD activity was enhanced from 85.28 to 91.94% following optimization. Notably, nitrogen source, nitrogen concentration, and zinc concentration emerged as significant influencers of biomass and SOD production. The Taguchi optimization thereby improved SOD yield in a cost-effective manner. The heightened antioxidation activity of SOD holds promising applications in formulating antioxidants and topical ointments in pharmaceutical and cosmeceutical industries.

Tumor microenvironment triggered iron-based metal organic frameworks for magnetic resonance imaging and photodynamic-enhanced ferroptosis therapy

Photodynamic therapy (PDT) primarily relies on the generation of reactive oxygen species (ROS) to eliminate tumor cells. However, the elevated levels of glutathione (GSH) within tumor cells can limit the efficacy of PDT, posing a challenge to achieve complete tumor eradication. Herein, a porous iron-based metal-organic frameworks (PEG-Fe-MOFs) nanoplatform was developed for the combined application of PDT and ferroptosis in cancer treatment. The coordination between tetrakis (4-carboxyphenyl) porphyrin (TCPP) and ferric (Fe3+) enabled PEG-modified Fe-MOFs (PEG-Fe-MOFs) to deliver excellent T1-weighted magnetic resonance (MR) imaging performance in physiological environments. Within the tumor microenvironment (TME), PEG-Fe-MOFs gradually degraded to release TCPP, which could be utilized for fluorescence imaging. Moreover, Fe2+ enhanced intracellular ROS levels via the Fenton reaction, generating hydroxyl radicals that further amplified ROS production. This synergistic effect comprising increased ROS levels and GSH depletion augmented the efficacy of PDT while simultaneously inducing robust ferroptosis in tumor cells, thereby maximizing therapeutic outcomes. Both in vitro and in vivo experiments have demonstrated the superior T1 weighted MR and fluorescence imaging capabilities of PEG-Fe-MOFs, along with its potent synergistic therapeutic effects on tumors. These results highlighted the potential of this nanoplatform for combining PDT and ferroptosis in cancer treatment.

Ecdysteroid-Containing Squalenoylated Self-Assembling Nanoparticles Exert Tumor-Selective Sensitization to Reactive Oxygen Species (ROS)-Induced Oxidative Damage While Protecting Normal Cells: Implications for Selective Radiotherapy

Central nervous system (CNS) tumors are exceptionally difficult to treat, and oxidative stress-inducing radiotherapy is an important treatment modality. In this study, we examined self-assembling pro-drug nanoconjugates of naturally derived antitumor ecdysteroids, which were designed to interfere with oxidative stress in brain tumor cells. Eight ecdysteroid-squalene conjugates were semi-synthesized and formulated into self-assembled aqueous nanosuspensions, which showed excellent stability for up to 16 weeks. The nanoassemblies demonstrated a strong dose-dependent sensitizing effect to tert-butyl hydroperoxide (tBHP)-induced oxidative damage in SH-SY5Y cells, while exerting a strong protective effect in MRC-5 fibroblast cells. In contrast, free ecdysteroids protected both cell lines from tBHP-induced damage. This suggests an important role for squalenoylation in the antitumor effect and indicates that our conjugates have potential as highly selective adjuvants in radiotherapy by sensitizing cancer cells and protecting surrounding tissues. Furthermore, our findings suggest a potential neuroprotective effect of nonconjugated ecdysteroids.

Bimetallic NiCu-MOF Protects DOX-Induced Myocardial Injury and Cardiac Dysfunction by Suppressing Ferroptosis and Inflammation

Doxorubicin (DOX), a potent anthracycline chemotherapeutic agent, is widely used in cancer treatment but is associated with significant adverse effects, particularly DOX-induced cardiomyopathy (DIC). DIC pathogenesis involves the generation of reactive oxygen species (ROS) and ferroptosis induction. Novel therapeutic strategies targeting antioxidant defenses and ferroptosis inhibition are essential for mitigating DIC. An innovative bimetallic metal-organic framework (MOF), NiCu-MOF (NCM), is developed, exhibiting multifaceted antioxidant enzyme-mimicking activities that effectively scavenge a broad spectrum of ROS. Additionally, the bimetallic NCM exhibits excellent iron-chelating ability. In vitro experiments demonstrate that NCM significantly reduces cardiomyocyte death by attenuating ROS levels and inhibiting ferroptosis. Furthermore, in a mouse model of DIC, NCM treatment results in substantial myocardial protection, evidenced by improved cardiac function and structural integrity. This protective effect is attributed to suppression of ferroptosis, preservation of mitochondrial function, and attenuation of inflammatory responses. Collectively, these findings highlight biocompatible NCM's potential as a novel cardioprotective agent and offer a promising therapeutic strategy for managing DIC.

Cerium-based nanoplatform for severe acute pancreatitis: Achieving enhanced anti-inflammatory effects through calcium homeostasis restoration and oxidative stress mitigation

Severe acute pancreatitis (SAP), a life-threatening inflammatory disease of the pancreas, has a high mortality rate (∼40 %). Current therapeutic approaches, including antibiotics, trypsin inhibitors, fasting, rehydration, and even continuous renal replacement therapy, yield limited clinical management efficacy. Abnormally elevated calcium levels and reactive oxygen species (ROS) overproduction by damaged mitochondria are key factors in the inflammatory cascade in SAP. The combination of calcium chelators and cerium-based nanozymes loaded with catalase (MOF808@BA@CAT) was developed to bind intracellular calcium, eliminate excessive ROS, and ameliorate the resulting mitochondrial dysfunction, thereby achieving multiple anti-inflammatory effects on SAP. A single low dose of the nanoplatform (1.5 mg kg-1) significantly reduced pancreatic necrosis in SAP rats, effectively ameliorated oxidative stress in the pancreas, improved mitochondrial dysfunction, reduced the proportion of apoptotic cells, and blocked the systemic inflammatory amplification cascade, resulting in the alleviation of systemic inflammation. Moreover, the nanoplatform restored impaired autophagy and inhibited endoplasmic reticulum stress in pancreatic tissue, preserving injured acinar cells. Mechanistically, the administration of the nanoplatform reversed metabolic abnormalities in pancreatic tissue and inhibited the signaling pathways that promote inflammation progression in SAP. This nanoplatform provides a new strategy for SAP treatment, with clinical translation prospects, through ion homeostasis regulation and pancreatic oxidative stress inhibition.

ERK1/2 gene expression and hypomethylation of Alu and LINE1 elements in patients with type 2 diabetes with and without cataract: Impact of hyperglycemia-induced oxidative stress

AIMS

This study aimed to delineate the effect of hyperglycemia on the Alu/LINE-1 hypomethylation and in ERK1/2 genes expression in type 2 diabetes with and without cataract.

METHODS

This study included 58 diabetic patients without cataracts, 50 diabetic patients with cataracts, and 36 healthy controls. After DNA extraction and bisulfite treatment, LINE-1 and Alu methylation levels were assessed using Real-time MSP. ERK1/2 gene expression was analyzed through real-time PCR. Total antioxidant capacity (TAC), and fasting plasma glucose (FPG) were measured using colorimetric methods. Statistical analysis was performed with SPSS23, setting the significance level at P < 0.05.

RESULTS

The TAC levels were significantly lower for cataract and diabetic groups than controls (259.31 ± 122.99, 312.43 ± 145.46, 372.58 ± 132.95 nanomole of Trolox equivalent) with a significant correlation between FPG and TAC levels in both the cataract and diabetic groups (P < 0.05). Alu and LINE-1 sequences were found to be statistically hypomethylated in diabetic and cataract patients compared to controls. In these groups, TAC levels were directly correlated with Alu methylation (P < 0.05) but not LINE-1. ERK1/2 gene expression was significantly higher in diabetic and cataract patients, showing increases of 2.41-fold and 1.43-fold for ERK1, and 1.27-fold and 1.5 for ERK2, respectively. ERK1 expression correlated significantly with FPG levels. A reverse correlation was observed between TAC levels and ERK1/2 expression.

