Self-assembled prodrug nanomedicine has emerged as an advanced platform for antitumor therapy,mainly comprise drug modules,response modules and modification modules.However,existing studies usually compare the differe...Self-assembled prodrug nanomedicine has emerged as an advanced platform for antitumor therapy,mainly comprise drug modules,response modules and modification modules.However,existing studies usually compare the differences between single types of modification modules,neglecting the impact of steric-hindrance effect caused by chemical structure.Herein,single-tailed modification module with low-steric-hindrance effect and two-tailed modification module with high-steric-hindrance effect were selected to construct paclitaxel prodrugs(P-LA_(C18)and P-BAC18),and the in-depth insights of the sterichindrance effect on prodrug nanoassemblies were explored.Notably,the size stability of the two-tailed prodrugs was enhanced due to improved intermolecular interactions and steric hindrance.Single-tailed prodrug nanoassemblies were more susceptible to attack by redox agents,showing faster drug release and stronger antitumor efficacy,but with poorer safety.In contrast,two-tailed prodrug nanoassemblies exhibited significant advantages in terms of pharmacokinetics,tumor accumulation and safety due to the good size stability,thus ensuring equivalent antitumor efficacy at tolerance dose.These findings highlighted the critical role of steric-hindrance effect of the modification module in regulating the structureactivity relationship of prodrug nanoassemblies and proposed new perspectives into the precise design of self-assembled prodrugs for high-performance cancer therapeutics.展开更多
Chemotherapy has been recommended as the standard protocol for triple-negative breast cancer(TNBC)at the advanced stage.However,the current treatment is unsatisfactory due to inefficient drug accumulation and rapid ch...Chemotherapy has been recommended as the standard protocol for triple-negative breast cancer(TNBC)at the advanced stage.However,the current treatment is unsatisfactory due to inefficient drug accumulation and rapid chemo-resistance.Thus,rational design of advanced drug delivery systems that can induce multiple cell death pathways is a promising strategy to combat TNBC.Ferroptosis is a powerful non-apoptotic cell death modality,showing potential in tumor inhibition.Herein,we propose a binary prodrug nanoassemblies that combines chemotherapy with ferroptosis for TNBC treatment.In this system,paclitaxel is linked with paracetamol(ferroptosis activator)by a disulfide linkage to construct self-assembly prodrug.Meanwhile,2-distearoyl-sn-glycerol-3-phosphoethanolamine-N-methyl(polyethylene glycol)-2000-tyrosine(DSPE-PEG2k-tyrosine)is applied for large neutral amino acid transporter 1(LAT1)targeting,which is highly expressed in TNBC.The prodrug nanoassemblies exhibit good stability and a glutathione(GSH)-responsive release profile.Furthermore,the LAT1-targeted nanoassemblies show stronger cytotoxicity,higher cellular uptake,and more obvious ferroptosis activation than non-decorated ones.In a TNBC mice model,the prodrug nanoassemblies demonstrate strong anti-tumor efficacy.The application of ferroptosis-assisting chemotherapy may provide a promising strategy for TNBC therapy.展开更多
Successful chemotherapy with paclitaxel(PTX)is impeded by multidrug resistance(MDR)in tumor cells.In this study,lipid-albumin nanoassemblies co-loaded with borneol and paclitaxel(BOR/PTX LANs)were prepared to circumve...Successful chemotherapy with paclitaxel(PTX)is impeded by multidrug resistance(MDR)in tumor cells.In this study,lipid-albumin nanoassemblies co-loaded with borneol and paclitaxel(BOR/PTX LANs)were prepared to circumvent MDR in C6 glioma cells.The physiochemical properties including particle size,encapsulation efficiency and morphology were evaluated in vitro.Quantitative and qualitative investigations of cellular uptake were carried out in C6 glioma cells.The cytotoxicity of the BOR/PTX LANs was determined by MTT assay.After that,the tumor targeting was also evaluated in C6 glioma bearing mice by in vivo imaging analysis.BOR/PTX LANs have a higher entrapment efficiency(90.4±1.2%),small particle size(107.5±3.2 nm),narrow distribution(P.I.=0.171±0.02).The cellular uptake of PTX was significantly increased by BOR/PTX LANs compared with paclitaxel loaded lipidalbumin nanoassemblies(PTX LANs)in quantitative research.The result was further confirmed by confocal laser scanning microscopy qualitatively.The cellular uptake was energy-,timeand concentration-dependent,and clathrin-and endosome/lysosome-associated pathways were involved.The BOR/PTX LANs displayed a higher cytotoxicity agaist C6 glioma cells in comparion with PTX LANs and Taxol.Moreover,the encapsulation of BOR in LANs obviously increased the accumulation of the drug in tumor tissues,demonstrating the tumor targeted ability of BOR/PTX LANs.These results indicated that BOR/PTX LANs could overcome MDR by combination of drug delivery systems and P-gp inhibition,and shown the potential for treatment of gliomas.展开更多
Nanomedicine has made great progress in the targeted therapy of cancer. Here, we established a novel drug-mate strategy by studying the formulation of nanodrugs at the molecular level. In the drug-mate combination, th...Nanomedicine has made great progress in the targeted therapy of cancer. Here, we established a novel drug-mate strategy by studying the formulation of nanodrugs at the molecular level. In the drug-mate combination, the drug is a hydrophobic drug that is poorly soluble in water, and the mate is an amphiphilic small molecule (SMA) that has both hydrophilic and lipophilic properties. We proposed that the hydrophobic drug could co-assemble with a suitable SMA on a nanoscale without additive agents. The proof-ofconcept methodology and results were presented to support our hypothesis. We selected five hydrophobic drugs and more than ten amphiphilic small molecules to construct a library. Through molecular dynamic simulation and quantum chemistry computation,we speculated that the formation of nanoassemblies was related to the binding energy of the drug-mate, and the drug-mate interaction must overcome drug-drug interaction.Furthermore, the obtained SF/VECOONa nanoassemblieswas selected as a model, which had an ultra-high drug loading content (46%), improved pharmacokinetics, increased bioavailability, and enhanced therapeutic efficacy. In summary, the drug-mate strategy is an essential resource to design exact SMA for many hydrophobic drugs and provides a reference for the design of a carrier-free drug delivery system.展开更多
As a representative type of self-supported templates, cyano-bridged cyanogels provide ideal plateaus for synthesis of three-dimensional(3 D) nanostructures. Herein, 3 D pomegranate-like Fe-doped NiCo nanoassemblies(3 ...As a representative type of self-supported templates, cyano-bridged cyanogels provide ideal plateaus for synthesis of three-dimensional(3 D) nanostructures. Herein, 3 D pomegranate-like Fe-doped NiCo nanoassemblies(3 D PG-NiCoFe NAs) were synthesized via facile one-step bi-component cyanogel reduction with NaBH_4 as the reducing agent. Specifically, the influence of the incorporated Fe amount was carefully investigated by finely adjusting the feeding molar ratios of the Ni/Co/Fe atoms in the precursors.By virtue of the unique structure and enriched oxygen vacancies originated from well-modulated electronic structures, the 3 D PG-NiCoFe-211 NAs exhibited outstanding electrocatalytic performances for oxygen evolution reaction(OER) in alkaline solution, outperforming commercial RuO_2 catalyst. The current incorporation of foreign metal atom into host material provides some valuable insights into design and synthesis of metal-based nanocatalysts for constructing practical water splitting devices.展开更多
