Semiconducting conjugated polymer nanoparticles(SPNs)represent an emerging class of phototheranostic materi-als with great promise for cancer treatment.In this report,low-bandgap electron donoracceptor(DA)-conjugated ...Semiconducting conjugated polymer nanoparticles(SPNs)represent an emerging class of phototheranostic materi-als with great promise for cancer treatment.In this report,low-bandgap electron donoracceptor(DA)-conjugated SPNs with sur-face cloaked by red blood cell membrane(RBCM)are developed for highly e ective photoacoustic imaging and photothermal therapy.The resulting RBCM-coated SPN(SPN@RBCM)displays remarkable near-infrared light absorption and good photosta-bility,as well as high photothermal conver-sion e ciency for photoacoustic imaging and photothermal therapy.Particularly,due to the small size(<5 nm),SPN@RBCM has the advantages of deep tumor penetration and rapid clearance from the body with no appreciable toxicity.The RBCM endows the SPNs with prolonged systematic circulation time,less reticuloendothelial system uptake and reduced immune-recognition,hence improving tumor accumulation after intravenous injection,which provides strong photoacoustic signals and exerts excellent photothermal therapeutic e ects.Thus,this work provides a valuable paradigm for safe and highly e cient tumor pho-toacoustic imaging and photothermal therapy for further clinical translation.展开更多
Plasmonic nanostructure-mediated photothermal therapy(PTT) has proven to be a promising approach for cancer treatment,and new approaches for its effective delivery to tumor lesions are currently being developed.This s...Plasmonic nanostructure-mediated photothermal therapy(PTT) has proven to be a promising approach for cancer treatment,and new approaches for its effective delivery to tumor lesions are currently being developed.This study aimed to assess macrophage-mediated delivery of PTT using radioiodine-124-labeled gold nanoparticles with crushed gold shells(124I-Au@AuCBs) as a theranostic nanoplatform.124I-Au@AuCBs exhibited effective photothermal conversion effects both in vitro and in vivo and were efficiently taken up by macrophages without cytotoxicity.After the administration of 124I-Au@AuCB-labeled macrophages to colon tumors,intensive signals were observed at tumor lesions,and subsequent in vivo PTT with laser irradiation yielded potent antitumor effects.The results indicate the considerable potential of 124I-Au@AuCBs as novel theranostic nanomaterials and the prominent advantages of macrophage-mediated cellular therapies in treating cancer and other diseases.展开更多
Photothermal cancer therapy is an alternative to chemotherapy, radiotherapy, and surgery. With the development of nanophotothermal agents, this therapy holds immense potential in clinical translation. However, the tox...Photothermal cancer therapy is an alternative to chemotherapy, radiotherapy, and surgery. With the development of nanophotothermal agents, this therapy holds immense potential in clinical translation. However, the toxicity issues derived from the fact that nanomaterials are trapped and retained in the reticuloendothelial systems limit their biomedical application.Developing biodegradable photothermal agents is the most practical route to address these concerns. In addition to the physicochemical properties of nanomaterials, various internal and external stimuli play key roles on nanomaterials uptake,transport, and clearance. In this review, we summarized novel nanoplatforms for photothermal therapy; these nanoplatforms can elicit stimuli-triggered degradation. We focused on the recent innovative designs endowed with biodegradable photothermal agents under different stimuli, including enzyme, p H, and near-infrared(NIR) laser.展开更多
Tumor lymph node(LN)metastasis seriously affects the treatment prognosis.Studies have shown that nanoparticles with size of sub-50 nm can directly penetrate into LN metastases after intravenous administration.Here,we ...Tumor lymph node(LN)metastasis seriously affects the treatment prognosis.Studies have shown that nanoparticles with size of sub-50 nm can directly penetrate into LN metastases after intravenous administration.Here,we speculate through introducing targeting capacity,the nanoparticle accumulation in LN metastases would be further enhanced for improved local treatment such as photothermal therapy.Trastuzumabtargeted micelles(<50 nm)were formulated using a unique surfactantstripping approach that yielded concentrated phthalocyanines with strong near-infrared absorption.Targeted micellar phthalocyanine(T-MP)was an effective photothermal transducer and ablated HT-29 cells in vitro.A HER2-expressing colorectal cancer cell line(HT-29)was used to establish an orthotopic mouse model that developed metastatic disease in mesenteric sentinel LN.T-MP accumulated more in the LN metastases compared to the micelles conjugated with control IgG.Following surgical resection of the primary tumor,minimally invasive photothermal treatment of the metastatic LN with T-MP,but not the control micelles,extended mouse survival.Our findings demonstrate for the first time that targeted small-sized nanoparticles have potential to enable superior paradigms for dealing with LN metastases.展开更多