CONCLUSIONS

Our findings indicate that hyperglycemia-induced oxidative stress may alter ERK1/2 gene expression patterns and induce aberrant hypomethylation in Alu and LINE-1 sequences. These aberrant changes may play a contributing role in diabetic complications such as cataracts.

Versatile nanomaterials used in combatting biofilm infections

Microbial infections are a pressing global health issue, exacerbated by the rise of antibiotic-resistant bacteria due to widespread antibiotic overuse. This resistance diminishes the effectiveness of current treatments, intensifying the need for new antimicrobial agents and innovative drug delivery strategies. Nanotechnology presents promising solutions, leveraging the unique properties of nanomaterials such as tunable optical and electronic characteristics, nanoscale size, and high surface-to-volume ratios. These features enhance their effectiveness as innovative antimicrobial agents and versatile drug delivery systems. This minireview classifies antimicrobial nanomaterials into four categories based on their mechanisms of action: thermal generation, reactive oxygen species generation, gas generation, and nanocarrier systems such as liposomes, polymersomes, and metal-organic frameworks. Uniquely, this review integrates a comparative analysis of these mechanisms, highlighting their relative advantages, limitations, and applications across diverse microbial targets. Additionally, it identifies emerging trends in the field, providing a forward-looking perspective on how recent advancements in nanotechnology can be leveraged to address unmet clinical needs. Finally, this article discusses future directions and emerging opportunities in antimicrobial nanotechnology.

In situ photocrosslinkable hydrogel treats radiation-induced skin injury by ROS elimination and inflammation regulation

The clinical management of radiation-induced skin injury (RSI) poses a significant challenge, primarily due to the acute damage caused by an overabundance of reactive oxygen species (ROS) and the ongoing inflammatory microenvironment. Here, we designed a dual-network hydrogel composed of 5 % (w/v) Pluronic F127 diacrylate and 2 % (w/v) hyaluronic acid methacryloyl, termed the FH hydrogel. To confer antioxidant and anti-inflammation properties to the hydrogel, we incorporated PVP-modified Prussian blue nanoparticles (PPBs) and resveratrol (Res) to form PHF@Res hydrogels. PHF@Res hydrogels not only exhibited multiple free radical scavenging activities (DPPH, ABTS), but also displayed multiple enzyme-like activities (POD-, catalase). Meanwhile, PHF@Res-2 hydrogels significantly suppressed intracellular ROS and promoted the migration of fibroblasts in a high-oxidative stress environment. Moreover, in the RSI mouse model, the PHF@Res-2 hydrogel regulated inflammatory factors and collagen deposition, significantly reduced epithelial hyperplasia, promoted limb regeneration and neovascularization, and accelerated wound healing, outperforming the commercial antiradiation formulation, Kangfuxin. The PHF@Res-2 hydrogel dressing shows great potential in accelerating wound healing in RSI, offering tremendous promise for clinical wound management and regeneration.

Dual-functional silver nanoparticle-enhanced ZnO nanorods for improved reactive oxygen species generation and cancer treatment

Recent advancements in sonodynamic therapy (SDT) for cancer treatment have highlighted the potential of enhancing reactive oxygen species (ROS) generation and improving therapeutic outcomes. This study introduces zinc oxide (ZnO) nanorods (NRs) in situ loaded with silver nanoparticles (ZnO@Ag NRs), designed to optimize ROS production under ultrasound irradiation and offer significant advantages in tumor specificity and biosafety. The transmission electron microscopy and elemental mapping confirmed the consistent size and monodispersed Ag nanoparticle for ZnO@Ag NR. Sonodynamic properties showed that ZnO@Ag NRs produce higher singlet oxygen and hydroxyl radicals under ultrasound. In vitro studies demonstrated excellent biocompatibility and enhanced cell-killing effects of ZnO@Ag NRs on CT-26 cells, while in vivo results confirmed its superior anti-tumor efficacy and biosafety. Furthermore, the ZnO@Ag NRs' antibacterial properties were also confirmed, suggesting additional benefits in treating cancers associated with bacterial infections. Collectively, these findings establish ZnO@Ag NRs as a potent and safe agent for ultrasound-driven cancer therapy.

Potential application and prospects of ROS-sensitive biomaterials in cancer therapy: a immune microenvironment triggered nanomaterial

Reactive Oxygen Species (ROS) is the collective term used for the extremely reactive molecules that are important mediators in physiological processes as well as the development of various disease conditions. Normal cells maintain a delicate equilibrium, known as redox homeostasis, between antioxidants and ROS levels. Any imbalance in the redox homeostasis of the body results in oxidative stress which can result in inflammation, necrosis, apoptosis, cell death, and eventually a disease state. Enhanced ROS levels are a key feature in cancer cells that is being explored for developing reactive oxygen species-sensitive biomaterials. The distinct variation in redox potential between normal cells and tumour cells is one of the major physiological differences between them, that has enabled the development of ROS-sensitive nanomaterials for cancer therapy. ROS-sensitive nanomaterials are sensitive to the physiological variations in the cells, like high levels of hydrogen peroxide and glutathione in the cancer cells. ROS-responsive nanomaterials have the unique property of modulating microenvironmental redox conditions in cancer cells. ROS-sensitive material can work either by scavenging the ROS or by simulating the cellular antioxidants, leading to cancer cell cytotoxicity. These ROS-sensitive nanomaterials can simulate the human body's natural antioxidants like, superoxide dismutase and peroxidase. Thus, ROS-sensitive nanomaterials hold promise as a potential platform for the treatment of cancer. The present review will cover the importance of ROS in cancer, the different types of ROS-sensitive nanomaterials available and their therapeutic application in cancer therapy.

Synergistic polyphenol-amino acid nanoparticles: a new strategy for reactive oxygen species management

Polyphenols exhibit strong antioxidant, and anti-inflammatory but are limited by chemical instability and low bioavailability. To address these challenges, we developed polyphenol-amino acid conjugates that self-assemble into stable nanospheres, enhancing their stability and bioavailability. These nanoparticles demonstrate significantly improved ROS scavenging efficiency and promote cell proliferation in vitro. The incorporation of amino acids enhances biocompatibility and facilitates effective ROS elimination. The polyphenol-amino acid nanoparticles offer a multifaceted therapeutic strategy to mitigate oxidative stress, overcoming traditional antioxidant limitations through advanced nanotechnology. This approach contributes to the development of next-generation wound care solutions with enhanced efficacy and safety profiles.

Application trends of hydrogen-generating nanomaterials for the treatment of ROS-related diseases

Reactive oxygen species (ROS) play essential roles in both physiological and pathological processes. Under physiological conditions, appropriate amounts of ROS play an important role in signaling and regulation in cells. However, too much ROS can lead to many health problems, including inflammation, cancer, delayed wound healing, neurodegenerative diseases (such as Parkinson's disease and Alzheimer's disease), and autoimmune diseases, and oxidative stress from excess ROS is also one of the most critical factors in the pathogenesis of cardiovascular and metabolic diseases such as atherosclerosis. Hydrogen gas effectively removes ROS from the body due to its good antioxidant properties, and hydrogen therapy has become a promising gas therapy strategy due to its inherent safety and stability. The combination of nanomaterials can achieve targeted delivery and effective accumulation of hydrogen, and has some ameliorating effects on diseases. Herein, we summarize the use of hydrogen-producing nanomaterials for the treatment of ROS-related diseases and talk about the prospects for the treatment of other ROS-induced disease models, such as acute kidney injury.

Topotactic Transformation in Fe3O4 Induces Spontaneous Growth of Compositionally Diverse Nanostructures

Topotactic transformation is an emerging strategy for synthesizing materials with exotic functional properties. In this report, instead of producing new crystals with related structures, we exploited the topotactic transformation phenomenon to spontaneously produce compositionally diverse nanostructures on the transforming substrate. The surface of magnetite nanoparticles (Fe3O4 NPs) is topotactically transformed into maghemite (γ-Fe2O3). Benefiting from such oxidation susceptibility of ultrasmall Fe3O4 NPs, we achieved spontaneous growth of metals (Ag, Au, Pt, and Pd), a non-metal (Se), and a metal oxide (MnO2) based nanostructures onto the surface of Fe3O4. No spontaneous growth of nanostructures was observed when the oxidized Fe3O4 NPs were tested, likely due to the loss of the Fe2+-associated mobile electrons. The obtained nanostructures displayed appreciable antioxidant activities, which we utilized to effectively treat inflammation in the intestines. It is anticipated that this synthetic route, based on topotactic transformation, represents a significant advancement in synthesizing various chemically diverse hetero-nanostructures.

