Brain metastasis and primary glioblastoma multiforme represent the most common and lethal malignant brain tumors.Its median survival time is typically less than a year after diagnosis.One of the major challenges in tr...Brain metastasis and primary glioblastoma multiforme represent the most common and lethal malignant brain tumors.Its median survival time is typically less than a year after diagnosis.One of the major challenges in treating these cancers is the efficiency of the transport of drugs to the central nervous system.The blood-brain barrier is cooperating with advanced stages of malignancy.The blood-brain barrier poses a significant challenge to delivering systemic medications to brain tumors.Nanodrug delivery systems have emerged as promising tools for effectively crossing this barrier.Additionally,the development of smart nanoparticles brings new hope for cancer diagnosis and treatment.These nanoparticles improve drug delivery efficiency,allowing for the creation of targeted and stimuli-responsive delivery methods.This review highlights recent advancements in nanoparticle and smart nanoparticle technologies for brain cancer treatment,exploring the range of nanoparticles under development,their applications,targeting strategies,and the latest progress in enhancing transport across the blood-brain barrier.It also addresses the ongoing challenges and potential benefits of these innovative approaches.展开更多
Mesenchymal stromal cell transplantation is an effective and promising approach for treating various systemic and diffuse diseases.However,the biological characteristics of transplanted mesenchymal stromal cells in hu...Mesenchymal stromal cell transplantation is an effective and promising approach for treating various systemic and diffuse diseases.However,the biological characteristics of transplanted mesenchymal stromal cells in humans remain unclear,including cell viability,distribution,migration,and fate.Conventional cell tracing methods cannot be used in the clinic.The use of superparamagnetic iron oxide nanoparticles as contrast agents allows for the observation of transplanted cells using magnetic resonance imaging.In 2016,the National Medical Products Administration of China approved a new superparamagnetic iron oxide nanoparticle,Ruicun,for use as a contrast agent in clinical trials.In the present study,an acute hemi-transection spinal cord injury model was established in beagle dogs.The injury was then treated by transplantation of Ruicun-labeled mesenchymal stromal cells.The results indicated that Ruicunlabeled mesenchymal stromal cells repaired damaged spinal cord fibers and partially restored neurological function in animals with acute spinal cord injury.T2*-weighted imaging revealed low signal areas on both sides of the injured spinal cord.The results of quantitative susceptibility mapping with ultrashort echo time sequences indicated that Ruicun-labeled mesenchymal stromal cells persisted stably within the injured spinal cord for over 4 weeks.These findings suggest that magnetic resonance imaging has the potential to effectively track the migration of Ruicun-labeled mesenchymal stromal cells and assess their ability to repair spinal cord injury.展开更多
We prepared Co_(x)Pt_(100-x)(x=40,45,50,55,60)nanoparticles by the sol-gel method.The phase composition and crystal structure,morphology and microstructure,and magnetic properties of the samples were characterized and...We prepared Co_(x)Pt_(100-x)(x=40,45,50,55,60)nanoparticles by the sol-gel method.The phase composition and crystal structure,morphology and microstructure,and magnetic properties of the samples were characterized and tested using X-ray diffraction(XRD),transmission electron microscopy(TEM),and vibrating sample magnetometer(VSM),respectively.The results demonstrate that the coercivity of CoPt nanoparticles can be effectively controlled by adjusting the atomic ratio of Co and Pt in the samples.Among the compositions studied,the Co_(45)Pt_(55)sample synthesized by the sol-gel method exhibits smaller grain size and a coercivity as high as 6.65×10^(5) A/m is achieved.The morphology and microstructure of the nanoparticles were analyzed by TEM images,indicating that a slight excess of Pt can effectively enhance the coercivity of CoPt nanoparticles.展开更多
Improving device efficiency is fundamental for advancing energy harvesting technology,particularly in systems designed to convert light energy into electrical output.In our previous studies,we developed a basic struct...Improving device efficiency is fundamental for advancing energy harvesting technology,particularly in systems designed to convert light energy into electrical output.In our previous studies,we developed a basic structure light pressure electric generator(Basic-LPEG),which utilized a layered configuration of Ag/Pb(Zr,Ti)O_(3)(PZT)/Pt/GaAs to generate electricity based on light-induced pressure on the PZT.In this study,we sought to enhance the performance of this Basic-LPEG by introducing Ag nanoparticles/graphene oxide(AgNPs/GO)composite units(NP-LPEG),creating upgraded harvesting device.Specifically,by depositing the AgNPs/GO units twice onto the Basic-LPEG,we observed an increase in output voltage and current from 241 mV and 3.1μA to 310 mV and 9.3μA,respectively,under a solar simulator.The increase in electrical output directly correlated with the intensity of the light pressure impacting the PZT,as well as matched the Raman measurements,finite-difference time-domain simulations,and COMSOL Multiphysics Simulation.Experimental data revealed that the enhancement in electrical output was proportional to the number of hot spots generated between Ag nanoparticles,where the electric field experienced substantial amplification.These results underline the effectiveness of AgNPs/GO units in boosting the light-induced electric generation capacity,thereby providing a promising pathway for high-efficiency energy harvesting devices.展开更多
The surge in environmental pollution in recent years driven by numerous pollutants has necessitated the search for efficient removal methods.Phytoremediation is an eco-friendly technique that provides multiple benefit...The surge in environmental pollution in recent years driven by numerous pollutants has necessitated the search for efficient removal methods.Phytoremediation is an eco-friendly technique that provides multiple benefits over conventional methods of removing contaminants.Despite the numerous benefits of this technique,it has certain limitations that can be addressed by incorporating nanoparticles to improve its effectiveness.This review paper aims to explore the impact of heavy metal pollution on plants and human health.It highlights the role and mechanism of nanoparticles in enhancing phytoremediation,their application in the detection of heavy metals,and the strategies for the safe disposal of phytoremediation biomass.Biosynthesized nanoparticles are eco-friendly and non-toxic,with applications in biomedical and environmental fields.Nanoparticles can be used in the form of nano biosensors like smartphone-operated wireless sensors made from Cinnamomum camphora,enabling efficient detection of heavy metal ions.According to the studies,nanoparticles remove 80%–97%of heavy metals by various methods like reduction,precipitation,adsorption,etc.The phytoremediation biomass disposal can be done by heat treatment,phytomining,and microbial treatment with some modifications to further enhance their results.Phytoremediation is an environmentally friendly technique but requires further research and integration with biomass energy production to overcome scalability challenges and ensure safe biomass disposal.展开更多