Photothermal therapy(PTT)using near-infrared(NIR)light for tumor treatment has triggered extensive attentions because of its advantages of noninvasion and convenience.The current research on PTT usually uses lasers in...Photothermal therapy(PTT)using near-infrared(NIR)light for tumor treatment has triggered extensive attentions because of its advantages of noninvasion and convenience.The current research on PTT usually uses lasers in the first NIR window(NIR-I;700–900 nm)as irradiation source.However,the second NIR window(NIR-II;1000–1700 nm)especially NIRIIa window(1300–1400 nm)is considered much more promising in diagnosis and treatment as its superiority in penetration depth and maximum permissible exposure over NIR-I window.Hereby,we propose the use of laser excitation at 1275 nm,which is approved by Food and Drug Administration for physical therapy,as an attractive technique for PTT to balance of tissue absorption and scattering with water absorption.Specifically,CuS-PEG nanoparticles with similar absorption values at 1275 and 808 nm,a conventional NIR-I window for PTT,were synthesized as PTT agents and a comparison platform,to explore the potential of 1275 and 808 nm lasers for PTT,especially in deep-tissue settings.The results showed that 1275 nm laser was practicable in PTT.It exhibited much more desirable outcomes in cell ablation in vitro and deep-tissue antitumor capabilities in vivo compared to that of 808 nm laser.NIR-IIa laser illumination is superior to NIR-I laser for deep-tissue PTT,and shows high potential to improve the PTT outcome.展开更多
Melanins(eumelanin,pheomelanin,and allomelanin)represent a very,if not themost,important group of biological pigments.Their biological roles are multiple,from photoprotection to antioxidant activity,heavy metal dispos...Melanins(eumelanin,pheomelanin,and allomelanin)represent a very,if not themost,important group of biological pigments.Their biological roles are multiple,from photoprotection to antioxidant activity,heavy metal disposal or the myriad uses of color in organisms across all Phyla.In the first part of this review,eumelanin biology and some chemical aspects will be presented,as well as key physico-chemical features that make this biological pigment so interesting.The principal characteristics of the melanocyte,the melanin-synthesizing cell in mammals,will also be introduced.Transformed melanocytes are the cause of one of the most devastating known cancers:the malignant melanoma.Epidemiology and molecular signaling aspects will be presented next,as well as the principal advances in promising oncotherapies designed and applied for the treatment of melanoma.In particular,on account of the photo-physical properties of melanin,special details will be provided regarding the use of photothermal therapy for melanoma treatment.展开更多
Quite a great proportion of known tumor cells carry mutation in TP53 gene,expressing mutant p53 proteins(mutp53)missing not only original genome protective activities but also acquiring gain-of-functions that favor tu...Quite a great proportion of known tumor cells carry mutation in TP53 gene,expressing mutant p53 proteins(mutp53)missing not only original genome protective activities but also acquiring gain-of-functions that favor tumor progression and impede treatment of cancers.Zinc ions were reported as agents cytocidal to mutp53-carrying cells by recovering p53 normal functions and abrogating mutp53.Meanwhile in a hyperthermia scenario,the function of wild type p53 is required to ablate tumors upon heat treatment hence the effects might be hindered in a mutp53 background.We herein synthesized zinc-doped Prussian blue(ZP)nanoparticles(NPs)to combine Zn 2+based and photothermal therapeutic effects.An efficient release of Zn 2+in a glutathione-enriched tumor intracellular microenvironment and a prominent photothermal conversion manifested ZP NPs as zinc ion carriers and photothermal agents.Apoptotic death and autophagic mutp53 elimination were found to be induced by ZP NPs in R280K mutp53-containing MDA-MB-231 cells and hyperthermia was rendered to ameliorate the treatment in vitro through further mutp53 elimination and increased cell death.The combinatorial therapeutic effect was also confirmed in vivo in a mouse model.This study might expand zinc delivery carriers and shed a light on potential interplay of hyperthermia and mutp53 degradation in cancer treatment.展开更多
OBJECTIVE Plasmonic nanostructures act as a type of promising candidate for cancer photothermal therapy.These photothermal agents with good biocompatibility and high photothermal conversion efficiency are highly desir...OBJECTIVE Plasmonic nanostructures act as a type of promising candidate for cancer photothermal therapy.These photothermal agents with good biocompatibility and high photothermal conversion efficiency are highly desirable.In the present study,we synthesized poly(diallyldimethylammonium chloride)(PDDAC)coated porous platinum(Pt)nanoparticles for photothermal therapy.METHODS Biocompatibility and cellular uptake of Pt nanoparticles were studied in human glioblastoma U-87 MG cells.Cell viability was evaluated by ATP assay and calcein AM staining.The photothermal therapeutic effect of the Pt nanoparticles was studied under 808-nm laser irradiation.In addition,the synergistic anti-cancer effect of the Pt nanoparticle-based photothermal therapy and doxorubicinwas investigated.RESULTS The as-prepared Pt nanoparticles exhibited considerable photothermal conversion efficiency under 809 nm and 980 nm laser irradiation.In vitro study indicated that the Pt nanoparticles displayed good biocompatibility and high cellular uptake efficiency.In the presence of the Pt nanoparticles,808-nm laser irradiation at 8.4 W·cm-2for3 min induces significant cytotoxicity,and cell necrosis is involved in the photothermal injury.Furthermore,simultaneousapplication of photothermal therapy synergistically enhances the cytotoxicity of anticancer drug doxorubicin.CONCLUSION Therefore,PDADMAC-coated Pt nanoparticles will have great potential in cancer photothermal therapy.展开更多