In this paper, cucurbit[7]uril(CB[7])-mediated three-dimensional gold nanoassemblies were successfully prepared to increase the loaded amount of CB[7] and enhance the electrochemical detection of amino acids. Particle...In this paper, cucurbit[7]uril(CB[7])-mediated three-dimensional gold nanoassemblies were successfully prepared to increase the loaded amount of CB[7] and enhance the electrochemical detection of amino acids. Particle sizes of gold nanoparticles(Au NPs) significantly affect stability and detection sensitivity of nanoassemblies. The volume of gold nanoassemblies first increased and then decreased with the increase of CB[7] concentration. The 3D gold nanoassemblies composed of 16 nm Au NPs and 100 μmol/L CB[7]had excellent stability and maximum volume, exhibiting more sensitive detection for a variety of amino acids. And the detection limits of aromatic amino acids are lower in virtue of the higher binding constant between aromatic amino acids and CB[7]. This study will develop and deepen our understanding of molecular recognition in amino acids detection.展开更多
The clinical utility of irinotecan is restricted by individual variability in carboxylesterase expression.Direct administration of its active metabolite,7-ethyl-10-hydroxycamptothecin(SN38),presents an appealing alter...The clinical utility of irinotecan is restricted by individual variability in carboxylesterase expression.Direct administration of its active metabolite,7-ethyl-10-hydroxycamptothecin(SN38),presents an appealing alternative due to its potent anti-tumor efficacy.However,the undesirable properties of SN38,such as poor water solubility and nontarget toxicity,present significant hurdles to its clinical development.Prodrug nanoassemblies based on modular design strategy show promise in overcoming these challenges by enhancing drug delivery and selective activation.In modular design,the modification module plays a crucial role in improving the self-assembly capability of prodrugs.While current studies mainly focus on using straight aliphatic chains for prodrug design,branched aliphatic chains emerge as superior alternatives warranting further investigation.In this study,we selected 2-heptylundecanol(BAlc18)as modification module to construct an SN38 prodrug.Through exquisite design,SN38-SS-BAlc18 NPs integrated prominent properties in selfassembly capability,specific activation and biocompatibility,resolving the challenges of irinotecan and SN38,ultimately demonstrating excellent anti-tumor efficacy.This exploration enriched the design theory of prodrug nanoassemblies that can effectively balance safety and colorectal anti-tumor efficacy.展开更多
Irinotecan,one of the most effective chemotherapeutic agents for the treatment of advanced colorectal cancer,suffers from extremely low activatability and non-selective tumor activation.7-Ethyl-10-hydroxy-camptothecin...Irinotecan,one of the most effective chemotherapeutic agents for the treatment of advanced colorectal cancer,suffers from extremely low activatability and non-selective tumor activation.7-Ethyl-10-hydroxy-camptothecin(SN38),the active metabolite of irinotecan,has been limited in clinical development due to poor water solubility and stability.Here,the thioether bond and disulfide bond were employed as response modules to construct tumor-selective SN38 prodrug nanoassemblies(SN38-S-C_(21) NPs and SN38-SS-C_(21) NPs).11-Henicosanol was chosen as a self-assembly module to enhance stability.Both SN38-S-C_(21) NPs and SN38-SS-C_(21) NPs presented ultra-high in vivo stability with a 12146-fold and 23151-fold elevation in the area under the curve(AUC)compared to SN38.Moreover,SN38-S-C_(21) NPs and SN38-SS-C_(21) NPs showed a significant reduction of SN38exposure in blood compared to irinotecan.Importantly,the prodrug nanoassemblies enabled selective activation within tumor cells,and the conversion rates of SN38-SS-C_(21) NPs and SN38-S-C_(21) NPs to SN38 were 10-and 7-fold higher than irinotecan.Compared with SN38-S-C_(21) NPs,the superior in vivo stability,SN38 conversion efficiency and tumor selectivity of SN38-SSC_(21) NPs resulted in potent antitumor effects and safety.Our findings proved that the disulfide bond was more suitable for constructing high-performance SN38 prodrug nanoassemblies,which showed significant promise for the rational design of SN38 nanomedicines.展开更多
Dimeric prodrug nanoassemblies(DPNAs)offer great potential in improving the efficacy of chemotherapy.Previously,we developed tetrasulfide bonds as a novel response module and the obtainedγ-4S-2CTX NPs demonstrated su...Dimeric prodrug nanoassemblies(DPNAs)offer great potential in improving the efficacy of chemotherapy.Previously,we developed tetrasulfide bonds as a novel response module and the obtainedγ-4S-2CTX NPs demonstrated superlative self-assembly stability and enhanced anti-tumor efficacy.However,current DPNAs mainly rely on simple PEGylation for surface modification to improve blood circulation,which lacks tumor-selective functionality and limits their further application.To address these limitations,we introduced a new surface modification strategy using RM-1 tumor cell membranes(CMs)to enhance biofunctionality.The initial attempt to use CMs as a single surface modification failed because the affinity of nanocores-CMs remains a problem,which affected the stability of membrane-coated DPNAs.To address this,we used 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N[methoxy(polyethyleneglycol)-2000](DSPE-PEG2k)as an adhesive bridge to improve the affinity between CMs and DPNAs,resulting in a dual-modified formulation termed CM-pDPNAs.This dual modification strategy enhanced CMs binding to DPNAs,enabling precise tumor recognition and internalization,thereby improving tumor elimination efficacy.Furthermore,this approach addressed key challenges associated with current CM-coated nanoparticles(CM-NPs),including complex preparation procedures and poor drug-carrier compatibility.This work elucidates the application of CMs as surface modification modules,paving the way for the next generation of biomimetic prodrug nanoassemblies with superior stability and tumor specficity.展开更多
Prodrug-based nanoassemblies have emerged as advanced carrier-free nanomedicines.These prodrugs typically consist of drug modules,response modules,and modification modules.The general role of modification modules is t...Prodrug-based nanoassemblies have emerged as advanced carrier-free nanomedicines.These prodrugs typically consist of drug modules,response modules,and modification modules.The general role of modification modules is to modulate the self-assembly ability of the prodrugs.How to optimize the structure of modification modules for balanced efficacy and safety of high-toxicity chemotherapeutic drugs deserves to be further investigated.In this study,a modification strategy of aliphatic alcohols with various chain lengths(SC_(4),SC_(8),SC_(12),SC_(16) and SC_(20))was carried out to design five cabazitaxel(CBZ)prodrugs.Among them,CBZ-SC NPs with shorter chain length(SC_(4) and SC_(8))showed poor self-assembly stability.CBZ-SC_(12) NPs also failed to remain stable while the other two CBZ-SC NPs exhibited good stability.In turn,the drug release rate was hindered by the increasing chain length.CBZ-SC12 NPs caused kidney damage due to their high redox-sensitivity and rapid release rate during circulation.By contrast,CBZ-SC NPs with longer chain length(SC_(16) and SC_(20))not only demonstrated superior stability with improved pharmacokinetic behavior,but also might solve the dilemma of dose-related toxicity caused by CBZ.Overall,these findings emphasized the importance of chain length in modification module to modulate the efficacy and safety of CBZ prodrug nanoassemblies.展开更多