Preeclampsia(PE)poses a significant threat to maternal and fetal health,characterized by hypertension during pregnancy.This study investigates a promising approach to combat PE utilizing nanotechnology for the targete...Preeclampsia(PE)poses a significant threat to maternal and fetal health,characterized by hypertension during pregnancy.This study investigates a promising approach to combat PE utilizing nanotechnology for the targeted delivery of short-chain fatty acids.By leveraging a sol-gel method and chemical deposition,cerium oxide-coated mesoporous silica nanoparticles loaded with sodium butyrate(CeO_(2)@MSN@SB)were synthesized.The innovative strategy focuses on modulating gut microbiota and JunB proto-oncogene(JUNB)gene expression to induce macrophage M2 polarization and facilitate vascular remodeling.Evaluation in PE mouse models revealed that CeO_(2)@MSN@SB effectively improved blood pressure,urinary protein levels,placental function,and gut microbiota composition.Furthermore,the nanoparticles exhibited the ability to regulate key genes related to angiogenesis and inflammation,notably JUNB,leading to enhanced macrophage M2 polarization,trophoblast functionality,and vascular restructuring.These findings highlight that the application of nanotechnology holds potential to advance PE prevention and therapy.展开更多
Developing biomass platform compounds into high value-added chemicals is a key step in renewable resource utilization.Herein,we report porous carbon-supported Ni-ZnO nanoparticles catalyst(Ni-ZnO/AC)synthesized via lo...Developing biomass platform compounds into high value-added chemicals is a key step in renewable resource utilization.Herein,we report porous carbon-supported Ni-ZnO nanoparticles catalyst(Ni-ZnO/AC)synthesized via low-temperature coprecipitation,exhibiting excellent performance for the selective hydrogenation of 5-hydroxymethylfurfural(HMF).A linear correlation is first observed between solvent polarity(E_(T)(30))and product selectivity within both polar aprotic and protic solvent classes,suggesting that solvent properties play a vital role in directing reaction pathways.Among these,1,4-dioxane(aprotic)favors the formation of 2,5-bis(hydroxymethyl)furan(BHMF)with 97.5%selectivity,while isopropanol(iPrOH,protic)promotes 2,5-dimethylfuran production with up to 99.5%selectivity.Mechanistic investigations further reveal that beyond polarity,proton-donating ability is critical in facilitating hydrodeoxygenation.iPrOH enables a hydrogen shuttle mechanism where protons assist in hydroxyl group removal,lowering the activation barrier.In contrast,1,4-dioxane,lacking hydrogen bond donors,stabilizes BHMF and hinders further conversion.Density functional theory calculations confirm a lower activation energy in iPrOH(0.60 eV)compared to 1,4-dioxane(1.07 eV).This work offers mechanistic insights and a practical strategy for solvent-mediated control of product selectivity in biomass hydrogenation,highlighting the decisive role of solvent-catalyst-substrate interactions.展开更多
Functional neurological recovery remains the primary objective when treating ischemic stroke.However,current therapeutic approaches often fall short of achieving optimal outcomes.One of the most significant challenges...Functional neurological recovery remains the primary objective when treating ischemic stroke.However,current therapeutic approaches often fall short of achieving optimal outcomes.One of the most significant challenges in stroke treatment is the effective delivery of neuroprotective agents across the blood–brain barrier to ischemic regions within the brain.The blood–brain barrier,while essential for protecting the brain from harmful substances,also restricts the passage of many therapeutic compounds,thus limiting their efficacy.In this review,we summarizes the emerging role of nanoparticle-based therapies for the treatment of ischemic stroke and investigate their potential to revolutionize drug delivery,enhance neuroprotection,and promote functional recovery.Recent advancements in nanotechnology have led to the development of engineered nanoparticles specifically designed to overcome the blood–brain barrier,thus enabling the targeted delivery of therapeutic agents directly to the affected brain areas.Preclinical studies have demonstrated the remarkable potential of nanoparticle-based therapies to activate key neuroprotective pathways,such as the phosphoinositide 3-kinase/protein kinase B/c AMP response element-binding protein signaling cascade,which is crucial for neuronal survival,synaptic plasticity,and post-stroke recovery.By modulating these pathways,nanoparticles could mitigate neuronal damage,reduce inflammation,and promote tissue repair.Furthermore,nanoparticles offer a unique advantage by enabling multimodal therapeutic strategies that simultaneously target multiple pathological mechanisms of ischemic stroke,including oxidative stress,neuroinflammation,and apoptosis.This multifaceted approach enhances the overall efficacy of treatment,addressing the complex and interconnected processes that contribute to stroke-related brain injury.Surface modifications,such as functionalization with specific ligands or targeting molecules,further improve the precision of drug delivery,enhance targeting specificity,and prolong systemic circulation,thereby optimizing therapeutic outcomes.Nanoparticlebased therapeutics represent a paradigm shift for the management of stroke and provide a promising avenue for reducing post-stroke disability and improving the outcomes of long-term rehabilitation.By combining targeted drug delivery with the ability to modulate critical neuroprotective pathways,nanoparticles hold the potential to transform the treatment landscape for ischemic stroke.However,while preclinical data are highly encouraging,significant challenges remain in translating these advancements into clinical practice.Further research is needed to refine nanoparticle designs,optimize their safety profiles,and ensure their scalability for widespread application.Rigorous clinical trials are essential to validate their efficacy,assess long-term biocompatibility,and address potential off-target effects.The integration of interdisciplinary approaches,combining insights from nanotechnology,neuroscience,and pharmacology,will be critical if we are to overcome these challenges.Ultimately,nanoparticle-based therapies offer a foundation for innovative,precision-based treatments that could significantly improve outcomes for stroke patients,thus paving the way for a new era in stroke care and neurological rehabilitation.展开更多
Fe reducing bacteria(FRB),through extracellular electron transfer(EET)pathway,can reduce Fe(III)nanoparticles,thereby affecting the migration,transformation,and degradation of pollutants.However,the interaction of Fe(...Fe reducing bacteria(FRB),through extracellular electron transfer(EET)pathway,can reduce Fe(III)nanoparticles,thereby affecting the migration,transformation,and degradation of pollutants.However,the interaction of Fe(III)nanoparticles with the most commonly identified FRB,Geobacter sulfurreducens PCA,remains poorly understood.Herein,we demonstrated that the synergistic role of outer membrane proteins and periplasmic proteins in the EET process for-Fe_(2)O_(3),Fe3O4,and𝛽α-FeOOH nanoparticles by construction of multiple gene knockout strain.oxpG(involved in the type II secretion system)and omcST(outer membrane c-type cytochrome)medi-ated pathways accounted for approximately 67%of the total reduction of𝛼α-Fe_(2)O_(3) nanoparticles.The residual reduction of𝛼α-Fe_(2)O_(3) nanoparticles in∆oxpG-omcST strain was likely caused by redox-active substances in cell supernatant.Conversely,the reduction of dissolved Fe(III)was almost unaffected in∆oxpG-omcST strain at the same concentration.However,at high dissolved Fe(III)concentration,the reduction significantly decreased due to the formation of Fe(III)nanoparticles,suggesting that this EET process is specific to Fe(III)nanoparticles.Overall,our study provided a more comprehensive understanding for the EET pathways between G.sulfurreducens PCA and different Fe(III)species,enriching our knowledge on the role of microorganisms in iron biogeochemical cycles and remediation strategies of pollutants.展开更多