Our study producted Polydopamine modified gold nanoflowers with controlled morphology for anti-tumor photothermal therapy.The branch structure containsabundant(Au NFs).By adjusting the reduction rate,the dosage of red...Our study producted Polydopamine modified gold nanoflowers with controlled morphology for anti-tumor photothermal therapy.The branch structure containsabundant(Au NFs).By adjusting the reduction rate,the dosage of reducing agent(sodium borohydride)and the reduction temperature,we can adjust tthe morphology and particle size of Au NFs.We found that the lower reaction temperature is,the more abundant the surface branching structure of gold nanoflowers is,by adjusting the reaction temperature.and the largest specific surface area of golden nanopowder was found at 0℃.The results of TEM indicated that with the increase of sodium borohydride,the diameter of gold nano flowers gold nanoflowers decreased and was in the range of 60~100nm,and it has good EPR effect After that,we modify poly(dopamine)(PDA)biomimetic layer on the surface of golden nanoparticles to obtain Au NFS@PDA.Poly(dopamine)has the ability,of photothermal conversion,which can enhance the plasma resonance ability and biocompatibility of gold nanoflowers in the near infrared region.We can control the thickness of polydopamine layer on the surface of gold nanoflowers between 7~15nm by adjusting dopamine DA concentrationgold nanoflowers.Au NFS@PDA was characterized by its morphology and physical properties.We detect(UV-Vis)spectra in the near infrared region.And it showed obvious absorption peaks in the near infrared region of 575~650nm.Under the 808nm irradiation laser,the photothermal conversion of gold nanoflowers and polydopamine can be rapidly increased to 57°C.Fourier Transform Infrared Absorption Spectroscopy(FTIR)and X-ray Diffraction(XRD)analysis showed that polydopamine was modified successfully,Au NFS@PDA and Au NFs had no obvious difference in crystal form.The cell viability test showed that the bionic Au NFS@PDA had good biocompatibility and showed good antitumor activity against HeLa cells under NIR irradiation.The cell viability was only 12%.Therefore,we can use Au NFS@PDA with good biocompatibility as a promising photothermal conversion agent in tumor therapy.展开更多
The study designed a polyacrylic acid(PAA)modified Fe3O4@MnO2 nanoparticles(Fe3O4@MnO2@PAA)for T1/T2 dualmode imaging.In addition,this nano-drug has pH response and anti-tumor photothermal therapy.First,using Fe3O4 as...The study designed a polyacrylic acid(PAA)modified Fe3O4@MnO2 nanoparticles(Fe3O4@MnO2@PAA)for T1/T2 dualmode imaging.In addition,this nano-drug has pH response and anti-tumor photothermal therapy.First,using Fe3O4 as the core can significantly reduce the signal of Fe3O4@MnO2@PAA nanoparticles.MnO2 nanoshells can be decomposed into paramagnetic Mn2+under the acidic environment in the tumor,which enhanced the T1 signal.The pH-responsive T1/T2 dual-mode magnetic resonance imaging(MRI)contrast agent had good sensitivity and specificity,providing more comprehensive and detailed information for tumor diagnosis.In addition,Fe3O4@MnO2@PAA nanoparticles showed excellent absorption capacity in the near-infrared region(NIR),which could be used as a good photothermal conversion material to mediate photothermal treatment of tumors.Therefore,the pHresponsive dual-mode MRI nanoparticle-mediated photothermal therapy showed good application potential in tumor treatment and diagnosis.展开更多
Recent research on photothermal therapy(PTT) has sparked significant interest in the development of new organic photothermal agents(PTAs),ranging from single-molecule to aggregated levels.However,controlling aggregati...Recent research on photothermal therapy(PTT) has sparked significant interest in the development of new organic photothermal agents(PTAs),ranging from single-molecule to aggregated levels.However,controlling aggregation pathways for PTAs with ultrahigh photothermal conversion efficiency(PCE) remains a major challenge.Herein,a two-pronged approach utilizing “Haggregation” and “intramolecular motion” was employed to enhance the PCE of an acceptor-substituted squaraine dye(NSQs).The C2vmolecular symmetry of the NSQs,which possess a ground state dipole moment(μg),promotes H-dimeric aggregates through dipole-dipole counteraction.Peripheral triphenylethylene or diphenylamine groups were added to this H-dimeric nanoplatform.This was done to enhance intramolecular motions for heat generation and also to extend conjugation,which redshifted the optical absorption and balanced the blue-shift induced by H-aggregation.With this technique,an organic PTA with NIR-II absorption was developed,and its nanoparticle achieved a remarkable PCE of 86.3% under 1,064 nm laser excitation.Femtosecond transient absorption spectroscopy and quantum mechanical calculations demonstrated the accelerated internal conversion process in NIR-II PTAs for rapid heat generation.The NSQs nanoparticles exhibit superior photothermal therapeutic properties for in vivo photoacoustic imaging-guided PTT,demonstrating the potential of bottom-up design to enable synergistic engineering strategies towards efficient phototheranostic agents.展开更多