Preparation, characterization, and pesticide adsorption capacity of chitosan-magnetic graphene oxide nanoparticles with toxicological studies

This study investigated magnetic graphene oxide nanoparticles (MGO-NPs) and functionalized with chitosan (CS-MGO-NPs) for removing florasulam, metalaxyl, and thiamethoxam pesticides from water. A comprehensive characterization employing Fourier transform infrared spectroscopy (FTIR), scanning electron microscopy (SEM), zeta potential measurements, XRD analysis, and surface area/porosity determinations confirmed the successful synthesis of the composites with the desired properties. Factorial experimental design was applied to identify the most significant factors of pesticide concentration, adsorbent amount, temperature, pH, agitation time, and ionic strength on the efficiency of removal of tested pesticides from water samples. CS-MGO-NPs exhibited superior removal efficiencies for all three pesticides compared to MGO-NPs. They achieved high removal rates for florasulam (average 92.94%) and metalaxyl (average 88.95%), while demonstrated moderate effectiveness against thiamethoxam (average 64.04%). Different kinetic and isotherm models described how well the nanoparticles adsorbed each pesticide. According to these models, the pseudo-first-order kinetic model interpreted well the adsorption of florasulam, and thiamethoxam onto CS-GO-NPs. While the pseudo-second-order kinetic model interpreted well the adsorption of metalaxyl. The Freundlich isotherm model gave the best fit with florasulam onto CS-GO-NPs. While the Langmuir isotherm model gave the best fit with metalaxyl and thiamethoxam. Finally, the toxicological studies of CS-MGO-NPs in rats were performed, and it was found negative effects at high doses, suggesting caution is needed for practical applications. Overall, this study shows promise for CS-MGO-NPs in water purification, but safety needs further investigation.

The mitochondrial membrane potential and the sources of reactive oxygen species in the hemocytes of the ark clam Anadara kagoshimensis under hypoosmotic stress

To compensate for changes in cell volume caused by changes in salt concentration, mollusks use regulatory mechanisms such as the regulation of volume decrease (RVD). This may increase the rate of aerobic metabolism and lead to an increase in reactive oxygen species (ROS). This study examined the production of ROS in the mitochondria of Anadara kagoshiensis hemocytes, the effect of mitochondrial inhibitors on osmotic stability in hemocytes, and the dynamics of changes in ROS levels and mitochondrial membrane potential when RVD is activated under hypo-osmotic conditions. Hemocytes maintained at a control osmolarity of 460 mOsm l-1 showed significant decreases in ROS production following incubation with complex III inhibitors (S3QEL). Hypoosmotic shock stimulated RVD in all experimental groups. The cell volume increased by about 70 % immediately after osmolarity was reduced, and then decreased by about 40 % over the next 30 min. A reduction in osmolarity from about 460 to 200 mOsm l-1 significantly decreased ROS and mitochondrial potentials in A. kashimensis hemocyctes. Inhibitors of mitochondrial complexes did not affect changes in ROS or mitochondria potentials in A kashimiensis hemocytes under hypoosmotic conditions or in hemocyte volume regulation mechanisms.

Homocysteine S-Methyltransferase 3 Positively Regulates Cadmium Tolerance in Maize

The increasing contamination of agricultural soils with cadmium (Cd) poses a significant threat to human health and global food security. Plants initiate a series of mechanisms to reduce Cd toxicity. However, the response of maize to Cd toxicity remains poorly understood. In this study, we identified that ZmHMT3, which encodes a homocysteine S-methyltransferases family protein, acted as a regulator of Cd tolerance in maize. Subcellular localization and in situ PCR exhibited that ZmHMT3 was localized in the cytoplasm and predominantly expressed in the phloem. Overexpression of ZmHMT3 enhanced Cd tolerance and reduced Cd concentration in both shoots and roots. In contrast, ZmHMT3 mutants attenuated Cd tolerance but did not change shoot Cd concentration. Heterologous overexpression of ZmHMT3 in rice enhanced Cd tolerance and reduced grain Cd concentration. Transcriptome analysis revealed that ZmHMT3 upregulated the expression of stress-responsive genes, especially glutathione S-transferases (GSTs) and transcription factors, including MYBs, NACs and WRKYs, and modulates the expression of different ATP-binding cassette (ABC) transporters, thereby enhancing Cd tolerance. Collectively, these findings highlight the pivotal role of ZmHMT3 in Cd tolerance and as a candidate gene for improving Cd tolerance in elite maize varieties.

Polyoxometalate-based injectable coacervate inhibits HCC metastasis after incomplete radiofrequency ablation via scavenging ROS

BACKGROUND

Incomplete radiofrequency ablation (iRFA) stimulates residual hepatocellular carcinoma (HCC) metastasis, leading to a poor prognosis for patients. Therefore, it is imperative to develop an effective therapeutic strategy to prevent iRFA-induced HCC metastasis.

RESULTS

Our study revealed that iRFA induced an abnormal increase in ROS levels within residual HCC, which enhanced tumor cell invasiveness and promoted macrophage M2 polarization, ultimately facilitating HCC metastasis. Molybdenum-based polyoxometalate (POM) is an excellent ROS-scavenging nanocluster, but its size is too small to be easily cleared by the kidneys, limiting its effectiveness in scavenging iRFA-induced ROS. To overcome this limitation, we synthesized an injectable POM-loaded coacervate delivery system named POM@Coa, which can sustainably scavenge iRFA-induced ROS by slowly releasing POM. POM@Coa markedly reduced HCC invasiveness, reversed macrophage polarization from M2 to M1, and promoted the infiltration and activation of CD8+ T cells, ultimately inhibiting HCC metastasis. Importantly, POM@Coa showed superior therapeutic efficacy to free POM in the absence of systemic toxicity.

CONCLUSIONS

POM@Coa exhibits the potential to decrease HCC invasiveness and activate anti-tumor immunity, opening up new avenues for the safe and effective treatment and prevention of HCC metastasis when combined with RFA.

Colloidal ZnAl-Layered Double Hydroxide Nanomaterials for Effective Prevention of SARS-CoV-2

SARS-CoV-2 is a threat to global public health, which requires the development of safe measures to reduce the spread of this coronavirus. Herein, in this study, we prepared and examined potential antiviral agents based on ZnAl-layered double hydroxide (ZnAl-LDH) materials. ZnAl-LDH-based samples were synthesized via a one-pot low-temperature coprecipitation method, which features an ultrathin structure. The incorporation of trace amounts of Ag induces the formation of ZnO particles on the ZnAl-LDH surface, where both ZnO and Ag enhance UV light absorption. Interestingly, ZnAl-LDH-Ag shows a significantly high anticoronavirus effect upon exposure to the daylight lamp of the operation console and ultraviolet light. Moreover, ZnAl-LDH and ZnAl-LDH-Ag potently blocked the entry of SARS-CoV-2 pseudoparticles to cells. The in vivo biocompatibility experiment has demonstrated that ZnAl-LDH-Ag is a potentially biocompatible and potent anti-SARS-CoV-2 agent for virus prevention. The synergistic interactions between these nanoparticles continuously generate reactive oxygen species (ROS), leading to effective and sustained viral inactivation. This light-sensitive ROS production introduces a photocatalytic inactivation mechanism in antiviral materials. Moreover, unlike conventional antiviral agents that rapidly deplete their active components, the layered structure of this composite enables the controlled long-term release of antiviral radicals, enhancing its durability. ZnAl-LDH-Ag has been expected to be a promising solution for long-lasting antiviral applications.