The self-assembly prodrugs are usually consisted of drug modules,activation modules,and assembly modules.Keeping the balance between efficacy and safety by selecting suitable modules remains a challenge for developing...The self-assembly prodrugs are usually consisted of drug modules,activation modules,and assembly modules.Keeping the balance between efficacy and safety by selecting suitable modules remains a challenge for developing prodrug nanoassemblies.This study designed four docetaxel(DTX)prodrugs using disulfide bonds as activation modules and different lengths of branched-chain fatty alcohols as assembly modules(C_(16),C_(18),C_(20),and C_(24)).The lengths of the assembly modules determined the self-assembly ability of prodrugs and affected the activation modules’sensitivity.The extension of the carbon chains improved the prodrugs’self-assembly ability and pharmacokinetic behavior while reducing the cytotoxicity and increased cumulative toxicity.The use of C_(20) can balance efficacy and safety.These results provide a great reference for the rational design of prodrug nanoassemblies.展开更多
Small-molecule prodrug nanoassemblies have emerged as efficient antitumor drug delivery systems.However,in the case of camptothecins-based prodrug nanoassemblies,linear aliphatic side chain modification often results ...Small-molecule prodrug nanoassemblies have emerged as efficient antitumor drug delivery systems.However,in the case of camptothecins-based prodrug nanoassemblies,linear aliphatic side chain modification often results in rod-shaped or irregularly shaped nanoassemblies,which are highly unfavorable for sterilization through filtration,and may cause capillary blockage upon intravenous injection.The rational design of camptothecins-based prodrug nanoassemblies remains a challenge.Herein,we propose that branched aliphatic alcohol(BAA)functionalization could fine-tune the structure-tolerance-antitumor efficacy axis of prodrug nanoassemblies.Correspondingly,four SN38-BAA prodrugs were synthesized by conjugating 7-ethyl-10-hydroxycamptothecin(SN38)with BAAs of varying lengths via a tumor redox-responsive disulfide bond,which self-assemble into uniform spherical nanoparticles.The length of BAA was found to significant impact the multiple drug delivery process,including colloidal stability,drug release profiles and pharmacokinetics.Overall,SN38-C21 NPs(SN38-11-heneicosanol nanoparticles),featuring the longest BAA,showcased multiple therapeutic advantages,ultimately culminating the optimal antitumor efficacy and tolerance.The findings underscore the potential of BAA functionalization in strengthening the therapeutic outcomes of prodrug nanoassemblies,and provide valuable insights for developing translational camptothecins-based nanomedicines.展开更多
Natural phytoconstituents exhibit distinct advantages in the management and prevention of inflammatory bowel disease(IBD),attributed to their robust biological activity,multi-target effects,and elevated safety profile...Natural phytoconstituents exhibit distinct advantages in the management and prevention of inflammatory bowel disease(IBD),attributed to their robust biological activity,multi-target effects,and elevated safety profile.Although promising,the clinical application of phytoconstituents have been impeded by poor water solubility,low oral bioavailability,and inadequate colonic targeting.Recent advancements in nanotechnology has offered prospective avenues for the application of phytoconstituents in the treatment of IBD.A common strategy involves encapsulating or conjugating phytoconstituents with nanocarriers to enhance their stability,prolong intestinal retention,and facilitate targeted delivery to colonic inflammatory tissues.Furthermore,drawing inspiration from the self-assembling nanostructures that emerge during the decoction process of Chinese herbs,a variety of natural active compounds-based nanoassemblies have been developed for the treatment of IBD.They exhibit high drug-loading capacities and surmount the challenges posed by poor water solubility and low bioavailability.Notably,phyto-derived nanovesicles,owing to their unique structure and biological functions,can serve as therapeutic agents or novel delivery vehicles for the treatment of IBD.Consequently,this review provides an extensive overview of emerging phytoconstituent-derived nano-medicines/vesicles for the treatment of IBD,intending to offer novel insights for the clinical management of IBD.展开更多
Prodrug nanoassemblies, which can refrain from large excipients, achieve higher drug loading and control drug release, have been placed as the priority in drug delivery system. Reasoning that glutathione(GSH) and reac...Prodrug nanoassemblies, which can refrain from large excipients, achieve higher drug loading and control drug release, have been placed as the priority in drug delivery system. Reasoning that glutathione(GSH) and reactive oxygen species(ROS) are highly upgraded in tumor tissues which makes them attractive targets for drug delivery system, we designed and synthetized a novel prodrug which utilized mono thioether bond as a linker to bridge linoleic acid(LA) and docetaxel(DTX). This mono thioether-linked conjugates(DTX-S-LA) could self-assemble into nanoparticles without the aid of much excipients. The mono thioether endowed the nanoparticles redox sensitivity resulting in specific release at the tumor tissue. Our studies demonstrated that the nanoassemblies had uniform particle size, high stability and fast release behavior. DTX-S-LA nanoassemblies outperformed DTX solution in pharmacokinetic profiles for it had longer circulation time and higher area under curve(AUC). Compared with DTX solution, the redox dual-responsive nanoassemblies had comparable cytotoxic activity. Besides, the antitumor efficacy was evaluated in mice bearing 4 T1 xenograft. It turned out this nanoassemblies couldenhance anticancer efficacy by increasing the dose because of higher tolerance. Overall, these results indicated that the redox sensitivity nanoassemblies may have a great potential to cancer therapy.展开更多
Novel self-assembled architectures have received a growing amount of attention and have significant potential for application in catalysis/electrocatalysis. Herein, we take advantage of the unique coordination and sel...Novel self-assembled architectures have received a growing amount of attention and have significant potential for application in catalysis/electrocatalysis. Herein, we take advantage of the unique coordination and self-assembly properties of arginine for the preparation of dendritic PtCu bimetallic nanoassemblies with tunable chemical composition and structure. Strong interactions between the arginine molecules are key in driving the self-assembly of primary nanocrystals. In addition, the strong coordination interactions between arginine and metal ions is responsible for the formation of Pt-Cu alloys. We also investigated the electrocatalytic activity of various dendritic PtCu bimetallic nanoassemblies towards the methanol oxidation reaction. PtBCUl nanoassemblies exhibited excellent electrocatalytic activity and stability in comparison with other PtCu bimetallic nanoassemblies (PtlCu3, PtlCu~) and commercial Pt black, due to their unique dendritic structures and the synergistic effect between the Pt and Cu atoms.展开更多
Nanoparticle-based therapeutics represent potential strategies for treating atherosclerosis;however,the complex plaque microenvironment poses a barrier for nanoparticles to target the dysfunctional cells.Here,we repor...Nanoparticle-based therapeutics represent potential strategies for treating atherosclerosis;however,the complex plaque microenvironment poses a barrier for nanoparticles to target the dysfunctional cells.Here,we report reactive oxygen species(ROS)-responsive and size-reducible nanoassemblies,formed by multivalent host-vip interactions betweenβ-cyclodextrins(β-CD)-anchored discoidal recombinant high-density lipoprotein(NP^(3)_(ST))and hyaluronic acid-ferrocene(HA-Fc)conjugates.The HA-Fc/NP^(3)_(ST)nanoassemblies have extended blood circulation time,specifically accumulate in atherosclerotic plaque mediated by the HA receptors CD44 highly expressed in injured endothelium,rapidly disassemble in response to excess ROS in the intimal and release smaller NP^(3)_(ST),allowing for further plaque penetration,macrophage-targeted cholesterol efflux and drug delivery.In vivo pharmacodynamicses in atherosclerotic mice shows that HA-Fc/NP^(3)_(ST)reduces plaque size by 53%,plaque lipid deposition by 63%,plaque macrophage content by 62%and local inflammatory factor level by 64%compared to the saline group.Meanwhile,HA-Fc/NP^(3)_(ST)alleviates systemic inflammation characterized by reduced serum inflammatory factor levels.Collectively,HA-Fc/NP^(3)_(ST)nanoassemblies with ROS-responsive and size-reducible properties exhibit a deeper penetration in atherosclerotic plaque and enhanced macrophage targeting ability,thus exerting effective cholesterol efflux and drug delivery for atherosclerosis therapy.展开更多