Repolarizing tumor-associated macrophages(TAMs)toward the proinflammatory M1 phenotype represents a promising strategy to reverse the immunosuppressive tumor microenvironment(TME)and enhance antitumor immunotherapy.Re...Repolarizing tumor-associated macrophages(TAMs)toward the proinflammatory M1 phenotype represents a promising strategy to reverse the immunosuppressive tumor microenvironment(TME)and enhance antitumor immunotherapy.Recent studies have demonstrated that exogenous electrical stimulation can effectively repolarize TAMs toward the M1 phenotype.However,conventional electrical stimulation methods,relying on invasive implanted electrodes,are restricted to targeting localized tumor regions and pose inherent risks to patients.Notably,biological neural networks,distributed systems of interconnected neurons,can naturally permeate tissues and orchestrate cellular activities with high spatial efficiency.Inspired by this natural system,we developed a global in situ electric field network using piezoelectric BaTiO_(3)nanoparticles.Upon ultrasound stimulation,the nanoparticles generate a wireless electric field throughout the TME.In addtion,their nanoscale size enables them to function as synthetic“neurons”,allowing for uniform penetration throughout the tumor tissue and inducing significant repolarization of TAMs via the Ca^(2+)influx-activated nuclear factor-kappa B(NF-κB)signaling pathway.The repolarized M1 TAMs restore anti-tumor immunostimulatory functions and secrete key proinflammatory cytokines(e.g.,tumor necrosis factor-alpha(TNF-α)and interleukin-1 beta(IL-1β)),which enhance immunostimulation within the TME and directly contribute to tumor cell elimination.Remarkably,this strategy achieved robust in vivo tumor growth inhibition with excellent biosafety in a 4T1 breast tumor model.Overall,this work establishes a non-invasive,wireless electric field platform capable of globally repolarizing TAMs,offering a safe and efficient strategy to advance cancer immunotherapy and accelerate the clinical translation of bioelectronic therapies.展开更多
Ultrasmall superparamagnetic iron oxide nanoparticles(usSPIONs)are promising alternatives to gadolinium‐based contrast agents for positive contrast enhancement in magnetic resonance imaging(MRI).Unlike larger SPIONs ...Ultrasmall superparamagnetic iron oxide nanoparticles(usSPIONs)are promising alternatives to gadolinium‐based contrast agents for positive contrast enhancement in magnetic resonance imaging(MRI).Unlike larger SPIONs that primarily function as T2/T2*negative contrast agents,usSPIONs with core diameters below 5 nm can effectively shorten T1 relaxation times,producing bright signals in T1‐weighted images.This distinct behavior stems from their unique magnetic properties,including single‐domain configurations,surface spin canting,and rapid Néel relaxation dynamics,which are particularly enhanced at low magnetic field strengths.The biocompatibility of iron oxide,efficient renal clearance pathways,and versatility for surface functionalization offer potential advantages over gadolinium‐based agents,especially regarding safety concerns related to nephrogenic systemic fibrosis and gadolinium deposition.These nanoparticles show particular promise for applications in lowfield MRI,vascular imaging,targeted molecular imaging,and theranostic platforms.Although challenges remain in optimizing synthesis methods for consistent production of monodisperse usSPIONs with tailored surface chemistry,ongoing research continues to advance their potential for clinical translation.This review explores the mechanisms,synthesis approaches,applications,and future perspectives of usSPIONs as positive contrast agents in MRI.展开更多
Peri-implant mucositis is the mucosal inflammatory lesion around implants that does not result in the loss of the peri-implant bone that supports them.Furthermore,Peri-implantitis(PI),a medical condition affecting the...Peri-implant mucositis is the mucosal inflammatory lesion around implants that does not result in the loss of the peri-implant bone that supports them.Furthermore,Peri-implantitis(PI),a medical condition affecting the tissues surrounding dental implants,is characterized by inflammation and a progressive loss of supporting bone.Of the several types of Nanoparticles(NPs),a lot of research has been done on the effects of Metal NPs(MNPs)-such as those made of silver,zinc,and copper-and non-MNPs-such as those made of Graphene Oxide(GO),Carbon-based NPs(CNPs),and Chitosan(CS)NPs-on peri-implant microorganisms.These NPs serve as antibacterial and anti-inflammatory agents and cover dental implants.Furthermore,Peri-implant Disease(PID)and many others in the oral and dental domains may be effectively treated using Green Synthesis(GS)NPs enabled by various biological sources.Compared to chemical and physical processes,GS offers several benefits,including non-toxicity,pollution-free production,environmental friendliness,cost-effectiveness,and sustainability.Hence,the significance of GS NPs,both MNPs and non-MNPs,was first explored in this work.Using eco-friendly methods,we then reviewed the PID-related effects of various MNPs and non-MNPs synthesized.NPs,both MNPs and non-MNPs,have great potential as a future therapy for PI,and the environmentally friendly manufacturing process may play a significant role in this development.Consequently,we have looked into the benefits and drawbacks of this treatment method in terms of clinical practice in our study.Research from reputable sources,such as PubMed and Google Scholar,was used to compile the papers included in the review article.Researchers may make progress in producing MNPs and non-MNPs NPs for treating PI by adopting GS.展开更多
Directly occluding polymer nanoparticles into growing host crystals provides a versatile pathway for synthe sizing polymer-inorganic composite crystals,where vip nanoparticles are distributed within the crystal matr...Directly occluding polymer nanoparticles into growing host crystals provides a versatile pathway for synthe sizing polymer-inorganic composite crystals,where vip nanoparticles are distributed within the crystal matrix.However,systematically controlling the extent of nanoparticle occlusion within a host crystal remains a significant challenge.In this study,we employ a one-step,soap-free emulsion polymerization method to synthesize polyethyleneimine-functionalized poly(tert-butyl methacrylate)(PtBMA/PEI)nanoparticles.These cationic nanoparticles are subsequently modified using formaldehyde to systematically tune the content of surface amine group via the Eschweiler-Clarke reaction.This approach yields a series of model nanoparticles that allow us to investigate how surface chemistry influences the extent of nanoparticle occlusion within calcite crystals.Our findings reveal that the extent of nanoparticle occlusion within calcite crystals is proportional to the surface amine group content.This study offers a new design rule for creating composite crystals with tailored compositions through a nanoparticle occlusion strategy.展开更多
The optically levitated mechanical system in vacuum is a powerful platform in physics.It has been displaying more extensive application prospects.This paper presents an experimental study of optical levitation,identif...The optically levitated mechanical system in vacuum is a powerful platform in physics.It has been displaying more extensive application prospects.This paper presents an experimental study of optical levitation,identification,motion measurement,and assembly of two-species photoluminescence nanoparticles.A laser trapping array simultaneously levitates nitrogen-vacancy(NV)nanodiamonds and Yb^(3+)/Er^(3+):NaYF_(4)nanoparticles.The species of each nanoparticle can be individually identified by measuring the photoluminescence spectrum.We choose the single NV nanodiamond and Yb^(3+)/Er^(3+):NaYF_(4)nanoparticle and assemble them into a Janus composite nanoparticle,which integrates the merits of the two components.This work demonstrates the potential advantages of a hybrid optically levitated system.It provides a practicable scheme for the study of macroscopic quantum phenomena and precision measurement,thanks to the spin manipulation or spin-mechanical coupling of an NV diamond and by simultaneously implementing laser refrigeration to the Yb^(3+)/Er^(3+):NaYF_(4)nanoparticle in an optically levitated composite nanoparticle.展开更多