Catalytic Biomaterials-Activated In Situ Chemical Reactions: Strategic Modulation and Enhanced Disease Treatment

Chemical reactions underpin biological processes, and imbalances in critical biochemical pathways within organisms can lead to the onset of severe diseases. Within this context, the emerging field of "Nanocatalytic Medicine" leverages nanomaterials as catalysts to modulate fundamental chemical reactions specific to the microenvironments of diseases. This approach is designed to facilitate the targeted synthesis and localized accumulation of therapeutic agents, thus enhancing treatment efficacy and precision while simultaneously reducing systemic side effects. The effectiveness of these nanocatalytic strategies critically hinges on a profound understanding of chemical kinetics and the intricate interplay of reactions within particular pathological microenvironments to ensure targeted and effective catalytic actions. This review methodically explores in situ catalytic reactions and their associated biomaterials, emphasizing regulatory strategies that control therapeutic responses. Furthermore, the discussion encapsulates the crucial elements-reactants, catalysts, and reaction conditions/environments-necessary for optimizing the thermodynamics and kinetics of these reactions, while rigorously addressing both the biochemical and biophysical dimensions of the disease microenvironments to enhance therapeutic outcomes. It seeks to clarify the mechanisms underpinning catalytic biomaterials and evaluate their potential to revolutionize treatment strategies across various pathological conditions.

Tea polyphenols nanoparticles integrated with microneedles multifunctionally boost 5-aminolevulinic acid photodynamic therapy for skin cancer

5-aminolevulinic acid photodynamic therapy (ALA-PDT) is an emerging therapeutic strategy for skin cancer due to its noninvasiveness and high spatiotemporal selectivity. However, poor skin penetration, poor intratumoral delivery, the instability of aqueous ALA, and the tumor's inherent hypoxia microenvironment are major hurdles hindering the efficacy of ALA-PDT. Herein, we aim to address these challenges by using microneedles (MNs) to assist in delivering nanoparticles based on natural polymeric tea polyphenols (TP NPs) to self-assemble and load ALA (ALA@TP NPs). The TP NPs specifically increase cellular uptake of ALA by A375 and A431 cells and reduce mitochondrial membrane potential. Subsequently, the photosensitizer protoporphyrin IX derived from ALA accumulates in the tumor cells in a dose-dependent manner with TP NPs, generating reactive oxygen species to promote apoptosis and necrosis of A375 and A431 cells. Interestingly, TP NPs can ameliorate the tumor's inherent hypoxia microenvironment and rapid oxygen consumption during PDT by inhibiting hypoxia inducible factor-1α, thereby boosting reactive oxygen species (ROS) generation and enhancing ALA-PDT efficacy through a positive feedback loop. After ALA@TP NPs are loaded into MNs to fabricate ALA@TP NPs@MNs, the MNs enhance skin penetration and storage stability of ALA. Importantly, they exhibit remarkable antitumor efficacy in A375-induced melanoma and A431-induced squamous cell carcinoma with a reduced dose of ALA and reverse hypoxia in vivo. This study provides a facile and novel strategy that integrates MNs and green NPs of TP for addressing the bottlenecks of ALA-PDT and enhancing the ALA-PDT efficacy against skin cancers for future clinical translation.

On Multicell-Interaction Chip: In Situ Observing the Interactions between the Astrocytes with Lysosomal Dysfunction and BBB Cells

Lysosomes in astrocytes play vital roles in toxic protein degradation in the brain. Lysosomal dysfunction can lead to abnormal protein deposits, which further induce damage to neurons and the blood-brain barrier (BBB), and thereby affect the interaction between the nervous and vascular systems. Therefore, investigating the interactions between astrocytes with lysosomal dysfunction and BBB cells is of significant importance. However, the lack of effective in vitro models hinders the study of this complex system. Herein, an 8-well arrayed microfence multicell interculture chip (AMMIC) with a hydrophilically optimized surface is introduced for investigating the interactions between astrocytes and BBB cells. Then, a novel lysosome-targeted photosensitizer, IVQ-2Br, is synthesized for inducing controllable oxidative stress damage in the lysosomes of astrocytes. By the combination of the 8-well AMMIC and IVQ-2Br, a model for studying the interactions between astrocytes with lysosomal dysfunction and BBB cells has been constructed. Particularly, severe secondary injuries to BBB cells brought about by oxidative stress, including alterations in cell morphology and activity as well as notable DNA damage, are in situ observed on the 8-well AMMIC. The mediators involved in this oxidative stress injury-mediated intercellular communication are validated to be reactive oxygen species (ROS) and exosomes. This work not only presents an in vitro modeling method for studying cell-cell interactions but also demonstrates the potential of in vitro models constructed through the integration of complex microfluidic chip techniques and photosensitizers for advancing biomedical research.

From Bench to Bedside: ROS-Responsive Nanocarriers in Cancer Therapy

Reactive oxygen species (ROS) play a dual role in cancer, acting as both signaling molecules that promote tumour growth and as agents that can inhibit tumour progression through cytotoxic effects. In cancer therapy, ROS-responsive drug delivery systems take advantage of the elevated ROS levels found in tumors compared to healthy tissues. These systems are engineered to release drugs precisely in response to increased ROS levels in tumour cells, allowing targeted and controlled treatment, minimizing side effects, and enhancing therapeutic outcomes. ROS generation in cancer cells is linked to metabolic changes, mitochondrial dysfunction, and oncogenic signaling, leading to increased oxidative stress. Tumour cells manage this by upregulating antioxidant defenses to prevent ROS from reaching harmful levels. This balance between ROS production and neutralization is critical for cancer cell survival, making ROS both a challenge and an opportunity for targeted therapies. ROS also connect inflammation and cancer. Chronic inflammation leads to elevated ROS, which can damage DNA and proteins, promoting mutations and cancer development. Additionally, ROS contribute to protein degradation, affecting essential cellular functions. Therapeutic strategies targeting ROS aim to either increase ROS beyond tolerable levels for cancer cells or inhibit their antioxidant defenses. Nanocarriers responsive to ROS show great potential in improving the precision of cancer treatments by releasing drugs specifically in high ROS environments, like tumors. This review discusses the mechanisms of ROS in cancer, its role in inflammation and protein degradation, and the advances in ROS-targeted nanocarrier therapies across different cancer types.

Multifaceted role of nanocomposite hydrogels in diabetic wound healing: enhanced biomedical applications and detailed molecular mechanisms

The complex microenvironment of diabetic wounds, which is characterized by persistent hyperglycemia, excessive inflammatory responses, and hypoxic conditions, significantly impedes the efficacy of traditional hydrogels. Nanocomposite hydrogels, which combine the high-water content and biocompatibility of hydrogels with the unique functionalities of nanomaterials, offer a promising solution. These hydrogels exhibit enhanced antibacterial, antioxidant, and drug-release properties. Incorporating nanomaterials increases the mechanical strength and bioactivity of hydrogels, allowing for dynamic regulation of the wound microenvironment and promoting cell migration, proliferation, and angiogenesis, thereby accelerating wound healing. This review provides a comprehensive overview of the latest advances in nanocomposite hydrogels for diabetic wound treatment and discusses their advantages and molecular mechanisms at various healing stages. The study aims to provide a theoretical foundation and practical guidance for future research and clinical applications. Furthermore, it highlights the challenges related to the mechanical durability, antimicrobial performance, resistance issues, and interactions with the cellular environments of these hydrogels. Future directions include optimizing smart drug delivery systems and personalized medical approaches to enhance the clinical applicability of nanocomposite hydrogels.