Poly(caprolactone-b-2-vinylpyridine) (PCL-P2VP) coated with folate-conjugated M13 (FA-M13) provides a nanosized delivery system which is capable of encapsulating hydrophobic antitumor drugs such as doxorubicin ...Poly(caprolactone-b-2-vinylpyridine) (PCL-P2VP) coated with folate-conjugated M13 (FA-M13) provides a nanosized delivery system which is capable of encapsulating hydrophobic antitumor drugs such as doxorubicin (DOX). The DOXqoaded FA-M13-PCL-P2VP assemblies had an average diameter of approximately 200 nm and their structure was characterized using transmission electron microscopy, scanning electron microscopy, and dynamic light scattering. The particles were stable at physiological pH but could be degraded at a lower pH. The release of DOX from the nanoassemblies under acidic conditions was shown to be significantly faster than that observed at physiological pH. In addition, the DOX-loaded FA-M13-PCL-P2VP particles showed a distinctly greater cellular uptake and cytotoxicity against folate-receptor-positive cancer cells than folate-receptor-negative cells, indicating that the receptor facilitates folate uptake via receptor-mediated endocytosis. Furthermore, the DOX-loaded particles also had a significantly higher tumor uptake and selectivity compared to free DOX. This study therefore offers a new way to fabricate nanosized drug delivery vehicles.展开更多
Controllable self-assembly of noble metal nanocrystals is of broad interest for the development of highly active electrocatalysts. Here we report an efficient arginine-mediated hydrothermal approach for the high-yield...Controllable self-assembly of noble metal nanocrystals is of broad interest for the development of highly active electrocatalysts. Here we report an efficient arginine-mediated hydrothermal approach for the high-yield synthesis of cube-like Pt nanoassemblies (Pt-CNAs) with porous cavities and rough surfaces based on the self-assembly of zero dimensional Pt nanocrystals. In this process, arginine acts as the reductant, structure directing agent, and linker between adjacent nanocrystals. Interestingly, the Pt-CNAs exhibit single-crystal structures with dominant {100} facets, as evidenced by X-ray diffraction. Based on electrocatalytic studies, the as-synthesized Pt-CNAs exhibit improved electrocatalytic activity as well as good stability and CO tolerance in the methanol oxidation reaction. The Pt-CNA's good performance is attributed to their unique morphology and surface structure. We believe that the synthetic strategy outlined here could be extended to other rationally designed monometallic or bimetallic nanoassemblies for use in high performance fuel cells.展开更多
The practical application of nanomedicines for cancer therapy is generally hampered by their compromised tumor accumulation and transmembrane potency.Cell penetrating peptides(CPPs)have been widely used to enhance the...The practical application of nanomedicines for cancer therapy is generally hampered by their compromised tumor accumulation and transmembrane potency.Cell penetrating peptides(CPPs)have been widely used to enhance the drug delivery efficiency in tumor cells.However,conventional CPPs are vulnerable towards proteases and are generally lack of therapeutic effects.To maximize the efficacy of nanomedicines,new classes of cell penetrating therapeutic modalities are highly desirable.Stapled peptides have drawn wide attention as one of the cell-permeable peptidomimetics for intracellular targets.Herein,we reported a novel approach for enhancing the therapeutic efficacy of chemo-photothermal therapy by taking advantage of the robust cell permeability and therapeutic effects of stapled peptides.The designed pH-activatable lactam-stapled peptide-polymer conjugate formed supramolecular nanoassemblies to encapsulate the chemodrug doxorubicin(DOX).Once reaching the tumor site,the lactam-stapled proapoptotic peptide could be efficiently activated under acidic tumor microenvironment,thereby promoting the drug delivery to the tumor cells and specific targeting mitochondria to interfere with the energy metabolism of tumor cells,which works in synergy with the DOX and local hyperthermia upon near infrared ray(NIR)light irradiation.This work may benefit future design of stapled peptides-based stimuli-responsive nanoplatforms for enhanced cancer therapy.展开更多
Photoimmunotherapy(PIT)is an emerging therapeutic approach that integrates phototherapy and immunotherapy to eliminate primary tumors under an appropriate dosage of local light irradiation,while simultaneously prevent...Photoimmunotherapy(PIT)is an emerging therapeutic approach that integrates phototherapy and immunotherapy to eliminate primary tumors under an appropriate dosage of local light irradiation,while simultaneously preventing tumor metastasis and recurrence by activating the host antitumor immune response.Tumor-responsive dynamic nanoassemblies(TDNs)have evolved from being a mere curiosity to a promising platform for high-performance PIT.However,the dynamic nano-bio interaction between TDNs and tumor microenvironment remains poorly understood,which shall be critical for precise control of TDNs assembling/disassembling behavior and superior PIT efficacy.To deepen the understanding of the structure–function relationship of TDNs,this review introduces the rational design,nano-bio interactions,and controllable functionalities of cutting-edge TDNs for enhanced PIT.Moreover,the synergetic mechanism between TDNs-based PIT and immunomodulatory agents-mediated immunomodulation is particularly emphasized.Finally,the challenges and future perspectives in this emerging field are assessed.展开更多
基金supported by the National Natural Science Foundation of China,(Nos.82272151,82204318)Liaoning Revitalization Talents Program(No.XLYC2203083)+2 种基金Shenyang Young and Middle-aged Science and Technology Innovation Talent Support Program(No.RC220389)Postdoctoral Fellowship Program of CPSF(No.GZC20231732)China Postdoctoral Science Foundation(Nos.2023TQ0222,2023MD744229).
文摘Self-assembled prodrug nanomedicine has emerged as an advanced platform for antitumor therapy,mainly comprise drug modules,response modules and modification modules.However,existing studies usually compare the differences between single types of modification modules,neglecting the impact of steric-hindrance effect caused by chemical structure.Herein,single-tailed modification module with low-steric-hindrance effect and two-tailed modification module with high-steric-hindrance effect were selected to construct paclitaxel prodrugs(P-LA_(C18)and P-BAC18),and the in-depth insights of the sterichindrance effect on prodrug nanoassemblies were explored.Notably,the size stability of the two-tailed prodrugs was enhanced due to improved intermolecular interactions and steric hindrance.Single-tailed prodrug nanoassemblies were more susceptible to attack by redox agents,showing faster drug release and stronger antitumor efficacy,but with poorer safety.In contrast,two-tailed prodrug nanoassemblies exhibited significant advantages in terms of pharmacokinetics,tumor accumulation and safety due to the good size stability,thus ensuring equivalent antitumor efficacy at tolerance dose.These findings highlighted the critical role of steric-hindrance effect of the modification module in regulating the structureactivity relationship of prodrug nanoassemblies and proposed new perspectives into the precise design of self-assembled prodrugs for high-performance cancer therapeutics.