Photodynamic therapy(PDT)has been established as one of the most promising novel cancer therapies with fewer side-effects and enhanced efficacy compared to the currently available conventional treatments.However,its a...Photodynamic therapy(PDT)has been established as one of the most promising novel cancer therapies with fewer side-effects and enhanced efficacy compared to the currently available conventional treatments.However,its application has been hindered by the limitations that photosensitizers(PS)have.The combination of PS with metallic nanoparticles like platinum nanoparticles(PtNPs),can help to overcome these intrinsic drawbacks.In this work,the combination of PtNPs and the natural photosensitizer riboflavin(RF)is proposed.PtNPs are synthesized using RF(Pt@RF)as reducing and stabilizing agent in a one-step method,obtaining nanoparticles with mesoporous structure for UV triggered PDT.In view of possible future UV irradiation treatments,the degradation products of RF,ribitol(RB)and lumichrome(LC),this last being a photosensitizing byproduct,are also employed for the synthesis of porous PtNPs,obtaining Pt@LC and Pt@RB.When administered in vitro to lung cancer cells,all the samples elicit a strong decrease of cell viability and a decrease of intracellular ATP levels.The antitumoral effect of both Pt@RF and Pt@LC is triggered by UV-A irradiation.This antitumoral activity is caused by the induction of oxidative stress,shown in our study by the decrease in intracellular glutathione and increased expression of antioxidant enzymes.展开更多
Practical application of carvacrol in different fields including foods and biopesticides has been limited due to its instability and water insolubility.In this work,carvacrol encapsulated Pickering emulsion is develop...Practical application of carvacrol in different fields including foods and biopesticides has been limited due to its instability and water insolubility.In this work,carvacrol encapsulated Pickering emulsion is developed by using polymeric Janus nanoparticles as the stabilizer.To achieve this,dumbbell-shaped polymeric nanoparticles composed of two spheres of shellac and polylactic acid(PLA)are firstly prepared via co-precipitation in a rotating packed bed reactor,followed by grafting of chitooligosaccharides(COS)onto shellac to synthesis amphiphilic Janus nanoparticles(PLA/shellac-COS).Pickering emulsions with typical oil-in-water,bi-continuous structure and water-in-oil characteristics are produced by configuring carvacrol emulsions with different oil-to-water ratios.The stability of emulsions with 5%carvacrol content stabilized by 0.5% PLA/shellac-COS nanoparticles were more stable when compared to those prepared by shellac nanoparticles and PLA/shellac nanoparticles.After stored for one month,the carvacrol encapsulated Pickering emulsions maintained a high zeta potential of-43.8 mV,with no significant changes in particle size.These preliminary studies illustrated that polymeric Janus nanoparticles synthesized by co-precipitation in a rotating packed bed are promising particles for Pickering emulsions and related work in the future.展开更多
Synthesis of zinc oxide nanoparticles(ZnO-NPs)via green method is an outstanding alternative to conventional/regular methods;however,the safety or toxicity of the biosynthesized ZnO-NPs in vivo is not fully explored.T...Synthesis of zinc oxide nanoparticles(ZnO-NPs)via green method is an outstanding alternative to conventional/regular methods;however,the safety or toxicity of the biosynthesized ZnO-NPs in vivo is not fully explored.This study was conducted to evaluate the protective efficiency of cinnamaldehyde-loaded chitosan nanoparticles(Cin@CSNPs)against oxidative damage and genotoxicity of ZnO-NPs in mice.ZnO-NPs were biosynthesized using the extract of fresh leaves of Mentha pulegium L.Cin was extracted from cinnamon essential oil,and was loaded into chitosan nanoparticle(Cin@CSNPs).Both ZnO-NPs,Cin@CSNPs and CSNPs were characterized.The in vitro release of Cin@CSNPs was determined.In the biological study,6 groups of male BALB/c mice were treated by gavage for 3 weeks as follows,control group,the group received ZnO-NPs(25 mg/kg b.w),the groups received Cin@CSNPs at low dose(50 mg/kg b.w)or high dose(100 mg/kg b.w),and the groups received ZnO-NPs plus Cin@CSNPs at the 2 tested doses.Blood and tissue samples were collected for different biochemical,genetical and histological studies.The particle size of ZnO-NPs,CSNPs,and Cin@CSNPs were(20.78±2.60),(170.0±3.7),and(218.23±2.90)nm,andξ-potential were(32.7±4.6),(8.32±0.27)and(4.80±0.21)mV,respectively.ZnO-NPs disturbed the biochemical and oxidative stress indices,AFP,CEA,TNF-α,chromosomal aberrations in somatic and germ cells,and sperm abnormality along with severe pathological changes in the hepatic,renal,and testicular tissues.Cin@CSNPs improved significantly all the parameters tested and the histological picture in a dose-dependent.Therefore,the biosynthesized ZnO-NPs exhibit oxidative damage and genotoxicity,and Cin@CSNPs have potential protective effects against the risks of ZnO-NPs and may be a promising tool to overcome the challenges of using Cin in food and pharmaceuticals applications.展开更多
Primary biliary cholangitis(PBC)is an autoimmune disease characterized by the selective destruction of intrahepatic small bile ducts,primarily by infiltrating lymphocytes,and has limited therapeutic options.A growing ...Primary biliary cholangitis(PBC)is an autoimmune disease characterized by the selective destruction of intrahepatic small bile ducts,primarily by infiltrating lymphocytes,and has limited therapeutic options.A growing body of evidence suggests that nanoparticles encapsulating rapamycin(ImmTOR)can suppress autoreactive lymphocytes and reduce inflammatory cytokine levels in various autoimmune diseases.In a recent study,Yang et al investigated the therapeutic effects of ImmTOR in a mouse model of PBC.ImmTOR treatment reduced the expression and number of CD4+T cells,CD8+T cells,and B cells isolated from the liver and spleen,improved liver inflammation and enzyme levels,and was associated with a concomitant decrease in anti-mitochondrial antibody levels.In this editorial,we highlight the significance of these findings,focusing on the potential mechanisms by which ImmTOR suppresses hepatic autoreactive T cells and reduces anti-mitochondrial antibody levels,ultimately improving liver pa-thology,through pathways such as mammalian target of rapamycin inhibition and autophagy restoration.We also offer a perspective on future research di-rections for PBC in both animal models and in vitro studies.展开更多
Ultrafine metal nanoparticles are crucial for various applications,such as energy storage,catalysis,electronics,and biomedicine,owing to their high surfaceto-volume ratio and unique electronic properties.However,conve...Ultrafine metal nanoparticles are crucial for various applications,such as energy storage,catalysis,electronics,and biomedicine,owing to their high surfaceto-volume ratio and unique electronic properties.However,conventional nanoparticle synthesis methods often face challenges like irregular shapes and agglomeration,leading to compromised functionality.To address these challenges,this paper introduces a novel,rapid,high-temperature thermal radiation heating for the ultrafast synthesis and dispersion of metal nanoparticles.Utilizing the heating properties of carbon materials,the direct Joule heating generated by them rises to 1800-2000 K within~200 ms,followed by cooling to room temperature at a rate of 2×10^(3)K s^(-1).展开更多
文摘Brain metastasis and primary glioblastoma multiforme represent the most common and lethal malignant brain tumors.Its median survival time is typically less than a year after diagnosis.One of the major challenges in treating these cancers is the efficiency of the transport of drugs to the central nervous system.The blood-brain barrier is cooperating with advanced stages of malignancy.The blood-brain barrier poses a significant challenge to delivering systemic medications to brain tumors.Nanodrug delivery systems have emerged as promising tools for effectively crossing this barrier.Additionally,the development of smart nanoparticles brings new hope for cancer diagnosis and treatment.These nanoparticles improve drug delivery efficiency,allowing for the creation of targeted and stimuli-responsive delivery methods.This review highlights recent advancements in nanoparticle and smart nanoparticle technologies for brain cancer treatment,exploring the range of nanoparticles under development,their applications,targeting strategies,and the latest progress in enhancing transport across the blood-brain barrier.It also addresses the ongoing challenges and potential benefits of these innovative approaches.