Advanced technology in fruit preservation: Effects of nanoscale charged water particles on storage quality and reactive oxygen species in blueberries

During the postharvest period, blueberries with a short shelf life due to microbial activity and an overload of reactive oxygen species (ROS) were still a major unresolved problem. In this study, the effect of nanoscale charged water particles (NCWP) treatment on the postharvest characteristics and ROS metabolism in blueberries (Vaccinium ashei Reade) were investigated. The results showed that NCWP treatment significantly inhibited microbial growth, maintained high firmness and commercial acceptability, and extended the storage period of blueberries. The nutrient of blueberries was retained and elevated after NCWP treatment, especially in the 6 d of NCWP-9 h treatment, the total phenol and anthocyanin content reached the peak at 565.1 mg/L and 5.26 mg/g, which contribute to the total antioxidant capacity of blueberries increased. SEM showed that NCWP-9 h treatment maintained the integrity of the cuticular wax of the blueberry peel, which indirectly decelerated the decline of blueberry firmness. The NCWP treatment significantly enhanced the antioxidant enzyme system of blueberry peel. On days 2, 4 and 6 after NCWP-9 h treatment, the CAT, SOD and APX activities were significantly different from the control group (P < 0. 05), with 585.09 ΔA/min/g, 79.34 U/g and 3.32 umol/min/g, respectively, which effectively scavenged the oxidative stress markers (H2O2, O2-) accumulated in the blueberry peels, and slowed down the aging and deteriorated of the blueberry process. This finding demonstrates that NCWP is an effective postharvest preservation method for blueberries and provides a viable strategy for quality maintenance in the postharvest fruit and vegetable sector.

Ultra-Small Copper-Based Multienzyme-Like Nanoparticles Protect Against Hepatic Ischemia-Reperfusion Injury Through Scavenging Reactive Oxygen Species in Mice

Hepatic ischemia-reperfusion injury (IRI) is a severe complication that occurs in the process of liver transplantation, hepatectomy, and other end-stage liver disease surgery, often resulting in the failure of surgery operation and even patient death. Currently, there is no effective way to prevent hepatic IRI clinically. Here, it is reported that the ultra-small copper-based multienzyme-like nanoparticles with catalase-like (CAT-like) and superoxide dismutase-like (SOD-like) catalytic activities significantly scavenge the surge-generated endogenous reactive oxygen species (ROS) and effectively protects hepatic IRI. Density functional theory calculations confirm that the nanoparticles efficiently scavenge ROS through their synergistic effects of the ultra-small copper SOD-like activity and manganese dioxides CAT-like activity. Furthermore, the results show that the biocompatible CMP NPs significantly protected hepatocytes from IRI in vitro and in vivo. Importantly, their therapeutic effect is much stronger than that of N-acetylcysteamine acid (NAC), an FDA-approved antioxidative drug. Finally, it is demonstrated that the protective effects of CMP NPs on hepatic IRI are related to suppressing inflammation and hepatocytic apoptosis and maintaining endothelial functions through scavenging ROS in liver tissues. The study can provide insight into the development of next-generation nanomedicines for scavenging ROS.

Single-Atom Catalysts with Isolated Cu1-N4 Sites for Atopic Dermatitis Cascade Catalytic Therapy via Activating PPAR Signaling

Atopic dermatitis (AD) is one of the most common allergic skin disorders affecting over 230 million people worldwide, while safe and efficient therapeutic options for AD are currently rarely available. Reactive oxygen species (ROS) accumulation plays a key role in AD's disease progression. Therefore, a novel single-atom catalyst is designed with isolated Cu1-N4 sites anchored on carbon support (Cu1-N4 ISAC), featuring triple antioxidant enzyme-mimicking activities, for efficient AD cascade catalytic therapy (CCT). The excellent superoxide dismutase (SOD)-, glutathione peroxidase (GPx)-, and ascorbate peroxidase (APx)-like activities of Cu1-N4 ISACs enable the sequential conversion of O2•- to H2O2 and then to harmless H2O, thereby protecting keratinocytes from oxidative stress damage. Notably, two novel experimental methods are developed to directly prove the SOD-GPx and SOD-APx cascade catalytic activities for the first time. In vivo experiments show that Cu1-N4 ISACs are more potent than a recommended typical medicine (halcinonide solution). Additionally, RNA sequencing and bioinformatic analysis reveal that Cu1-N4 ISACs reduce inflammation and inhibit ROS production by activating PPAR signaling, which is aberrantly reduced in AD. Therefore, the synthesized catalytic medicine offers an alternative to alleviate AD and has the potential to serve as PPAR agonists for treating similar diseases.

Nanomaterials: Recent Advances in Knee Osteoarthritis Treatment

Osteoarthritis (OA) of the knee is the most prevalent degenerative joint condition that places a substantial financial and medical burden on society. However, due to drawbacks such as inefficiency, adverse effects, and brief duration of action, the clinical efficacy of the current major therapies for knee OA is largely restricted. Therefore, novel medication development is highly required to address these issues. Numerous studies in recent years have established that nanomaterials can be a potential and highly effective way to overcome these challenges. In this review, the anatomical distinctions between healthy and OA knee joints, as well as novel advances in the field of nanomaterials for the treatment of knee OA are summarized. The limits of the present therapeutic strategies for treating knee OA are also highlighted, as well as the potential prospects of nanomaterials in the future.

Nanomaterial-enabled drug transport systems: a comprehensive exploration of current developments and future avenues in therapeutic delivery

Over the years, nanotechnology has gained popularity as a viable solution to address gene and drug delivery challenges over conventional methods. Extensive research has been conducted on nanosystems that consist of organic/inorganic materials, drugs, and its biocompatibility become the primary goal of improving drug delivery. Various surface modification methods help focus targeted and controlled drug release, further enabling multidrug delivery also. This newer technology ensures the stability of drugs that can unravel the mechanisms involved in cellular processes of disease development and its management. Tailored medication delivery provides benefits such as therapy, controlled release, and reduced adverse effects, which are especially important for controlling illnesses like cancer. However, multifunctional nanocarriers that possess high viscoelasticity, extended circulation half-life, biocompatibility, and biodegradability face some challenges and limitations too in human bodies. To produce a consistent therapeutic platform based on complex three-dimensional nanoparticles, careful design and engineering, thorough orthogonal analysis methods, and reproducible scale-up and manufacturing processes will be required in the future. Safety and effectiveness of nano-based drug delivery should be thoroughly investigated in preclinical and clinical trials, especially when considering biodistribution, targeting specific areas, and potential immunological toxicities. Overall, the current review article explores the advancements in nanotechnology, specific to nanomaterial-enabled drug delivery systems, carrier fabrication techniques and modifications, disease management, clinical research, applications, limitations, and future challenges. The work portrays how nanomedicine distribution affects healthcare with an emphasis on the developments in drug delivery techniques.

Nanomaterial-based regulation of redox metabolism for enhancing cancer therapy

Altered redox metabolism is one of the hallmarks of tumor cells, which not only contributes to tumor proliferation, metastasis, and immune evasion, but also has great relevance to therapeutic resistance. Therefore, regulation of redox metabolism of tumor cells has been proposed as an attractive therapeutic strategy to inhibit tumor growth and reverse therapeutic resistance. In this respect, nanomedicines have exhibited significant therapeutic advantages as intensively reported in recent studies. In this review, we would like to summarize the latest advances in nanomaterial-assisted strategies for redox metabolic regulation therapy, with a focus on the regulation of redox metabolism-related metabolite levels, enzyme activity, and signaling pathways. In the end, future expectations and challenges of such emerging strategies have been discussed, hoping to enlighten and promote their further development for meeting the various demands of advanced cancer therapies. It is highly expected that these therapeutic strategies based on redox metabolism regulation will play a more important role in the field of nanomedicine.

A Novel pH-Responsive Nano-Sized Lanthanum-Doped Polyvinyl Alcohol-Carbon Quantum Dot Composite for Root Canal Irrigation

Purpose

The primary goals of endodontic therapy are to eliminate microbes and prevent reinfection. Persistent root canal infections and failure of root canal therapy are primarily attributed to the presence of bacteria, particularly E. faecalis. Chemical irrigants play a crucial role in complementing mechanical instrumentation in ensuring adequate disinfection. However, current techniques and available irrigants are limited in their ability to achieve optimal sterilization of the root canal system. In this study, we developed a novel material called La@PCDs by combining CQD-PVA and lanthanum for root canal irrigation.