基金supported by the National Nature Science Foundation of China(No.81803029)the Science and Technology Foundation of Yuzhong District,Chongqing(No.20210179)the Nature Science Foundation of Chongqing(No.cstc2021jcyjmsxmX1089)。
文摘Chemotherapy has been recommended as the standard protocol for triple-negative breast cancer(TNBC)at the advanced stage.However,the current treatment is unsatisfactory due to inefficient drug accumulation and rapid chemo-resistance.Thus,rational design of advanced drug delivery systems that can induce multiple cell death pathways is a promising strategy to combat TNBC.Ferroptosis is a powerful non-apoptotic cell death modality,showing potential in tumor inhibition.Herein,we propose a binary prodrug nanoassemblies that combines chemotherapy with ferroptosis for TNBC treatment.In this system,paclitaxel is linked with paracetamol(ferroptosis activator)by a disulfide linkage to construct self-assembly prodrug.Meanwhile,2-distearoyl-sn-glycerol-3-phosphoethanolamine-N-methyl(polyethylene glycol)-2000-tyrosine(DSPE-PEG2k-tyrosine)is applied for large neutral amino acid transporter 1(LAT1)targeting,which is highly expressed in TNBC.The prodrug nanoassemblies exhibit good stability and a glutathione(GSH)-responsive release profile.Furthermore,the LAT1-targeted nanoassemblies show stronger cytotoxicity,higher cellular uptake,and more obvious ferroptosis activation than non-decorated ones.In a TNBC mice model,the prodrug nanoassemblies demonstrate strong anti-tumor efficacy.The application of ferroptosis-assisting chemotherapy may provide a promising strategy for TNBC therapy.
文摘Successful chemotherapy with paclitaxel(PTX)is impeded by multidrug resistance(MDR)in tumor cells.In this study,lipid-albumin nanoassemblies co-loaded with borneol and paclitaxel(BOR/PTX LANs)were prepared to circumvent MDR in C6 glioma cells.The physiochemical properties including particle size,encapsulation efficiency and morphology were evaluated in vitro.Quantitative and qualitative investigations of cellular uptake were carried out in C6 glioma cells.The cytotoxicity of the BOR/PTX LANs was determined by MTT assay.After that,the tumor targeting was also evaluated in C6 glioma bearing mice by in vivo imaging analysis.BOR/PTX LANs have a higher entrapment efficiency(90.4±1.2%),small particle size(107.5±3.2 nm),narrow distribution(P.I.=0.171±0.02).The cellular uptake of PTX was significantly increased by BOR/PTX LANs compared with paclitaxel loaded lipidalbumin nanoassemblies(PTX LANs)in quantitative research.The result was further confirmed by confocal laser scanning microscopy qualitatively.The cellular uptake was energy-,timeand concentration-dependent,and clathrin-and endosome/lysosome-associated pathways were involved.The BOR/PTX LANs displayed a higher cytotoxicity agaist C6 glioma cells in comparion with PTX LANs and Taxol.Moreover,the encapsulation of BOR in LANs obviously increased the accumulation of the drug in tumor tissues,demonstrating the tumor targeted ability of BOR/PTX LANs.These results indicated that BOR/PTX LANs could overcome MDR by combination of drug delivery systems and P-gp inhibition,and shown the potential for treatment of gliomas.
基金supported by the National Natural Science Foundation of China (grant numbers:81974498)Natural Science Foundation of Shandong Province (grant numbers:ZR2019BH079)。
文摘Nanomedicine has made great progress in the targeted therapy of cancer. Here, we established a novel drug-mate strategy by studying the formulation of nanodrugs at the molecular level. In the drug-mate combination, the drug is a hydrophobic drug that is poorly soluble in water, and the mate is an amphiphilic small molecule (SMA) that has both hydrophilic and lipophilic properties. We proposed that the hydrophobic drug could co-assemble with a suitable SMA on a nanoscale without additive agents. The proof-ofconcept methodology and results were presented to support our hypothesis. We selected five hydrophobic drugs and more than ten amphiphilic small molecules to construct a library. Through molecular dynamic simulation and quantum chemistry computation,we speculated that the formation of nanoassemblies was related to the binding energy of the drug-mate, and the drug-mate interaction must overcome drug-drug interaction.Furthermore, the obtained SF/VECOONa nanoassemblieswas selected as a model, which had an ultra-high drug loading content (46%), improved pharmacokinetics, increased bioavailability, and enhanced therapeutic efficacy. In summary, the drug-mate strategy is an essential resource to design exact SMA for many hydrophobic drugs and provides a reference for the design of a carrier-free drug delivery system.
基金supported by the National Natural Science Foundation of China (No. 21805245)the Zhejiang Public Welfare Technology Application Research Project (LGG19B050001)the National Students’ Innovation and Entrepreneurship Training Program of Zhejiang Normal University (201910345032, Z.J. Wang)。
文摘As a representative type of self-supported templates, cyano-bridged cyanogels provide ideal plateaus for synthesis of three-dimensional(3 D) nanostructures. Herein, 3 D pomegranate-like Fe-doped NiCo nanoassemblies(3 D PG-NiCoFe NAs) were synthesized via facile one-step bi-component cyanogel reduction with NaBH_4 as the reducing agent. Specifically, the influence of the incorporated Fe amount was carefully investigated by finely adjusting the feeding molar ratios of the Ni/Co/Fe atoms in the precursors.By virtue of the unique structure and enriched oxygen vacancies originated from well-modulated electronic structures, the 3 D PG-NiCoFe-211 NAs exhibited outstanding electrocatalytic performances for oxygen evolution reaction(OER) in alkaline solution, outperforming commercial RuO_2 catalyst. The current incorporation of foreign metal atom into host material provides some valuable insights into design and synthesis of metal-based nanocatalysts for constructing practical water splitting devices.
基金supported in part by grants from the National Natural Science Foundation of China (No. 21871108)the Program for Innovative Teams of Outstanding Young and Middle-Aged Researchers in the Higher Education Institutions of Hubei Province(No. T201702)。
文摘In this paper, cucurbit[7]uril(CB[7])-mediated three-dimensional gold nanoassemblies were successfully prepared to increase the loaded amount of CB[7] and enhance the electrochemical detection of amino acids. Particle sizes of gold nanoparticles(Au NPs) significantly affect stability and detection sensitivity of nanoassemblies. The volume of gold nanoassemblies first increased and then decreased with the increase of CB[7] concentration. The 3D gold nanoassemblies composed of 16 nm Au NPs and 100 μmol/L CB[7]had excellent stability and maximum volume, exhibiting more sensitive detection for a variety of amino acids. And the detection limits of aromatic amino acids are lower in virtue of the higher binding constant between aromatic amino acids and CB[7]. This study will develop and deepen our understanding of molecular recognition in amino acids detection.
基金gotapproval from the Institutional Animal Ethical Care Committee(IAEC)of Shenyang Pharmaceutical University(ethical code:SYPU-IACUC-2022-0302-010).