基金supported by the National Key R&D Program of China,Nos.2017YFA0104302(to NG and XM)and 2017YFA0104304(to BW and ZZ)
文摘Mesenchymal stromal cell transplantation is an effective and promising approach for treating various systemic and diffuse diseases.However,the biological characteristics of transplanted mesenchymal stromal cells in humans remain unclear,including cell viability,distribution,migration,and fate.Conventional cell tracing methods cannot be used in the clinic.The use of superparamagnetic iron oxide nanoparticles as contrast agents allows for the observation of transplanted cells using magnetic resonance imaging.In 2016,the National Medical Products Administration of China approved a new superparamagnetic iron oxide nanoparticle,Ruicun,for use as a contrast agent in clinical trials.In the present study,an acute hemi-transection spinal cord injury model was established in beagle dogs.The injury was then treated by transplantation of Ruicun-labeled mesenchymal stromal cells.The results indicated that Ruicunlabeled mesenchymal stromal cells repaired damaged spinal cord fibers and partially restored neurological function in animals with acute spinal cord injury.T2*-weighted imaging revealed low signal areas on both sides of the injured spinal cord.The results of quantitative susceptibility mapping with ultrashort echo time sequences indicated that Ruicun-labeled mesenchymal stromal cells persisted stably within the injured spinal cord for over 4 weeks.These findings suggest that magnetic resonance imaging has the potential to effectively track the migration of Ruicun-labeled mesenchymal stromal cells and assess their ability to repair spinal cord injury.
基金Funded by the National Natural Science Foundation of China(No.52371169)。
文摘We prepared Co_(x)Pt_(100-x)(x=40,45,50,55,60)nanoparticles by the sol-gel method.The phase composition and crystal structure,morphology and microstructure,and magnetic properties of the samples were characterized and tested using X-ray diffraction(XRD),transmission electron microscopy(TEM),and vibrating sample magnetometer(VSM),respectively.The results demonstrate that the coercivity of CoPt nanoparticles can be effectively controlled by adjusting the atomic ratio of Co and Pt in the samples.Among the compositions studied,the Co_(45)Pt_(55)sample synthesized by the sol-gel method exhibits smaller grain size and a coercivity as high as 6.65×10^(5) A/m is achieved.The morphology and microstructure of the nanoparticles were analyzed by TEM images,indicating that a slight excess of Pt can effectively enhance the coercivity of CoPt nanoparticles.
基金supported by Korea Evaluation Institute of Industrial Technology(KEIT)grant funded by the Korea Government(MOTIE)(RS-2022-00154720,Technology Innovation Program Development of next-generation power semiconductor based on Si-on-SiC structure)the National Research Foundation of Korea(NRF)by the Korea government(RS-2023-NR076826)Global-Learning&Academic Research Institution for Master's·PhD students,and Postdocs(LAMP)Program of the National Research Foundation of Korea(NRF)by the Ministry of Education(No.RS-2024-00443714).
文摘Improving device efficiency is fundamental for advancing energy harvesting technology,particularly in systems designed to convert light energy into electrical output.In our previous studies,we developed a basic structure light pressure electric generator(Basic-LPEG),which utilized a layered configuration of Ag/Pb(Zr,Ti)O_(3)(PZT)/Pt/GaAs to generate electricity based on light-induced pressure on the PZT.In this study,we sought to enhance the performance of this Basic-LPEG by introducing Ag nanoparticles/graphene oxide(AgNPs/GO)composite units(NP-LPEG),creating upgraded harvesting device.Specifically,by depositing the AgNPs/GO units twice onto the Basic-LPEG,we observed an increase in output voltage and current from 241 mV and 3.1μA to 310 mV and 9.3μA,respectively,under a solar simulator.The increase in electrical output directly correlated with the intensity of the light pressure impacting the PZT,as well as matched the Raman measurements,finite-difference time-domain simulations,and COMSOL Multiphysics Simulation.Experimental data revealed that the enhancement in electrical output was proportional to the number of hot spots generated between Ag nanoparticles,where the electric field experienced substantial amplification.These results underline the effectiveness of AgNPs/GO units in boosting the light-induced electric generation capacity,thereby providing a promising pathway for high-efficiency energy harvesting devices.
文摘The surge in environmental pollution in recent years driven by numerous pollutants has necessitated the search for efficient removal methods.Phytoremediation is an eco-friendly technique that provides multiple benefits over conventional methods of removing contaminants.Despite the numerous benefits of this technique,it has certain limitations that can be addressed by incorporating nanoparticles to improve its effectiveness.This review paper aims to explore the impact of heavy metal pollution on plants and human health.It highlights the role and mechanism of nanoparticles in enhancing phytoremediation,their application in the detection of heavy metals,and the strategies for the safe disposal of phytoremediation biomass.Biosynthesized nanoparticles are eco-friendly and non-toxic,with applications in biomedical and environmental fields.Nanoparticles can be used in the form of nano biosensors like smartphone-operated wireless sensors made from Cinnamomum camphora,enabling efficient detection of heavy metal ions.According to the studies,nanoparticles remove 80%–97%of heavy metals by various methods like reduction,precipitation,adsorption,etc.The phytoremediation biomass disposal can be done by heat treatment,phytomining,and microbial treatment with some modifications to further enhance their results.Phytoremediation is an environmentally friendly technique but requires further research and integration with biomass energy production to overcome scalability challenges and ensure safe biomass disposal.
基金supported by the 2025 National Health Commission Scientific Research Fund-Major Science and Technology Plan Project of Zhejiang Province(No:WKJ-ZJ-2533)the National Key Research and Development Program of China(No.SQ2022YFC2700013.2022YFC2704601).