Methods

A one-pot hydrothermal method was used to prepare composites of lanthanum and CQD-PVA (La@PCDs). Scanning electron microscopy (SEM), Fourier-transform infrared (FTIR) spectroscopy and the particle size were employed to characterize La@PCDs. ROS generation was evaluated by measuring the fluorescence intensity emitted at 525 nm from 2',7'-dichlorodihydrofluorescein diacetate (DCFH-DA). In vitro experiments were conducted to assess the effectiveness of the nanoparticles in combating Enterococcus faecalis and eradicating in situ biofilm eradication in root canal. Furthermore, cytotoxicity assessments were carried out to demonstrate the safety of La@PCDs.

Results

SEM and FTIR results showed that La@PCDs were successfully prepared and exhibiting a homogeneous size distribution and irregular morphology. ROS assessment demonstrated that La@PCDs have a synergistic effect, promoting the production of a large number of ROS. This effect only occurred under acidic PH conditions. The inherent acidity in the biofilm microenvironment can act as internal stimulus. In vitro experiments revealed superior antibacterial efficiency under acidic conditions without causing significant cytotoxicity compared to the commonly used NaClO irrigant. The biosafety of La@PCDs was confirmed.

Conclusion

Compared to existing materials, these nanoparticles exhibit favorable antibacterial and anti-biofilm properties, along with improved biocompatibility. These findings emphasize the potential of the integrated La@PCDs as a promising option for enhancing root canal irrigation and disinfection.

Chiral nanoenzymes: synthesis and applications

Chiral nanoenzymes are a new type of material that possesses both chiral nanostructures and enzymatic catalytic activity. These materials exhibit selectivity in their catalytic activity towards organisms due to the introduction of chiral features in nanomaterials and have inherent chiral discrimination in organisms. As synthetic enzymes, chiral nanoenzymes offer significant advantages over natural enzymes. Due to their unique chiral structure and distinctive physicochemical properties, chiral nanoenzymes play an important role in various fields, including biology, medicine, and environmental protection. Their strong stereospecificity and biocompatibility make them useful in disease therapy, biosensing, and chiral catalysis, setting them apart from conventional and natural enzymes. In recent years, the design of synthetic methods and biological applications of chiral nanoenzymes has received significant attention and extensive research among scientists. This paper provides a systematic review of the research progress in the discovery, development, and application of chiral nanoenzymes in the last decade. Additionally, it presents various applications of chiral nanoenzymes, such as disease therapy, biosensing, and chiral catalysis. Finally, the challenges and future prospects of chiral nanoenzymes are discussed.

Preparation and antioxidant properties of tannic acid/copper ion nanozyme hybrid nanofibrous membranes

Excess free radicals can have some negative effects on human health. In this paper, a nanozyme was successfully constructed by the coordination of copper ions and tannic acid, and its structure and elemental distribution were determined by Fourier transform infrared spectroscopy, scanning electron microscopy and X-ray photoelectron spectroscopy. Free radical scavenging experiments confirmed that it possessed superoxide dismutase-like activity, catalase-like activity, and hydroxyl radical scavenging ability. The results of thermogravimetric analysis experiments demonstrated that it possessed good thermal stability. A polyacrylonitrile hybrid nanofibrous membrane loaded with Cu/TA nanozyme was successfully constructed by electrospinning technology, and the maximum scavenging rate of DPPH and ABTS radicals can reach 64.22% and 58.44%, respectively. The nanofiber membrane also exhibited the ability to protect cells from oxidative stress damage. Therefore, the hybrid nanofibrous membrane has a broad application prospect in fields such as food preservation and biomedicine.

Carbon Dots in the Pathological Microenvironment: ROS Producers or Scavengers?

Reactive oxygen species (ROS), as metabolic byproducts, play pivotal role in physiological and pathological processes. Recently, studies on the regulation of ROS levels for disease treatments have attracted extensive attention, mainly involving the ROS-induced toxicity therapy mediated by ROS producers and antioxidant therapy by ROS scavengers. Nanotechnology advancements have led to the development of numerous nanomaterials with ROS-modulating capabilities, among which carbon dots (CDs) standing out as noteworthy ROS-modulating nanomedicines own their distinctive physicochemical properties, high stability, and excellent biocompatibility. Despite progress in treating ROS-related diseases based on CDs, critical issues such as rational design principles for their regulation remain underexplored. The primary cause of these issues may stem from the intricate amalgamation of core structure, defects, and surface states, inherent to CDs, which poses challenges in establishing a consistent generalization. This review succinctly summarizes the recently progress of ROS-modulated approaches using CDs in disease treatment. Specifically, it investigates established therapeutic strategies based on CDs-regulated ROS, emphasizing the interplay between intrinsic structure and ROS generation or scavenging ability. The conclusion raises several unresolved key scientific issues and prominent technological bottlenecks, and explores future perspectives for the comprehensive development of CDs-based ROS-modulating therapy.

Ultra-small platinum nano-enzymatic spray with ROS scavenging and anti-inflammatory properties for photoaging treatment

Photoaging induced by ultraviolet (UV) results in oxidative stress and inflammation. Noble metal nanozymes have strong antioxidant and anti-inflammatory capacity, which are expected to eliminate the excessive reactive oxygen species (ROS) and inflammatory factors in the photoaged skin. Hence, we have synthesized ultrasmall platinum nanoparticles coated with polyvinylpyrrolidone (Pt NPs) with a diameter of nearly 5 nm for photoaging treatment. Thanks to multi-enzymatic capacities (catalase, peroxidase, and superoxide dismutase) of Pt NPs, they can effectively protect fibroblasts from UV-induced ROS attack, relieve fibroblasts from UV-induced cell cycle arrest, downregulate matrix metalloproteinases (MMPs) to regenerate type I collagen, and inhibit M1 macrophage polarization to decrease the expression of inflammatory factors. For photoaged mice treatment, we employ the concept of routine spray skincare and encapsulate Pt NPs solution in a spray bottle. In combination with roller needle, following Pt NPs nano-enzymatic spray given, UV-induced photoaged mice display reduced wrinkle formation in the collagen-depleted dermal tissue of mice and more youthful performance in both appearance and organizational structure. Consequently, multi-enzymatic functions of Pt NPs nano-spray offers a promising avenue for anti-photoaging therapy, providing potential benefits in both preventative and restorative skincare applications.

Stable Leonurus cardiaca L. polysaccharide-stabilized palladium nanoparticles for sensitive colorimetric detection of acetylcholine

Imbalances in acetylcholine levels within the human body readily precipitate neurological disorders. Hence, establishing a highly efficient and sensitive acetylcholine detection platform is of paramount importance. Palladium-based nanoparticles have high catalytic performance, which is of profoundly important in the development of nanozyme technology. Herein, we focused on extracting Leonurus cardiaca L. polysaccharide (LCLP) from Leonurus cardiaca L., which possesses an average molecular weight of 11,910 Da. Meanwhile, it has certain reducing power. Leonurus cardiaca L. polysaccharide-stabilized palladium nanoparticles (Pdn-LCLP NPs) were prepared. Pdn-LCLP NPs exhibited remarkable peroxidase-like properties due to their ability to decompose H2O2 into OH. In addition, Pdn-LCLP NPs were combined with the chromogenic substrate 3,3',5,5'-tetramethylbenzidine to form a colorimetric detection system for the detection of acetylcholine. The linear detection range and the limit of detection were 10 μM-200 μM and 1.02 μM (S/N = 3), respectively. This research broadened the horizon for the development of acetylcholine colorimetric biosensing systems.