文摘The clinical utility of irinotecan is restricted by individual variability in carboxylesterase expression.Direct administration of its active metabolite,7-ethyl-10-hydroxycamptothecin(SN38),presents an appealing alternative due to its potent anti-tumor efficacy.However,the undesirable properties of SN38,such as poor water solubility and nontarget toxicity,present significant hurdles to its clinical development.Prodrug nanoassemblies based on modular design strategy show promise in overcoming these challenges by enhancing drug delivery and selective activation.In modular design,the modification module plays a crucial role in improving the self-assembly capability of prodrugs.While current studies mainly focus on using straight aliphatic chains for prodrug design,branched aliphatic chains emerge as superior alternatives warranting further investigation.In this study,we selected 2-heptylundecanol(BAlc18)as modification module to construct an SN38 prodrug.Through exquisite design,SN38-SS-BAlc18 NPs integrated prominent properties in selfassembly capability,specific activation and biocompatibility,resolving the challenges of irinotecan and SN38,ultimately demonstrating excellent anti-tumor efficacy.This exploration enriched the design theory of prodrug nanoassemblies that can effectively balance safety and colorectal anti-tumor efficacy.
基金supported by the National Key R&D Program of China(2022YFE0111600)the Key Research and Development Program of Liaoning Province(2024JH2/102500061)+7 种基金the Youth Innovation Team of Liaoning Provincial Department of Education(LJ222410163049)the Liaoning Revitalization Talents Program(XLYC2203083)the Open Fund of High-level Key Discipline of Chemistry of Chinese Medicine of the State Administration of Traditional Chinese Medicinethe Anhui University of Chinese Medicine(HKDCCM2024007)the Postdoctoral Fellowship Program of China Postdoctoral Science Foundation(CPSF)(GZC20231-732)the China Postdoctoral Science Foundation(2023TQ0222,2023MD744229)the General Program of Department of Education of Liaoning Province(JYTMS20231372)the Doctoral Scientific Research Staring Foundation of Liaoning Province(2024-BS-073)。
文摘Irinotecan,one of the most effective chemotherapeutic agents for the treatment of advanced colorectal cancer,suffers from extremely low activatability and non-selective tumor activation.7-Ethyl-10-hydroxy-camptothecin(SN38),the active metabolite of irinotecan,has been limited in clinical development due to poor water solubility and stability.Here,the thioether bond and disulfide bond were employed as response modules to construct tumor-selective SN38 prodrug nanoassemblies(SN38-S-C_(21) NPs and SN38-SS-C_(21) NPs).11-Henicosanol was chosen as a self-assembly module to enhance stability.Both SN38-S-C_(21) NPs and SN38-SS-C_(21) NPs presented ultra-high in vivo stability with a 12146-fold and 23151-fold elevation in the area under the curve(AUC)compared to SN38.Moreover,SN38-S-C_(21) NPs and SN38-SS-C_(21) NPs showed a significant reduction of SN38exposure in blood compared to irinotecan.Importantly,the prodrug nanoassemblies enabled selective activation within tumor cells,and the conversion rates of SN38-SS-C_(21) NPs and SN38-S-C_(21) NPs to SN38 were 10-and 7-fold higher than irinotecan.Compared with SN38-S-C_(21) NPs,the superior in vivo stability,SN38 conversion efficiency and tumor selectivity of SN38-SSC_(21) NPs resulted in potent antitumor effects and safety.Our findings proved that the disulfide bond was more suitable for constructing high-performance SN38 prodrug nanoassemblies,which showed significant promise for the rational design of SN38 nanomedicines.
基金the National Key R&D Program of China(No.2022YFE0111600)the National Natural Science Foundation of China(No.82204318)+2 种基金Key research and development program of Liaoning Province(No.2024JH2/102500061)Youth innovation team of Liaoning Province Department of Education(No.LJ222410163049)Liaoning Revitalization Talents Program(No.XLYC2203083).
文摘Dimeric prodrug nanoassemblies(DPNAs)offer great potential in improving the efficacy of chemotherapy.Previously,we developed tetrasulfide bonds as a novel response module and the obtainedγ-4S-2CTX NPs demonstrated superlative self-assembly stability and enhanced anti-tumor efficacy.However,current DPNAs mainly rely on simple PEGylation for surface modification to improve blood circulation,which lacks tumor-selective functionality and limits their further application.To address these limitations,we introduced a new surface modification strategy using RM-1 tumor cell membranes(CMs)to enhance biofunctionality.The initial attempt to use CMs as a single surface modification failed because the affinity of nanocores-CMs remains a problem,which affected the stability of membrane-coated DPNAs.To address this,we used 1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N[methoxy(polyethyleneglycol)-2000](DSPE-PEG2k)as an adhesive bridge to improve the affinity between CMs and DPNAs,resulting in a dual-modified formulation termed CM-pDPNAs.This dual modification strategy enhanced CMs binding to DPNAs,enabling precise tumor recognition and internalization,thereby improving tumor elimination efficacy.Furthermore,this approach addressed key challenges associated with current CM-coated nanoparticles(CM-NPs),including complex preparation procedures and poor drug-carrier compatibility.This work elucidates the application of CMs as surface modification modules,paving the way for the next generation of biomimetic prodrug nanoassemblies with superior stability and tumor specficity.
基金support from the Key research and development program of Liaoning Province(No.2024JH2/102500061)Youth innovation team of Liaoning Province Department of Education(No.LJ222410163049)Liaoning Revitalization Talents Program(No.XLYC2203083).
文摘Prodrug-based nanoassemblies have emerged as advanced carrier-free nanomedicines.These prodrugs typically consist of drug modules,response modules,and modification modules.The general role of modification modules is to modulate the self-assembly ability of the prodrugs.How to optimize the structure of modification modules for balanced efficacy and safety of high-toxicity chemotherapeutic drugs deserves to be further investigated.In this study,a modification strategy of aliphatic alcohols with various chain lengths(SC_(4),SC_(8),SC_(12),SC_(16) and SC_(20))was carried out to design five cabazitaxel(CBZ)prodrugs.Among them,CBZ-SC NPs with shorter chain length(SC_(4) and SC_(8))showed poor self-assembly stability.CBZ-SC_(12) NPs also failed to remain stable while the other two CBZ-SC NPs exhibited good stability.In turn,the drug release rate was hindered by the increasing chain length.CBZ-SC12 NPs caused kidney damage due to their high redox-sensitivity and rapid release rate during circulation.By contrast,CBZ-SC NPs with longer chain length(SC_(16) and SC_(20))not only demonstrated superior stability with improved pharmacokinetic behavior,but also might solve the dilemma of dose-related toxicity caused by CBZ.Overall,these findings emphasized the importance of chain length in modification module to modulate the efficacy and safety of CBZ prodrug nanoassemblies.