文摘Preeclampsia(PE)poses a significant threat to maternal and fetal health,characterized by hypertension during pregnancy.This study investigates a promising approach to combat PE utilizing nanotechnology for the targeted delivery of short-chain fatty acids.By leveraging a sol-gel method and chemical deposition,cerium oxide-coated mesoporous silica nanoparticles loaded with sodium butyrate(CeO_(2)@MSN@SB)were synthesized.The innovative strategy focuses on modulating gut microbiota and JunB proto-oncogene(JUNB)gene expression to induce macrophage M2 polarization and facilitate vascular remodeling.Evaluation in PE mouse models revealed that CeO_(2)@MSN@SB effectively improved blood pressure,urinary protein levels,placental function,and gut microbiota composition.Furthermore,the nanoparticles exhibited the ability to regulate key genes related to angiogenesis and inflammation,notably JUNB,leading to enhanced macrophage M2 polarization,trophoblast functionality,and vascular restructuring.These findings highlight that the application of nanotechnology holds potential to advance PE prevention and therapy.
基金the National Nature Science Foundation of China for Excellent Young Scientists Fund(32222058)Fundamental Research Foundation of CAF(CAFYBB2022QB001).
文摘Developing biomass platform compounds into high value-added chemicals is a key step in renewable resource utilization.Herein,we report porous carbon-supported Ni-ZnO nanoparticles catalyst(Ni-ZnO/AC)synthesized via low-temperature coprecipitation,exhibiting excellent performance for the selective hydrogenation of 5-hydroxymethylfurfural(HMF).A linear correlation is first observed between solvent polarity(E_(T)(30))and product selectivity within both polar aprotic and protic solvent classes,suggesting that solvent properties play a vital role in directing reaction pathways.Among these,1,4-dioxane(aprotic)favors the formation of 2,5-bis(hydroxymethyl)furan(BHMF)with 97.5%selectivity,while isopropanol(iPrOH,protic)promotes 2,5-dimethylfuran production with up to 99.5%selectivity.Mechanistic investigations further reveal that beyond polarity,proton-donating ability is critical in facilitating hydrodeoxygenation.iPrOH enables a hydrogen shuttle mechanism where protons assist in hydroxyl group removal,lowering the activation barrier.In contrast,1,4-dioxane,lacking hydrogen bond donors,stabilizes BHMF and hinders further conversion.Density functional theory calculations confirm a lower activation energy in iPrOH(0.60 eV)compared to 1,4-dioxane(1.07 eV).This work offers mechanistic insights and a practical strategy for solvent-mediated control of product selectivity in biomass hydrogenation,highlighting the decisive role of solvent-catalyst-substrate interactions.
基金supported by the National Natural Science Foundations of China,Nos.82272163,82472164(both MF)。
文摘Functional neurological recovery remains the primary objective when treating ischemic stroke.However,current therapeutic approaches often fall short of achieving optimal outcomes.One of the most significant challenges in stroke treatment is the effective delivery of neuroprotective agents across the blood–brain barrier to ischemic regions within the brain.The blood–brain barrier,while essential for protecting the brain from harmful substances,also restricts the passage of many therapeutic compounds,thus limiting their efficacy.In this review,we summarizes the emerging role of nanoparticle-based therapies for the treatment of ischemic stroke and investigate their potential to revolutionize drug delivery,enhance neuroprotection,and promote functional recovery.Recent advancements in nanotechnology have led to the development of engineered nanoparticles specifically designed to overcome the blood–brain barrier,thus enabling the targeted delivery of therapeutic agents directly to the affected brain areas.Preclinical studies have demonstrated the remarkable potential of nanoparticle-based therapies to activate key neuroprotective pathways,such as the phosphoinositide 3-kinase/protein kinase B/c AMP response element-binding protein signaling cascade,which is crucial for neuronal survival,synaptic plasticity,and post-stroke recovery.By modulating these pathways,nanoparticles could mitigate neuronal damage,reduce inflammation,and promote tissue repair.Furthermore,nanoparticles offer a unique advantage by enabling multimodal therapeutic strategies that simultaneously target multiple pathological mechanisms of ischemic stroke,including oxidative stress,neuroinflammation,and apoptosis.This multifaceted approach enhances the overall efficacy of treatment,addressing the complex and interconnected processes that contribute to stroke-related brain injury.Surface modifications,such as functionalization with specific ligands or targeting molecules,further improve the precision of drug delivery,enhance targeting specificity,and prolong systemic circulation,thereby optimizing therapeutic outcomes.Nanoparticlebased therapeutics represent a paradigm shift for the management of stroke and provide a promising avenue for reducing post-stroke disability and improving the outcomes of long-term rehabilitation.By combining targeted drug delivery with the ability to modulate critical neuroprotective pathways,nanoparticles hold the potential to transform the treatment landscape for ischemic stroke.However,while preclinical data are highly encouraging,significant challenges remain in translating these advancements into clinical practice.Further research is needed to refine nanoparticle designs,optimize their safety profiles,and ensure their scalability for widespread application.Rigorous clinical trials are essential to validate their efficacy,assess long-term biocompatibility,and address potential off-target effects.The integration of interdisciplinary approaches,combining insights from nanotechnology,neuroscience,and pharmacology,will be critical if we are to overcome these challenges.Ultimately,nanoparticle-based therapies offer a foundation for innovative,precision-based treatments that could significantly improve outcomes for stroke patients,thus paving the way for a new era in stroke care and neurological rehabilitation.
基金supported by the National Key Research and Development Project(No.2020YFA0907500)the National Natural Science Foundation of China(No.22476206)+1 种基金the supports from the National Young Top-Notch Talents(No.W03070030)Youth Innovation Promotion Association of the Chinese Academy of Sciences(No.Y202011).
文摘Fe reducing bacteria(FRB),through extracellular electron transfer(EET)pathway,can reduce Fe(III)nanoparticles,thereby affecting the migration,transformation,and degradation of pollutants.However,the interaction of Fe(III)nanoparticles with the most commonly identified FRB,Geobacter sulfurreducens PCA,remains poorly understood.Herein,we demonstrated that the synergistic role of outer membrane proteins and periplasmic proteins in the EET process for-Fe_(2)O_(3),Fe3O4,and𝛽α-FeOOH nanoparticles by construction of multiple gene knockout strain.oxpG(involved in the type II secretion system)and omcST(outer membrane c-type cytochrome)medi-ated pathways accounted for approximately 67%of the total reduction of𝛼α-Fe_(2)O_(3) nanoparticles.The residual reduction of𝛼α-Fe_(2)O_(3) nanoparticles in∆oxpG-omcST strain was likely caused by redox-active substances in cell supernatant.Conversely,the reduction of dissolved Fe(III)was almost unaffected in∆oxpG-omcST strain at the same concentration.However,at high dissolved Fe(III)concentration,the reduction significantly decreased due to the formation of Fe(III)nanoparticles,suggesting that this EET process is specific to Fe(III)nanoparticles.Overall,our study provided a more comprehensive understanding for the EET pathways between G.sulfurreducens PCA and different Fe(III)species,enriching our knowledge on the role of microorganisms in iron biogeochemical cycles and remediation strategies of pollutants.