Photothermal therapy(PTT)is a cutting-edge cancer treatment that can kill cancer cells in hypoxic environments without relying on oxygen.Seeking of the ideal photothermal agents with a high absorption coefficient in t...Photothermal therapy(PTT)is a cutting-edge cancer treatment that can kill cancer cells in hypoxic environments without relying on oxygen.Seeking of the ideal photothermal agents with a high absorption coefficient in the near-infrared region,and a high excellent photothermal conversion efficiency is of great significance.Sulfone-Rhodanmine dye has showed an impressive absorption wavelength over 700 nm,but suffered from a stability issue.In this study,we synthesized five sulfone rhodamines and investigated the substitution effects on stability.SO_(2)R2 showed high stability and strong absorbance at 714 nm with an excellent photothermal conversion efficiency of 53.06%,making it suitable for accurate photoacoustic imaging-guided photothermal therapy in vivo.展开更多
Photothermal therapy(PTT)has been widely used in the treatment of tumors,but its efficacy is greatly limited by the inability of precise drug delivery and the increase of heat shock proteins(HSPs)caused by high temper...Photothermal therapy(PTT)has been widely used in the treatment of tumors,but its efficacy is greatly limited by the inability of precise drug delivery and the increase of heat shock proteins(HSPs)caused by high temperature.This article describes a therapeutic strategy to enhance PTT with starvation therapy in conjunction with ferroptosis mechanism.A nanoparticle platform ZIF-8@GA was constructed by wrapping together glucose oxidase(GOX)and gold nanospheres(AuNPs)loaded with dihydroartemisinin(DHA)with zeolitic imidazolate framework-8(ZIF-8).This platform can take advantage of the micro-environment of osteosarcoma(OS)cells,featuring low pH and high reactive oxygen species(ROS),for precision drug delivery.GOX can effectively catalyze glucose to produce gluconic acid and H_(2)O_(2),and DHA can also induce ROS production in OS cells.ROS produced by GOX and DHA can further generate lipid peroxidation(LPO)and lead to ferroptosis of OS cells.At the same time,ROS and LPO produced can inhibit the expression of HSPs,thereby increasing the therapeutic effect of PTT.In vitro experiments show that the nanoparticles are pH and ROS responsive.1μg/mL GOX combined with 0.2μg/mL DHA promotes ferroptosis of OS cells,and increases the killing effect of near-infrared(NIR)on OS cells.Further in vivo experiments showed that the nano drug-delivery platform combined with PTT can effectively inhibit the growth of OS cells.Meanwhile,this study provides a new idea for the treatment of OS with biomaterials combined with various treatment methods.展开更多
Plasmonic metal nanomaterials with intrinsic surface–enhanced Raman scattering(SERS)and photothermal properties,especially AuAg nanoalloys with both the outstanding merits of Au and Ag nanocrystals,show huge applicat...Plasmonic metal nanomaterials with intrinsic surface–enhanced Raman scattering(SERS)and photothermal properties,especially AuAg nanoalloys with both the outstanding merits of Au and Ag nanocrystals,show huge application prospects in bacterial theranostics.However,the direct exposure of AuAg nanoalloys in external conditions probably cause undesirable reactions and poisonous metal ion leakage during SERS detection and photothermal antibacterial therapy process,which severely hinder bacterial theranostics applications.Herein,we report an ultrastable graphene–isolated AuAg nanoalloy(GAA)with AuAg core confined in few–layer graphitic shell as a versatile platform for bacterial detection and therapy.The encapsulation of graphene ensures the good stability of AuAg core,that its superior SERS and photothermal properties are therefore further guaranteed.GAA is used for SERS detection of two vital bacterial biomarkers(including corrosive cyanide and pyocyanin),exhibiting good SERS quantitative and multiplexing ability.GAA is further used for photothermal antibacterial therapy application,and ultrahigh antibacterial efficacies for both Gram–negative Escherichia coli and Gram–positive Staphylococcus aureus are achieved under 808 nm laser irradiation.This work proposes a valuable method to develop robust bacterial theranostic platform.展开更多