Salvaging myocardial infarction with nanoenzyme-loaded hydrogels: Targeted scavenging of mitochondrial reactive oxygen species

Myocardial infarction resulting from coronary artery atherosclerosis is the leading cause of heart failure, which represents a significant global health burden. The limitations of conventional pharmacologic thrombolysis and flow reperfusion procedures highlight the urgent need for new therapeutic strategies to effectively treat myocardial infarction. In this study, we present a novel biomimetic approach that integrates polyphenols and metal nanoenzymes, inspired by the structure of pomegranates. We developed tannic acid-coated Mn-Co3O4 (MCT) nanoparticles in combination with an injectable collagen hydrogel for the effective treatment of myocardial infarction. The hydrogel enhanced the infarct microenvironment, while the slow-released MCT targets mitochondria to inhibit the post-infarction surge of reactive oxygen species, providing anti-apoptotic and anti-inflammatory effects. RNA sequencing revealed the potential of hydrogels to serve as an interventional mechanism during the post-infarction inflammatory phase. Notably, we found that the hydrogel, when combined with the nanopomegranate-based therapy, significantly improves adverse ventricular remodeling and restores cardiac function in early infarction management. The MCT hydrogel leverages the unique benefits of both MCT nanopomegranates and collagen, demonstrating a synergistic effect. This approach provides a promising example of the potential cooperation between nanomimetic structures and natural biomaterials in therapeutic applications.

Novel Collagen Analogs with Multicopy Mucin-Type Sequences for Multifunctional Enhancement Properties Using SUMO Fusion Tags

Multifunctional enhanced collagen materials in green biomanufacturing are highly desired yet challenging due to the poor comprehensive performance caused by the adoption of targeting monofunctional peptides. Herein, novel collagen analog design strategy using multicopy tandem of mucin-type sequence (GAPGAPGSQGAPGLQ) derived from human COL1α1 to construct basic building blocks is reported, in which SUMO tag is added to the N-terminal of the protein as a stabilizing core. In particular, novel collagen analogs (named S1506, S1511, S1523, and S1552) with multicopy mucin-type sequences (repeated 6, 11, 23, and 52 times), which were constructed in Escherichia coli, have distinct orientation preferences of functional enhancement (including cell proliferation, differentiation, migration, antioxidant activity, and anti-inflammatory property) compared to COL1α1 in HaCaT and THP-1 cell experiments due to variant three-dimensional structures (the different-length mucin-type polypeptide chains wind around central SUMO tag). Our findings suggest that the innovative protein design and synthesis approaches employed in the construction of these novel S15 proteins have the potential to advance the development of new types of recombinant collagen analogs.

Paralysis caused by dinotefuran at environmental concentration via interfering the Ca2+-ROS-mitochondria pathway in Chironomus kiiensis

Introduction

Dinotefuran as the third-generation of neonicotinoid insecticides is extensively used in agriculture worldwide, posing a potential toxic threat to non-target animals and humans. However, the chronic toxicity mechanism related to mitochondria damage of dinotefuran to non-target animals at environmental concentration is unclear.

Methods

In this study, the mitochondria damage and oxidative stress of dinotefuran on Chironomus kiiensis were investigated at environmental concentrations by long-term exposure. At the same time, relevant gene expressions of these toxicity indexes were measured as sensitive ecotoxicity biomarkers to reflect the toxic effects of dinotefuran on Chironomidae.

Results

Our present study showed that chronic exposure to environmental concentrations of dinotefuran resulted in behavioral inhibition in the larvae of Chironomidae. For burrowing inhibition of 10 days, the lowest observed-effect concentration (LOEC) and 50% inhibitory concentration (IC50) were 0.01 (0.01-0.04) and 0.60 (0.44-0.82) μg/L, respectively. Dinotefuran promoted the release of intracellular calcium ions (Ca2+) in Chironomidae via dysregulating the gene expressions of atp2b, camk ii, and calm. Subsequently, the disruption of the Ca2+ signaling pathway induced oxidative stress by raising reactive oxygen species (ROS), hydrogen peroxide (H2O2), and malonaldehyde (MDA) levels. Thus, the over-release of Ca2+ and ROS disordered the normal functioning of mitochondrial-related pathways by dysregulating the expressions of mitochondria-related genes of atpef0a, sdha, and cyt b.

Conclusion

Our findings showed that low environmental concentrations of dinotefuran caused paralysis of the midge via interfering the Ca2+-ROS-mitochondria pathway. These results provided data support for assessing the potential environmental risk of dinotefuran.

Oxidative stress-modifying effects of TiO2nanoparticles with varying content of Ti3+(Ti2+) ions

Nanoparticles (NPs) with reactive oxygen species (ROS)-regulating ability have recently attracted great attention as promising agents for nanomedicine. In the present study, we have analyzed the effects of TiO2defect structure related to the presence of stoichiometric (Ti4+) and non-stoichiometric (Ti3+and Ti2+) titanium ions in the crystal lattice and TiO2NPs aggregation ability on H2O2- and tert-butyl hydroperoxide (tBOOH)-induced ROS production in L929 cells. Synthesized TiO2-A, TiO2-B, and TiO2-C NPs with varying Ti3+(Ti2+) content were characterized by x-ray powder diffraction, transmission electron microscopy, small-angle x-ray scattering, x-ray photoelectron spectroscopy, and optical spectroscopy methods. Given the role of ROS-mediated toxicity for metal oxide NPs, L929 cell viability and changes in the intracellular ROS levels in H2O2- and tBOOH-treated L929 cells incubated with TiO2NPs have been evaluated. Our research shows that both the amount of non-stoichiometric Ti3+and Ti2+ions in the crystal lattice of TiO2NPs and NPs aggregative behavior affect their catalytic activity, in particular, H2O2decomposition and, consequently, the efficiency of aggravating H2O2- and tBOOH-induced oxidative damage to L929 cells. TiO2-A NPs reveal the strongest H2O2decomposition activity aligning with their less pronounced additional effects on H2O2-treated L929 cells due to the highest amount of Ti3+(Ti2+) ions. TiO2-C NPs with smaller amounts of Ti3+ions and a tendency to aggregate in water solutions show lower antioxidant activity and, consequently, some elevation of the level of ROS in H2O2/tBOOH-treated L929 cells. Our findings suggest that synthesized TiO2NPs capable of enhancing ROS generation at concentrations non-toxic for normal cells, which should be further investigated to assess their possible application in nanomedicine as ROS-regulating pharmaceutical agents.

The Application of Nanoparticle-Based Imaging and Phototherapy for Female Reproductive Organs Diseases

Various female reproductive disorders affect millions of women worldwide and bring many troubles to women's daily life. Let alone, gynecological cancer (such as ovarian cancer and cervical cancer) is a severe threat to most women's lives. Endometriosis, pelvic inflammatory disease, and other chronic diseases-induced pain have significantly harmed women's physical and mental health. Despite recent advances in the female reproductive field, the existing challenges are still enormous such as personalization of disease, difficulty in diagnosing early cancers, antibiotic resistance in infectious diseases, etc. To confront such challenges, nanoparticle-based imaging tools and phototherapies that offer minimally invasive detection and treatment of reproductive tract-associated pathologies are indispensable and innovative. Of late, several clinical trials have also been conducted using nanoparticles for the early detection of female reproductive tract infections and cancers, targeted drug delivery, and cellular therapeutics. However, these nanoparticle trials are still nascent due to the body's delicate and complex female reproductive system. The present review comprehensively focuses on emerging nanoparticle-based imaging and phototherapies applications, which hold enormous promise for improved early diagnosis and effective treatments of various female reproductive organ diseases.

Capped Plasmonic Gold and Silver Nanoparticles with Porphyrins for Potential Use as Anticancer Agents-A Review

Photothermal therapy (PTT) and photodynamic therapy (PDT) are potential cancer treatment methods that are minimally invasive with high specificity for malignant cells. Emerging research has concentrated on the application of metal nanoparticles encapsulated in porphyrin and their derivatives to improve the efficacy of these treatments. Gold and silver nanoparticles have distinct optical properties and biocompatibility, which makes them efficient materials for PDT and PTT. Conjugation of these nanoparticles with porphyrin derivatives increases their light absorption and singlet oxygen generation that create a synergistic effect that increases phototoxicity against cancer cells. Porphyrin encapsulation with gold or silver nanoparticles improves their solubility, stability, and targeted tumor delivery. This paper provides comprehensive review on the design, functionalization, and uses of plasmonic silver and gold nanoparticles in biomedicine and how they can be conjugated with porphyrins for synergistic therapeutic effects. Furthermore, it investigates this dual-modal therapy's potential advantages and disadvantages and offers perspectives for future prospects. The possibility of developing gold, silver, and porphyrin nanotechnology-enabled biomedicine for combination therapy is also examined.