基金supported by the National Natural Science Foundation of China(Nos.52373235 and 52573322)the National Natural Science Foundation of Hubei Province of China(No.2024AFB568).
文摘Repolarizing tumor-associated macrophages(TAMs)toward the proinflammatory M1 phenotype represents a promising strategy to reverse the immunosuppressive tumor microenvironment(TME)and enhance antitumor immunotherapy.Recent studies have demonstrated that exogenous electrical stimulation can effectively repolarize TAMs toward the M1 phenotype.However,conventional electrical stimulation methods,relying on invasive implanted electrodes,are restricted to targeting localized tumor regions and pose inherent risks to patients.Notably,biological neural networks,distributed systems of interconnected neurons,can naturally permeate tissues and orchestrate cellular activities with high spatial efficiency.Inspired by this natural system,we developed a global in situ electric field network using piezoelectric BaTiO_(3)nanoparticles.Upon ultrasound stimulation,the nanoparticles generate a wireless electric field throughout the TME.In addtion,their nanoscale size enables them to function as synthetic“neurons”,allowing for uniform penetration throughout the tumor tissue and inducing significant repolarization of TAMs via the Ca^(2+)influx-activated nuclear factor-kappa B(NF-κB)signaling pathway.The repolarized M1 TAMs restore anti-tumor immunostimulatory functions and secrete key proinflammatory cytokines(e.g.,tumor necrosis factor-alpha(TNF-α)and interleukin-1 beta(IL-1β)),which enhance immunostimulation within the TME and directly contribute to tumor cell elimination.Remarkably,this strategy achieved robust in vivo tumor growth inhibition with excellent biosafety in a 4T1 breast tumor model.Overall,this work establishes a non-invasive,wireless electric field platform capable of globally repolarizing TAMs,offering a safe and efficient strategy to advance cancer immunotherapy and accelerate the clinical translation of bioelectronic therapies.
文摘Ultrasmall superparamagnetic iron oxide nanoparticles(usSPIONs)are promising alternatives to gadolinium‐based contrast agents for positive contrast enhancement in magnetic resonance imaging(MRI).Unlike larger SPIONs that primarily function as T2/T2*negative contrast agents,usSPIONs with core diameters below 5 nm can effectively shorten T1 relaxation times,producing bright signals in T1‐weighted images.This distinct behavior stems from their unique magnetic properties,including single‐domain configurations,surface spin canting,and rapid Néel relaxation dynamics,which are particularly enhanced at low magnetic field strengths.The biocompatibility of iron oxide,efficient renal clearance pathways,and versatility for surface functionalization offer potential advantages over gadolinium‐based agents,especially regarding safety concerns related to nephrogenic systemic fibrosis and gadolinium deposition.These nanoparticles show particular promise for applications in lowfield MRI,vascular imaging,targeted molecular imaging,and theranostic platforms.Although challenges remain in optimizing synthesis methods for consistent production of monodisperse usSPIONs with tailored surface chemistry,ongoing research continues to advance their potential for clinical translation.This review explores the mechanisms,synthesis approaches,applications,and future perspectives of usSPIONs as positive contrast agents in MRI.
文摘Peri-implant mucositis is the mucosal inflammatory lesion around implants that does not result in the loss of the peri-implant bone that supports them.Furthermore,Peri-implantitis(PI),a medical condition affecting the tissues surrounding dental implants,is characterized by inflammation and a progressive loss of supporting bone.Of the several types of Nanoparticles(NPs),a lot of research has been done on the effects of Metal NPs(MNPs)-such as those made of silver,zinc,and copper-and non-MNPs-such as those made of Graphene Oxide(GO),Carbon-based NPs(CNPs),and Chitosan(CS)NPs-on peri-implant microorganisms.These NPs serve as antibacterial and anti-inflammatory agents and cover dental implants.Furthermore,Peri-implant Disease(PID)and many others in the oral and dental domains may be effectively treated using Green Synthesis(GS)NPs enabled by various biological sources.Compared to chemical and physical processes,GS offers several benefits,including non-toxicity,pollution-free production,environmental friendliness,cost-effectiveness,and sustainability.Hence,the significance of GS NPs,both MNPs and non-MNPs,was first explored in this work.Using eco-friendly methods,we then reviewed the PID-related effects of various MNPs and non-MNPs synthesized.NPs,both MNPs and non-MNPs,have great potential as a future therapy for PI,and the environmentally friendly manufacturing process may play a significant role in this development.Consequently,we have looked into the benefits and drawbacks of this treatment method in terms of clinical practice in our study.Research from reputable sources,such as PubMed and Google Scholar,was used to compile the papers included in the review article.Researchers may make progress in producing MNPs and non-MNPs NPs for treating PI by adopting GS.
基金financial supports from the National Natural Science Foundation of China(Nos.22475084 and 22101100)Guangdong Basic and Applied Basic Research Foundation(Nos.2024A1515012114 and 2025A1515012931)College Students’Innovation and Entrepreneurship Training Program.
文摘Directly occluding polymer nanoparticles into growing host crystals provides a versatile pathway for synthe sizing polymer-inorganic composite crystals,where vip nanoparticles are distributed within the crystal matrix.However,systematically controlling the extent of nanoparticle occlusion within a host crystal remains a significant challenge.In this study,we employ a one-step,soap-free emulsion polymerization method to synthesize polyethyleneimine-functionalized poly(tert-butyl methacrylate)(PtBMA/PEI)nanoparticles.These cationic nanoparticles are subsequently modified using formaldehyde to systematically tune the content of surface amine group via the Eschweiler-Clarke reaction.This approach yields a series of model nanoparticles that allow us to investigate how surface chemistry influences the extent of nanoparticle occlusion within calcite crystals.Our findings reveal that the extent of nanoparticle occlusion within calcite crystals is proportional to the surface amine group content.This study offers a new design rule for creating composite crystals with tailored compositions through a nanoparticle occlusion strategy.
基金supported in part by the National Natural Science Foundation of China(Grant Nos.61975101,11234008,11361161002,and 6157-1276)。
文摘The optically levitated mechanical system in vacuum is a powerful platform in physics.It has been displaying more extensive application prospects.This paper presents an experimental study of optical levitation,identification,motion measurement,and assembly of two-species photoluminescence nanoparticles.A laser trapping array simultaneously levitates nitrogen-vacancy(NV)nanodiamonds and Yb^(3+)/Er^(3+):NaYF_(4)nanoparticles.The species of each nanoparticle can be individually identified by measuring the photoluminescence spectrum.We choose the single NV nanodiamond and Yb^(3+)/Er^(3+):NaYF_(4)nanoparticle and assemble them into a Janus composite nanoparticle,which integrates the merits of the two components.This work demonstrates the potential advantages of a hybrid optically levitated system.It provides a practicable scheme for the study of macroscopic quantum phenomena and precision measurement,thanks to the spin manipulation or spin-mechanical coupling of an NV diamond and by simultaneously implementing laser refrigeration to the Yb^(3+)/Er^(3+):NaYF_(4)nanoparticle in an optically levitated composite nanoparticle.