Biofilms are closely associated with the tough healing and dysfunctional inflammation of chronic wounds.Photothermal therapy(PTT)emerged as a suitable alternative which could destroy the structure of biofilms with loc...Biofilms are closely associated with the tough healing and dysfunctional inflammation of chronic wounds.Photothermal therapy(PTT)emerged as a suitable alternative which could destroy the structure of biofilms with local physical heat.However,the efficacy of PTT is limited because the excessive hyperthermia could damage surrounding tissues.Besides,the difficult reserve and delivery of photothermal agents makes PTT hard to eradicate biofilms as expectation.Herein,we present a GelMA-EGF/Gelatin-MPDA-LZM bilayer hydrogel dressing to perform lysozyme-enhanced PTT for biofilms eradication and a further acceleration to the repair of chronic wounds.Gelatin was used as inner layer hydrogel to reserve lysozyme(LZM)loaded mesoporous polydopamine(MPDA)(MPDA-LZM)nanoparticles,which could rapidly liquefy while temperature rising so as to achieve a bulk release of nanoparticles.MPDA-LZM nanoparticles serve as photothermal agents with antibacterial capability,could deeply penetrate and destroy biofilms.In addition,the outer layer hydrogel consisted of gelatin methacryloyl(GelMA)and epidermal growth factor(EGF)promoted wound healing and tissue regeneration.It displayed remarkable efficacy on alleviating infection and accelerating wound healing in vivo.Overall,the innovative therapeutic strategy we came up with has significant effect on biofilms eradication and shows promising application in promoting the repair of clinical chronic wounds.展开更多
Tumor hypoxia is intimately associated with gliomas,which represents a significant threat to human health and are resistant to the first-line chemotherapeutic drug temozolomide(TMZ)due to hypoxia.In this work,to overc...Tumor hypoxia is intimately associated with gliomas,which represents a significant threat to human health and are resistant to the first-line chemotherapeutic drug temozolomide(TMZ)due to hypoxia.In this work,to overcome TMZ resistance in orthotopic gliomas,aptamer-functionalized liposomes are manufactured to encapsulate TMZ and photothermal agent IR780,and can cross the blood-brain barrier and actively target gliomas.It is possible to employ liposomes for both fluorescence and photoacoustic imaging simultaneously due to their stability and excellent photothermal conversion capabilities.This chemo/photothermal synergistic therapeutic effect of liposomes on gliomas is demonstrated by their abilities to target orthotopic gliomas,alleviate tumor hypoxia and consequently reverse resistance of glioma cells to TMZ,thereby extending the survival time of tumor-bearing mice,making the nanoplatforms and their synergistic chemo/photothermal therapy as a potential clinical treatment for gliomas.展开更多
Stanene,the two-dimensional form of elemental tin(Sn),is easily oxidized in the ambient environ-ment,significantly hindering its applications in biomedical fields.However,the degradation mechanism of stanene remains u...Stanene,the two-dimensional form of elemental tin(Sn),is easily oxidized in the ambient environ-ment,significantly hindering its applications in biomedical fields.However,the degradation mechanism of stanene remains unclear.Herein,combined DFT calculations and proof-of-concept experiments were conducted to elucidate the underlying degradation mechanism of stanene.The results reveal that the degradation of stanene in an oxygenated water environment is a water-accelerated oxidation process.H_(2) O molecules could not only facilitate the electron transfer from stanene to O_(2) because of the polarization effect of H_(2) O,but also directly react with the defect sites of stanene due to enhanced absorption energy.Moreover,several protective strategies like alcohol protection were proposed to avoid or mitigate the oxidation of stanene for further applications.Finally,stanene was explored as the second near-infrared(NIR-II)photonic agents for ablation of 4T1 tumor,depicting a tumor-growth inhibition ratio up to 96.7%,much better than that of the first near-infrared(NIR-I)group(65.5%).This work reveals the degradation mechanism of stanene and demonstrates its biomedical applications in the NIR-II region.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.61727823,51873160)the joint research project of Health and Education Commission of Fujian Province(Grant No.2019-WJ-20).
文摘Semiconducting conjugated polymer nanoparticles(SPNs)represent an emerging class of phototheranostic materi-als with great promise for cancer treatment.In this report,low-bandgap electron donoracceptor(DA)-conjugated SPNs with sur-face cloaked by red blood cell membrane(RBCM)are developed for highly e ective photoacoustic imaging and photothermal therapy.The resulting RBCM-coated SPN(SPN@RBCM)displays remarkable near-infrared light absorption and good photosta-bility,as well as high photothermal conver-sion e ciency for photoacoustic imaging and photothermal therapy.Particularly,due to the small size(<5 nm),SPN@RBCM has the advantages of deep tumor penetration and rapid clearance from the body with no appreciable toxicity.The RBCM endows the SPNs with prolonged systematic circulation time,less reticuloendothelial system uptake and reduced immune-recognition,hence improving tumor accumulation after intravenous injection,which provides strong photoacoustic signals and exerts excellent photothermal therapeutic e ects.Thus,this work provides a valuable paradigm for safe and highly e cient tumor pho-toacoustic imaging and photothermal therapy for further clinical translation.