基金financially supported by National Key R&D Program of China(No.2022YFE0111600)National Natural Science Foundation of China(No.82272151 and 82204318)+2 种基金Doctoral Scientific Research Staring Foundation of Liaoning Province(No.2021-BS-130,China)General Program of Department of Education of Liaoning Province(No.LJKZ0953,China)Shenyang Young and Middle-aged Science and Technology Innovation Talents Support Program(RC220389,China)。
文摘The self-assembly prodrugs are usually consisted of drug modules,activation modules,and assembly modules.Keeping the balance between efficacy and safety by selecting suitable modules remains a challenge for developing prodrug nanoassemblies.This study designed four docetaxel(DTX)prodrugs using disulfide bonds as activation modules and different lengths of branched-chain fatty alcohols as assembly modules(C_(16),C_(18),C_(20),and C_(24)).The lengths of the assembly modules determined the self-assembly ability of prodrugs and affected the activation modules’sensitivity.The extension of the carbon chains improved the prodrugs’self-assembly ability and pharmacokinetic behavior while reducing the cytotoxicity and increased cumulative toxicity.The use of C_(20) can balance efficacy and safety.These results provide a great reference for the rational design of prodrug nanoassemblies.
基金supported by National Natural Science Foundation of China(Nos.82272151,82204318 and 82173766)Doctoral Scientific Research Staring Foundation of Liaoning Province(No.2021-BS-130)+1 种基金General Program of Department of Education of Liaoning Province(No.LJKZ0953)Shenyang Young and Middle-aged Science and Technology Innovation Talent Support Program(No.RC220389).
文摘Small-molecule prodrug nanoassemblies have emerged as efficient antitumor drug delivery systems.However,in the case of camptothecins-based prodrug nanoassemblies,linear aliphatic side chain modification often results in rod-shaped or irregularly shaped nanoassemblies,which are highly unfavorable for sterilization through filtration,and may cause capillary blockage upon intravenous injection.The rational design of camptothecins-based prodrug nanoassemblies remains a challenge.Herein,we propose that branched aliphatic alcohol(BAA)functionalization could fine-tune the structure-tolerance-antitumor efficacy axis of prodrug nanoassemblies.Correspondingly,four SN38-BAA prodrugs were synthesized by conjugating 7-ethyl-10-hydroxycamptothecin(SN38)with BAAs of varying lengths via a tumor redox-responsive disulfide bond,which self-assemble into uniform spherical nanoparticles.The length of BAA was found to significant impact the multiple drug delivery process,including colloidal stability,drug release profiles and pharmacokinetics.Overall,SN38-C21 NPs(SN38-11-heneicosanol nanoparticles),featuring the longest BAA,showcased multiple therapeutic advantages,ultimately culminating the optimal antitumor efficacy and tolerance.The findings underscore the potential of BAA functionalization in strengthening the therapeutic outcomes of prodrug nanoassemblies,and provide valuable insights for developing translational camptothecins-based nanomedicines.
基金supported by the National Natural Science Foundation of China(Nos.82273824,31670359 and 82372111)the Liao Ning Revitalization Talents Program(No.XLYC 1905019)。
文摘Natural phytoconstituents exhibit distinct advantages in the management and prevention of inflammatory bowel disease(IBD),attributed to their robust biological activity,multi-target effects,and elevated safety profile.Although promising,the clinical application of phytoconstituents have been impeded by poor water solubility,low oral bioavailability,and inadequate colonic targeting.Recent advancements in nanotechnology has offered prospective avenues for the application of phytoconstituents in the treatment of IBD.A common strategy involves encapsulating or conjugating phytoconstituents with nanocarriers to enhance their stability,prolong intestinal retention,and facilitate targeted delivery to colonic inflammatory tissues.Furthermore,drawing inspiration from the self-assembling nanostructures that emerge during the decoction process of Chinese herbs,a variety of natural active compounds-based nanoassemblies have been developed for the treatment of IBD.They exhibit high drug-loading capacities and surmount the challenges posed by poor water solubility and low bioavailability.Notably,phyto-derived nanovesicles,owing to their unique structure and biological functions,can serve as therapeutic agents or novel delivery vehicles for the treatment of IBD.Consequently,this review provides an extensive overview of emerging phytoconstituent-derived nano-medicines/vesicles for the treatment of IBD,intending to offer novel insights for the clinical management of IBD.
基金supported by Liaoning BaiQianWan Talents Program(No.2016921064,China)Nature Science Foundation of Guangdong Province(No.2016A020217017,China)
文摘Prodrug nanoassemblies, which can refrain from large excipients, achieve higher drug loading and control drug release, have been placed as the priority in drug delivery system. Reasoning that glutathione(GSH) and reactive oxygen species(ROS) are highly upgraded in tumor tissues which makes them attractive targets for drug delivery system, we designed and synthetized a novel prodrug which utilized mono thioether bond as a linker to bridge linoleic acid(LA) and docetaxel(DTX). This mono thioether-linked conjugates(DTX-S-LA) could self-assemble into nanoparticles without the aid of much excipients. The mono thioether endowed the nanoparticles redox sensitivity resulting in specific release at the tumor tissue. Our studies demonstrated that the nanoassemblies had uniform particle size, high stability and fast release behavior. DTX-S-LA nanoassemblies outperformed DTX solution in pharmacokinetic profiles for it had longer circulation time and higher area under curve(AUC). Compared with DTX solution, the redox dual-responsive nanoassemblies had comparable cytotoxic activity. Besides, the antitumor efficacy was evaluated in mice bearing 4 T1 xenograft. It turned out this nanoassemblies couldenhance anticancer efficacy by increasing the dose because of higher tolerance. Overall, these results indicated that the redox sensitivity nanoassemblies may have a great potential to cancer therapy.
基金This research was sponsored by National Natural Sdence Foundation of China (Nos. 21473111, 21576139, 21503111, 21376122, and 21273116), United Fund of NSFC and Yunnan Province (No. Ul137602), Natural Science Foundation of Jiangsu Province (No. BK20131395), Natural Science Foundation of Shaanxi Province (No. 2015JM2043), Fundamental Research Funds for the Central Universities (No. GK201402016), China Scholarship Council (CSC, No. 201506860013), University Postgraduate Research and Innovation Project in Jiangsu Province (No. KYZZ15_0213), National and Local Joint Engineering Research Center of Biomedical Functional Material, and a project funded by the Priority Academic Program Development of Jiangsu Higher Education Institutions. The authors also thank John B. Goodenough UT-Austin for his help with XPS and electrochemical measurements during the article revision.
文摘Novel self-assembled architectures have received a growing amount of attention and have significant potential for application in catalysis/electrocatalysis. Herein, we take advantage of the unique coordination and self-assembly properties of arginine for the preparation of dendritic PtCu bimetallic nanoassemblies with tunable chemical composition and structure. Strong interactions between the arginine molecules are key in driving the self-assembly of primary nanocrystals. In addition, the strong coordination interactions between arginine and metal ions is responsible for the formation of Pt-Cu alloys. We also investigated the electrocatalytic activity of various dendritic PtCu bimetallic nanoassemblies towards the methanol oxidation reaction. PtBCUl nanoassemblies exhibited excellent electrocatalytic activity and stability in comparison with other PtCu bimetallic nanoassemblies (PtlCu3, PtlCu~) and commercial Pt black, due to their unique dendritic structures and the synergistic effect between the Pt and Cu atoms.
基金supported by grants from the National Natural Science Foundation of China(grant no.81773669,82073788)National Major Science and Technology Projects of China(grant no.2017YFA0205400).