Nanozymes in cancer immunotherapy: metabolic disruption and therapeutic synergy

Over the past decade, there has been a growing emphasis on investigating the role of immunotherapy in cancer treatment. However, it faces challenges such as limited efficacy, a diminished response rate, and serious adverse effects. Nanozymes, a subset of nanomaterials, demonstrate boundless potential in cancer catalytic therapy for their tunable activity, enhanced stability, and cost-effectiveness. By selectively targeting the metabolic vulnerabilities of tumors, they can effectively intensify the destruction of tumor cells and promote the release of antigenic substances, thereby eliciting immune clearance responses and impeding tumor progression. Combined with other therapies, they synergistically enhance the efficacy of immunotherapy. Hence, a large number of metabolism-regulating nanozymes with synergistic immunotherapeutic effects have been developed. This review summarizes recent advancements in cancer immunotherapy facilitated by nanozymes, focusing on engineering nanozymes to potentiate antitumor immune responses by disturbing tumor metabolism and performing synergistic treatment. The challenges and prospects in this field are outlined. We aim to provide guidance for nanozyme-mediated immunotherapy and pave the way for achieving durable tumor eradication.

A BODIPY-Ferrocene Conjugate for the Combined Photodynamic Therapy and Chemodynamic Therapy with Improved Antitumor Efficiency

Photodynamic therapy (PDT) can destroy tumor cells by generating singlet oxygen (1O2) under light irradiation, which is limited by the hypoxia of the neoplastic tissue. Chemodynamic therapy (CDT) can produce toxic hydroxyl radical (⋅OH) to eradicate tumor cells by catalytic decomposition of endogenous hydrogen peroxide (H2O2), the therapeutic effect of which is highly dependent on the concentration of H2O2. Herein, we propose a BODIPY-ferrocene conjugate with a balanced 1O2 and ⋅OH generation capacity, which can serve as a high-efficiency antitumor agent by combining PDT and CDT. The ferrocene moieties endow the as-prepared conjugates with the ability of chemodynamic killing of tumor cells. Moreover, combined PDT/CDT therapy with improved antitumor efficiency can be realized after exposure to light irradiation. Compared with the monotherapy by PDT or CDT, the BODIPY-ferrocene conjugates can significantly increase the intracellular ROS levels of the tumor cells after light irradiation, thereby inducing the tumor cell apoptosis at low drug doses. In this way, a synergistic antitumor treatment is achieved by the combination of PDT and CDT.

A study of scarless wound healing through programmed inflammation, proliferation and maturation using a redox balancing nanogel

In the study, we have shown the efficacy of an indigenously developed redox balancing chitosan gel with impregnated citrate capped Mn3O4 nanoparticles (nanogel). Application of the nanogel on a wound of preclinical mice model shows role of various signaling molecules and growth factors, and involvement of reactive oxygen species (ROS) at every stage, namely hemostasis, inflammation, and proliferation leading to complete maturation for the scarless wound healing. While in vitro characterization of nanogel using SEM, EDAX, and optical spectroscopy reveals pH regulated redox buffering capacity, in vivo preclinical studies on Swiss albino involving IL-12, IFN-γ, and α-SMA signaling molecules and detailed histopathological investigation and angiogenesis on every stage elucidate role of redox buffering for the complete wound healing process.

Infectious and Inflammatory Microenvironment Self-Adaptive Artificial Peroxisomes with Synergetic Co-Ru Pair Centers for Programmed Diabetic Ulcer Therapy

Complex microenvironments with bacterial infection, persistent inflammation, and impaired angiogenesis are the major challenges in chronic refractory diabetic ulcers. To address this challenge, a comprehensive strategy with highly effective and integrated antimicrobial, anti-inflammatory, and accelerated angiogenesis will offer a new pathway to the rapid healing of infected diabetic ulcers. Here, inspired by the tunable reactive oxygen species (ROS) regulation properties of natural peroxisomes, this work reports the design of infectious and inflammatory microenvironments self-adaptive artificial peroxisomes with synergetic Co-Ru pair centers (APCR) for programmed diabetic ulcer therapy. Benefiting from the synergistic Co and Ru atoms, the APCR can simultaneously achieve ROS production and metabolic inhibition for bacterial sterilization in the infectious microenvironment. After disinfection, the APCR can also eliminate ROS to alleviate oxidative stress in the inflammatory microenvironment and promote wound regeneration. The data demonstrate that the APCR combines highly effective antibacterial, anti-inflammatory, and provascular regeneration capabilities, making it an efficient and safe nanomedicine for treating infectious and inflammatory diabetic foot ulcers via a programmed microenvironment self-adaptive treatment pathway. This work expects that synthesizing artificial peroxisomes with microenvironments self-adaptive and bifunctional enzyme-like ROS regulation properties will provide a promising path to construct ROS catalytic materials for treating complex diabetic ulcers, trauma, or other infection-caused diseases.

A Stimulus-Responsive Ternary Heterojunction Boosting Oxidative Stress, Cuproptosis for Melanoma Therapy

Cuproptosis, a recently discovered copper-dependent cell death, presents significant potential for the development of copper-based nanoparticles to induce cuproptosis in cancer therapy. Herein, a unique ternary heterojunction, denoted as HACT, composed of core-shell Au@Cu2O nanocubes with surface-deposited Titanium Dioxide quantum dots and modified with hyaluronic acid is introduced. Compared to core-shell AC NCs, the TiO2/Au@Cu2O exhibits improved energy structure optimization, successfully separating electron-hole pairs for redox use. This optimization results in a more rapid generation of singlet oxygen and hydroxyl radicals triggering oxidative stress under ultrasound radiation. Furthermore, the HACT NCs initiate cuproptosis by Fenton-like reaction and acidic environment, leading to the sequential release of cupric and cuprous ions. This accumulation of copper induces the aggregation of lipoylated proteins and reduces iron-sulfur proteins, ultimately initiating cuproptosis. More importantly, HACT NCs show a tendency to selectively target cancer cells, thereby granting them a degree of biosecurity. This report introduces a ternary heterojunction capable of triggering both cuproptosis and oxidative stress-related combination therapy in a stimulus-responsive manner. It can energize efforts to develop effective melanoma treatment strategies using Cu-based nanoparticles through rational design.

Gold Nanodots-Anchored Cobalt Ferrite Nanoflowers as Versatile Tumor Microenvironment Modulators for Reinforced Redox Dyshomeostasis

Given that tumor microenvironment (TME) exerts adverse impact on the therapeutic response and clinical outcome, robust TME modulators may significantly improve the curative effect and increase survival benefits of cancer patients. Here, Au nanodots-anchored CoFe2O4 nanoflowers with PEGylation (CFAP) are developed to respond to TME cues, aiming to exacerbate redox dyshomeostasis for efficacious antineoplastic therapy under ultrasound (US) irradiation. After uptake by tumor cells, CFAP with glucose oxidase (GOx)-like activity can facilitate glucose depletion and promote the production of H2O2. Multivalent elements of Co(II)/Co(III) and Fe(II)/Fe(III) in CFAP display strong Fenton-like activity for·OH production from H2O2. On the other hand, energy band structure CFAP is superior for US-actuated 1O2 generation, relying on the enhanced separation and retarded recombination of e-/h+ pairs. In addition, catalase-mimic CFAP can react with cytosolic H2O2 to generate molecular oxygen, which may increase the product yields from O2-consuming reactions, such as glucose oxidation and sonosensitization processes. Besides the massive production of reactive oxygen species, CFAP is also capable of exhausting glutathione to devastate intracellular redox balance. Severe immunogenic cell death and effective inhibition of solid tumor by CFAP demonstrates the clinical potency of such heterogeneous structure and may inspire more relevant designs for disease therapy.