基金supported by National Research Foundation of Korea(NRF) grants funded by the Korea Government(MSIP)a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute(KHIDI) funded by the Ministry of Health&Welfare,Republic of Korea(HI16C1501)+1 种基金a grant from the Medical Cluster R&D Support Project through the Daegu-Gyeongbuk Medical Innovation Foundation(DGMIF) funded by the Ministry of Health and Welfare(HT16C0001,HT16C0002,HT17C0009)a National Research Foundation of Korea(NRF) Grant funded by the Korea Government(MSIP)(2014R1A1A1003323,2017R1D1A1B03028340,2018R1D1AB07047417)
文摘Plasmonic nanostructure-mediated photothermal therapy(PTT) has proven to be a promising approach for cancer treatment,and new approaches for its effective delivery to tumor lesions are currently being developed.This study aimed to assess macrophage-mediated delivery of PTT using radioiodine-124-labeled gold nanoparticles with crushed gold shells(124I-Au@AuCBs) as a theranostic nanoplatform.124I-Au@AuCBs exhibited effective photothermal conversion effects both in vitro and in vivo and were efficiently taken up by macrophages without cytotoxicity.After the administration of 124I-Au@AuCB-labeled macrophages to colon tumors,intensive signals were observed at tumor lesions,and subsequent in vivo PTT with laser irradiation yielded potent antitumor effects.The results indicate the considerable potential of 124I-Au@AuCBs as novel theranostic nanomaterials and the prominent advantages of macrophage-mediated cellular therapies in treating cancer and other diseases.
文摘Photothermal cancer therapy is an alternative to chemotherapy, radiotherapy, and surgery. With the development of nanophotothermal agents, this therapy holds immense potential in clinical translation. However, the toxicity issues derived from the fact that nanomaterials are trapped and retained in the reticuloendothelial systems limit their biomedical application.Developing biodegradable photothermal agents is the most practical route to address these concerns. In addition to the physicochemical properties of nanomaterials, various internal and external stimuli play key roles on nanomaterials uptake,transport, and clearance. In this review, we summarized novel nanoplatforms for photothermal therapy; these nanoplatforms can elicit stimuli-triggered degradation. We focused on the recent innovative designs endowed with biodegradable photothermal agents under different stimuli, including enzyme, p H, and near-infrared(NIR) laser.
基金Hai-Yi Feng and Yihang Yuan contributed equally to this work.We thank Prof.Gang Zheng(University of Toronto)for valuable discussion.We also thank the Core Facility of Basic Medical Sciences(SJTU-SM)for frozen section making and scanningThis work was supported by National Natural Science Foundation of China(81572998,81773274,82073379)+1 种基金Shanghai Municipal Science and Technology Commission(20ZR1451700,16520710700)Shanghai Collaborative Innovation Center for Translational Medicine(TM201731).
文摘Tumor lymph node(LN)metastasis seriously affects the treatment prognosis.Studies have shown that nanoparticles with size of sub-50 nm can directly penetrate into LN metastases after intravenous administration.Here,we speculate through introducing targeting capacity,the nanoparticle accumulation in LN metastases would be further enhanced for improved local treatment such as photothermal therapy.Trastuzumabtargeted micelles(<50 nm)were formulated using a unique surfactantstripping approach that yielded concentrated phthalocyanines with strong near-infrared absorption.Targeted micellar phthalocyanine(T-MP)was an effective photothermal transducer and ablated HT-29 cells in vitro.A HER2-expressing colorectal cancer cell line(HT-29)was used to establish an orthotopic mouse model that developed metastatic disease in mesenteric sentinel LN.T-MP accumulated more in the LN metastases compared to the micelles conjugated with control IgG.Following surgical resection of the primary tumor,minimally invasive photothermal treatment of the metastatic LN with T-MP,but not the control micelles,extended mouse survival.Our findings demonstrate for the first time that targeted small-sized nanoparticles have potential to enable superior paradigms for dealing with LN metastases.
基金supported,in part,by the Natural Science Foundation of China (Nos.81402043 and 81201141)the Clinical Capability Construction Project for Liaoning Provincial Hospitals (LNCCC-D50-2015+1 种基金LNCCC-C09-2015)the China postdoctoral science foundation Grant (2016T90233)
文摘Photothermal therapy(PTT)using near-infrared(NIR)light for tumor treatment has triggered extensive attentions because of its advantages of noninvasion and convenience.The current research on PTT usually uses lasers in the first NIR window(NIR-I;700–900 nm)as irradiation source.However,the second NIR window(NIR-II;1000–1700 nm)especially NIRIIa window(1300–1400 nm)is considered much more promising in diagnosis and treatment as its superiority in penetration depth and maximum permissible exposure over NIR-I window.Hereby,we propose the use of laser excitation at 1275 nm,which is approved by Food and Drug Administration for physical therapy,as an attractive technique for PTT to balance of tissue absorption and scattering with water absorption.Specifically,CuS-PEG nanoparticles with similar absorption values at 1275 and 808 nm,a conventional NIR-I window for PTT,were synthesized as PTT agents and a comparison platform,to explore the potential of 1275 and 808 nm lasers for PTT,especially in deep-tissue settings.The results showed that 1275 nm laser was practicable in PTT.It exhibited much more desirable outcomes in cell ablation in vitro and deep-tissue antitumor capabilities in vivo compared to that of 808 nm laser.NIR-IIa laser illumination is superior to NIR-I laser for deep-tissue PTT,and shows high potential to improve the PTT outcome.