文摘Nanoparticle-based therapeutics represent potential strategies for treating atherosclerosis;however,the complex plaque microenvironment poses a barrier for nanoparticles to target the dysfunctional cells.Here,we report reactive oxygen species(ROS)-responsive and size-reducible nanoassemblies,formed by multivalent host-vip interactions betweenβ-cyclodextrins(β-CD)-anchored discoidal recombinant high-density lipoprotein(NP^(3)_(ST))and hyaluronic acid-ferrocene(HA-Fc)conjugates.The HA-Fc/NP^(3)_(ST)nanoassemblies have extended blood circulation time,specifically accumulate in atherosclerotic plaque mediated by the HA receptors CD44 highly expressed in injured endothelium,rapidly disassemble in response to excess ROS in the intimal and release smaller NP^(3)_(ST),allowing for further plaque penetration,macrophage-targeted cholesterol efflux and drug delivery.In vivo pharmacodynamicses in atherosclerotic mice shows that HA-Fc/NP^(3)_(ST)reduces plaque size by 53%,plaque lipid deposition by 63%,plaque macrophage content by 62%and local inflammatory factor level by 64%compared to the saline group.Meanwhile,HA-Fc/NP^(3)_(ST)alleviates systemic inflammation characterized by reduced serum inflammatory factor levels.Collectively,HA-Fc/NP^(3)_(ST)nanoassemblies with ROS-responsive and size-reducible properties exhibit a deeper penetration in atherosclerotic plaque and enhanced macrophage targeting ability,thus exerting effective cholesterol efflux and drug delivery for atherosclerosis therapy.
基金We are grateful for financial support from the US National Science Foundation (NSF) (CAREER program and No. DMR-0706431), US Department of Defense (DoD) (No. W911NF-09-1-0236), the Alfred P. Sloan Scholarship, the Camille Dreyfus Teacher-Scholar Award, DoD-Army Research Office (ARO), and the W. M. Keck Foundation. We are also indebted to Dr. Udai Singh for assistance with flow cytometry and Laying Wu for TEM and SEM analyses.
文摘Poly(caprolactone-b-2-vinylpyridine) (PCL-P2VP) coated with folate-conjugated M13 (FA-M13) provides a nanosized delivery system which is capable of encapsulating hydrophobic antitumor drugs such as doxorubicin (DOX). The DOXqoaded FA-M13-PCL-P2VP assemblies had an average diameter of approximately 200 nm and their structure was characterized using transmission electron microscopy, scanning electron microscopy, and dynamic light scattering. The particles were stable at physiological pH but could be degraded at a lower pH. The release of DOX from the nanoassemblies under acidic conditions was shown to be significantly faster than that observed at physiological pH. In addition, the DOX-loaded FA-M13-PCL-P2VP particles showed a distinctly greater cellular uptake and cytotoxicity against folate-receptor-positive cancer cells than folate-receptor-negative cells, indicating that the receptor facilitates folate uptake via receptor-mediated endocytosis. Furthermore, the DOX-loaded particles also had a significantly higher tumor uptake and selectivity compared to free DOX. This study therefore offers a new way to fabricate nanosized drug delivery vehicles.
文摘Controllable self-assembly of noble metal nanocrystals is of broad interest for the development of highly active electrocatalysts. Here we report an efficient arginine-mediated hydrothermal approach for the high-yield synthesis of cube-like Pt nanoassemblies (Pt-CNAs) with porous cavities and rough surfaces based on the self-assembly of zero dimensional Pt nanocrystals. In this process, arginine acts as the reductant, structure directing agent, and linker between adjacent nanocrystals. Interestingly, the Pt-CNAs exhibit single-crystal structures with dominant {100} facets, as evidenced by X-ray diffraction. Based on electrocatalytic studies, the as-synthesized Pt-CNAs exhibit improved electrocatalytic activity as well as good stability and CO tolerance in the methanol oxidation reaction. The Pt-CNA's good performance is attributed to their unique morphology and surface structure. We believe that the synthetic strategy outlined here could be extended to other rationally designed monometallic or bimetallic nanoassemblies for use in high performance fuel cells.
基金the National Key Research and Development(R&D)Program of China(No.2021YFB3800900)the Natural Science Foundation of China(Nos.51725303,21708031,and 52033007)+3 种基金the National Postdoctoral Program for Innovative Talents(No.BX20180264)China Postdoctoral Science Foundation(No.2018M643519)the Sichuan Science and Technology Program(No.2020JDRC0051)the Fundamental Research Funds for the Central Universities(No.2682021ZTPY075)。
文摘The practical application of nanomedicines for cancer therapy is generally hampered by their compromised tumor accumulation and transmembrane potency.Cell penetrating peptides(CPPs)have been widely used to enhance the drug delivery efficiency in tumor cells.However,conventional CPPs are vulnerable towards proteases and are generally lack of therapeutic effects.To maximize the efficacy of nanomedicines,new classes of cell penetrating therapeutic modalities are highly desirable.Stapled peptides have drawn wide attention as one of the cell-permeable peptidomimetics for intracellular targets.Herein,we reported a novel approach for enhancing the therapeutic efficacy of chemo-photothermal therapy by taking advantage of the robust cell permeability and therapeutic effects of stapled peptides.The designed pH-activatable lactam-stapled peptide-polymer conjugate formed supramolecular nanoassemblies to encapsulate the chemodrug doxorubicin(DOX).Once reaching the tumor site,the lactam-stapled proapoptotic peptide could be efficiently activated under acidic tumor microenvironment,thereby promoting the drug delivery to the tumor cells and specific targeting mitochondria to interfere with the energy metabolism of tumor cells,which works in synergy with the DOX and local hyperthermia upon near infrared ray(NIR)light irradiation.This work may benefit future design of stapled peptides-based stimuli-responsive nanoplatforms for enhanced cancer therapy.
基金This work was funded by the National Key Research and Development Program of China(Nos.2022YFB3203804,2022YFB3203801,and 2022YFB3203800)the Leading Talent of“Ten Thousand Plan”-National High-Level Talents Special Support Plan,National Natural Science Foundation of China(Nos.32071374 and 32000985)+4 种基金Program of Shanghai Academic Research Leader under the Science and Technology Innovation Action Plan(No.21XD1422100)Program of Shanghai Science and Technology Development(No.22TS1400700)Zhejiang Provincial Natural Science Foundation of China(Nos.LR22C100001 and LQ21H300003)Innovative Research Team of High-Level Local Universities in Shanghai(No.SHSMUZDCX20210900)CAS Interdisciplinary Innovation Team(No.JCTD-2020-08)。
文摘Photoimmunotherapy(PIT)is an emerging therapeutic approach that integrates phototherapy and immunotherapy to eliminate primary tumors under an appropriate dosage of local light irradiation,while simultaneously preventing tumor metastasis and recurrence by activating the host antitumor immune response.Tumor-responsive dynamic nanoassemblies(TDNs)have evolved from being a mere curiosity to a promising platform for high-performance PIT.However,the dynamic nano-bio interaction between TDNs and tumor microenvironment remains poorly understood,which shall be critical for precise control of TDNs assembling/disassembling behavior and superior PIT efficacy.To deepen the understanding of the structure–function relationship of TDNs,this review introduces the rational design,nano-bio interactions,and controllable functionalities of cutting-edge TDNs for enhanced PIT.Moreover,the synergetic mechanism between TDNs-based PIT and immunomodulatory agents-mediated immunomodulation is particularly emphasized.Finally,the challenges and future perspectives in this emerging field are assessed.