基金funded by the Horizon Europe Project"PERSEUS"(No.101099423)financed by the Ministry of Universities under application 33.50.460A.752by the European Union NextGenerationEU/PRTR through a contract Margarita Salas from Universidade de Vigo.
文摘Photodynamic therapy(PDT)has been established as one of the most promising novel cancer therapies with fewer side-effects and enhanced efficacy compared to the currently available conventional treatments.However,its application has been hindered by the limitations that photosensitizers(PS)have.The combination of PS with metallic nanoparticles like platinum nanoparticles(PtNPs),can help to overcome these intrinsic drawbacks.In this work,the combination of PtNPs and the natural photosensitizer riboflavin(RF)is proposed.PtNPs are synthesized using RF(Pt@RF)as reducing and stabilizing agent in a one-step method,obtaining nanoparticles with mesoporous structure for UV triggered PDT.In view of possible future UV irradiation treatments,the degradation products of RF,ribitol(RB)and lumichrome(LC),this last being a photosensitizing byproduct,are also employed for the synthesis of porous PtNPs,obtaining Pt@LC and Pt@RB.When administered in vitro to lung cancer cells,all the samples elicit a strong decrease of cell viability and a decrease of intracellular ATP levels.The antitumoral effect of both Pt@RF and Pt@LC is triggered by UV-A irradiation.This antitumoral activity is caused by the induction of oxidative stress,shown in our study by the decrease in intracellular glutathione and increased expression of antioxidant enzymes.
基金financial support from the National Natural Science Foundation of China(22278027)the Beijing Natural Science Foundation(2232013)。
文摘Practical application of carvacrol in different fields including foods and biopesticides has been limited due to its instability and water insolubility.In this work,carvacrol encapsulated Pickering emulsion is developed by using polymeric Janus nanoparticles as the stabilizer.To achieve this,dumbbell-shaped polymeric nanoparticles composed of two spheres of shellac and polylactic acid(PLA)are firstly prepared via co-precipitation in a rotating packed bed reactor,followed by grafting of chitooligosaccharides(COS)onto shellac to synthesis amphiphilic Janus nanoparticles(PLA/shellac-COS).Pickering emulsions with typical oil-in-water,bi-continuous structure and water-in-oil characteristics are produced by configuring carvacrol emulsions with different oil-to-water ratios.The stability of emulsions with 5%carvacrol content stabilized by 0.5% PLA/shellac-COS nanoparticles were more stable when compared to those prepared by shellac nanoparticles and PLA/shellac nanoparticles.After stored for one month,the carvacrol encapsulated Pickering emulsions maintained a high zeta potential of-43.8 mV,with no significant changes in particle size.These preliminary studies illustrated that polymeric Janus nanoparticles synthesized by co-precipitation in a rotating packed bed are promising particles for Pickering emulsions and related work in the future.
基金supported by the National Research Centre,Dokki,Cairo,Egypt project#13050302.
文摘Synthesis of zinc oxide nanoparticles(ZnO-NPs)via green method is an outstanding alternative to conventional/regular methods;however,the safety or toxicity of the biosynthesized ZnO-NPs in vivo is not fully explored.This study was conducted to evaluate the protective efficiency of cinnamaldehyde-loaded chitosan nanoparticles(Cin@CSNPs)against oxidative damage and genotoxicity of ZnO-NPs in mice.ZnO-NPs were biosynthesized using the extract of fresh leaves of Mentha pulegium L.Cin was extracted from cinnamon essential oil,and was loaded into chitosan nanoparticle(Cin@CSNPs).Both ZnO-NPs,Cin@CSNPs and CSNPs were characterized.The in vitro release of Cin@CSNPs was determined.In the biological study,6 groups of male BALB/c mice were treated by gavage for 3 weeks as follows,control group,the group received ZnO-NPs(25 mg/kg b.w),the groups received Cin@CSNPs at low dose(50 mg/kg b.w)or high dose(100 mg/kg b.w),and the groups received ZnO-NPs plus Cin@CSNPs at the 2 tested doses.Blood and tissue samples were collected for different biochemical,genetical and histological studies.The particle size of ZnO-NPs,CSNPs,and Cin@CSNPs were(20.78±2.60),(170.0±3.7),and(218.23±2.90)nm,andξ-potential were(32.7±4.6),(8.32±0.27)and(4.80±0.21)mV,respectively.ZnO-NPs disturbed the biochemical and oxidative stress indices,AFP,CEA,TNF-α,chromosomal aberrations in somatic and germ cells,and sperm abnormality along with severe pathological changes in the hepatic,renal,and testicular tissues.Cin@CSNPs improved significantly all the parameters tested and the histological picture in a dose-dependent.Therefore,the biosynthesized ZnO-NPs exhibit oxidative damage and genotoxicity,and Cin@CSNPs have potential protective effects against the risks of ZnO-NPs and may be a promising tool to overcome the challenges of using Cin in food and pharmaceuticals applications.
文摘Primary biliary cholangitis(PBC)is an autoimmune disease characterized by the selective destruction of intrahepatic small bile ducts,primarily by infiltrating lymphocytes,and has limited therapeutic options.A growing body of evidence suggests that nanoparticles encapsulating rapamycin(ImmTOR)can suppress autoreactive lymphocytes and reduce inflammatory cytokine levels in various autoimmune diseases.In a recent study,Yang et al investigated the therapeutic effects of ImmTOR in a mouse model of PBC.ImmTOR treatment reduced the expression and number of CD4+T cells,CD8+T cells,and B cells isolated from the liver and spleen,improved liver inflammation and enzyme levels,and was associated with a concomitant decrease in anti-mitochondrial antibody levels.In this editorial,we highlight the significance of these findings,focusing on the potential mechanisms by which ImmTOR suppresses hepatic autoreactive T cells and reduces anti-mitochondrial antibody levels,ultimately improving liver pa-thology,through pathways such as mammalian target of rapamycin inhibition and autophagy restoration.We also offer a perspective on future research di-rections for PBC in both animal models and in vitro studies.
基金financially supported by the National Natural Science Foundation of China(Nos.22468029,52274408,52204314)the Major Science and Technology Projects in Yunnan Province(No.202402AF080005)+1 种基金Yunnan Fundamental Research Projects(No.202201AW070014)the Program for Innovative Research Team in the University of ministry of Education of China(No.IRT_17R48)
文摘Ultrafine metal nanoparticles are crucial for various applications,such as energy storage,catalysis,electronics,and biomedicine,owing to their high surfaceto-volume ratio and unique electronic properties.However,conventional nanoparticle synthesis methods often face challenges like irregular shapes and agglomeration,leading to compromised functionality.To address these challenges,this paper introduces a novel,rapid,high-temperature thermal radiation heating for the ultrafast synthesis and dispersion of metal nanoparticles.Utilizing the heating properties of carbon materials,the direct Joule heating generated by them rises to 1800-2000 K within~200 ms,followed by cooling to room temperature at a rate of 2×10^(3)K s^(-1).