文摘Melanins(eumelanin,pheomelanin,and allomelanin)represent a very,if not themost,important group of biological pigments.Their biological roles are multiple,from photoprotection to antioxidant activity,heavy metal disposal or the myriad uses of color in organisms across all Phyla.In the first part of this review,eumelanin biology and some chemical aspects will be presented,as well as key physico-chemical features that make this biological pigment so interesting.The principal characteristics of the melanocyte,the melanin-synthesizing cell in mammals,will also be introduced.Transformed melanocytes are the cause of one of the most devastating known cancers:the malignant melanoma.Epidemiology and molecular signaling aspects will be presented next,as well as the principal advances in promising oncotherapies designed and applied for the treatment of melanoma.In particular,on account of the photo-physical properties of melanin,special details will be provided regarding the use of photothermal therapy for melanoma treatment.
基金by the National Natural Science Foundation of China(No.81772278).
文摘Quite a great proportion of known tumor cells carry mutation in TP53 gene,expressing mutant p53 proteins(mutp53)missing not only original genome protective activities but also acquiring gain-of-functions that favor tumor progression and impede treatment of cancers.Zinc ions were reported as agents cytocidal to mutp53-carrying cells by recovering p53 normal functions and abrogating mutp53.Meanwhile in a hyperthermia scenario,the function of wild type p53 is required to ablate tumors upon heat treatment hence the effects might be hindered in a mutp53 background.We herein synthesized zinc-doped Prussian blue(ZP)nanoparticles(NPs)to combine Zn 2+based and photothermal therapeutic effects.An efficient release of Zn 2+in a glutathione-enriched tumor intracellular microenvironment and a prominent photothermal conversion manifested ZP NPs as zinc ion carriers and photothermal agents.Apoptotic death and autophagic mutp53 elimination were found to be induced by ZP NPs in R280K mutp53-containing MDA-MB-231 cells and hyperthermia was rendered to ameliorate the treatment in vitro through further mutp53 elimination and increased cell death.The combinatorial therapeutic effect was also confirmed in vivo in a mouse model.This study might expand zinc delivery carriers and shed a light on potential interplay of hyperthermia and mutp53 degradation in cancer treatment.
基金The project supported by the Macao Science and Technology Development Fund(FDCT)(014/2014/A1)
文摘OBJECTIVE Plasmonic nanostructures act as a type of promising candidate for cancer photothermal therapy.These photothermal agents with good biocompatibility and high photothermal conversion efficiency are highly desirable.In the present study,we synthesized poly(diallyldimethylammonium chloride)(PDDAC)coated porous platinum(Pt)nanoparticles for photothermal therapy.METHODS Biocompatibility and cellular uptake of Pt nanoparticles were studied in human glioblastoma U-87 MG cells.Cell viability was evaluated by ATP assay and calcein AM staining.The photothermal therapeutic effect of the Pt nanoparticles was studied under 808-nm laser irradiation.In addition,the synergistic anti-cancer effect of the Pt nanoparticle-based photothermal therapy and doxorubicinwas investigated.RESULTS The as-prepared Pt nanoparticles exhibited considerable photothermal conversion efficiency under 809 nm and 980 nm laser irradiation.In vitro study indicated that the Pt nanoparticles displayed good biocompatibility and high cellular uptake efficiency.In the presence of the Pt nanoparticles,808-nm laser irradiation at 8.4 W·cm-2for3 min induces significant cytotoxicity,and cell necrosis is involved in the photothermal injury.Furthermore,simultaneousapplication of photothermal therapy synergistically enhances the cytotoxicity of anticancer drug doxorubicin.CONCLUSION Therefore,PDADMAC-coated Pt nanoparticles will have great potential in cancer photothermal therapy.
文摘Our study producted Polydopamine modified gold nanoflowers with controlled morphology for anti-tumor photothermal therapy.The branch structure containsabundant(Au NFs).By adjusting the reduction rate,the dosage of reducing agent(sodium borohydride)and the reduction temperature,we can adjust tthe morphology and particle size of Au NFs.We found that the lower reaction temperature is,the more abundant the surface branching structure of gold nanoflowers is,by adjusting the reaction temperature.and the largest specific surface area of golden nanopowder was found at 0℃.The results of TEM indicated that with the increase of sodium borohydride,the diameter of gold nano flowers gold nanoflowers decreased and was in the range of 60~100nm,and it has good EPR effect After that,we modify poly(dopamine)(PDA)biomimetic layer on the surface of golden nanoparticles to obtain Au NFS@PDA.Poly(dopamine)has the ability,of photothermal conversion,which can enhance the plasma resonance ability and biocompatibility of gold nanoflowers in the near infrared region.We can control the thickness of polydopamine layer on the surface of gold nanoflowers between 7~15nm by adjusting dopamine DA concentrationgold nanoflowers.Au NFS@PDA was characterized by its morphology and physical properties.We detect(UV-Vis)spectra in the near infrared region.And it showed obvious absorption peaks in the near infrared region of 575~650nm.Under the 808nm irradiation laser,the photothermal conversion of gold nanoflowers and polydopamine can be rapidly increased to 57°C.Fourier Transform Infrared Absorption Spectroscopy(FTIR)and X-ray Diffraction(XRD)analysis showed that polydopamine was modified successfully,Au NFS@PDA and Au NFs had no obvious difference in crystal form.The cell viability test showed that the bionic Au NFS@PDA had good biocompatibility and showed good antitumor activity against HeLa cells under NIR irradiation.The cell viability was only 12%.Therefore,we can use Au NFS@PDA with good biocompatibility as a promising photothermal conversion agent in tumor therapy.
文摘The study designed a polyacrylic acid(PAA)modified Fe3O4@MnO2 nanoparticles(Fe3O4@MnO2@PAA)for T1/T2 dualmode imaging.In addition,this nano-drug has pH response and anti-tumor photothermal therapy.First,using Fe3O4 as the core can significantly reduce the signal of Fe3O4@MnO2@PAA nanoparticles.MnO2 nanoshells can be decomposed into paramagnetic Mn2+under the acidic environment in the tumor,which enhanced the T1 signal.The pH-responsive T1/T2 dual-mode magnetic resonance imaging(MRI)contrast agent had good sensitivity and specificity,providing more comprehensive and detailed information for tumor diagnosis.In addition,Fe3O4@MnO2@PAA nanoparticles showed excellent absorption capacity in the near-infrared region(NIR),which could be used as a good photothermal conversion material to mediate photothermal treatment of tumors.Therefore,the pHresponsive dual-mode MRI nanoparticle-mediated photothermal therapy showed good application potential in tumor treatment and diagnosis.
基金supported by the National Natural Science Foundation of China (22063005)the Natural Science Foundation of Jiangxi Province (20212ACBA203012,20224BAB214003,20232BAB-203031)the Interdisciplinary Innovation Fund of Natural Science,Nanchang University (9167-27060003-ZD2101,9167-28220007-YB2113)。
文摘Recent research on photothermal therapy(PTT) has sparked significant interest in the development of new organic photothermal agents(PTAs),ranging from single-molecule to aggregated levels.However,controlling aggregation pathways for PTAs with ultrahigh photothermal conversion efficiency(PCE) remains a major challenge.Herein,a two-pronged approach utilizing “Haggregation” and “intramolecular motion” was employed to enhance the PCE of an acceptor-substituted squaraine dye(NSQs).The C2vmolecular symmetry of the NSQs,which possess a ground state dipole moment(μg),promotes H-dimeric aggregates through dipole-dipole counteraction.Peripheral triphenylethylene or diphenylamine groups were added to this H-dimeric nanoplatform.This was done to enhance intramolecular motions for heat generation and also to extend conjugation,which redshifted the optical absorption and balanced the blue-shift induced by H-aggregation.With this technique,an organic PTA with NIR-II absorption was developed,and its nanoparticle achieved a remarkable PCE of 86.3% under 1,064 nm laser excitation.Femtosecond transient absorption spectroscopy and quantum mechanical calculations demonstrated the accelerated internal conversion process in NIR-II PTAs for rapid heat generation.The NSQs nanoparticles exhibit superior photothermal therapeutic properties for in vivo photoacoustic imaging-guided PTT,demonstrating the potential of bottom-up design to enable synergistic engineering strategies towards efficient phototheranostic agents.
基金the National Natural Science Foundation of China(Nos.21762045,21911540466)Shandong Provincial Natural Science Foundation(No.ZR2019YQ12)+1 种基金China Postdoctoral Science Foundation(No.219M652306)Taishan Scholar Project(No.tsqn201812049)for supporting this work。
文摘Photothermal therapy(PTT)is a cutting-edge cancer treatment that can kill cancer cells in hypoxic environments without relying on oxygen.Seeking of the ideal photothermal agents with a high absorption coefficient in the near-infrared region,and a high excellent photothermal conversion efficiency is of great significance.Sulfone-Rhodanmine dye has showed an impressive absorption wavelength over 700 nm,but suffered from a stability issue.In this study,we synthesized five sulfone rhodamines and investigated the substitution effects on stability.SO_(2)R2 showed high stability and strong absorbance at 714 nm with an excellent photothermal conversion efficiency of 53.06%,making it suitable for accurate photoacoustic imaging-guided photothermal therapy in vivo.
基金supported by the National Natural Science Foundation of China(No.82002363)Natural Science Foundation of Chongqing,China(No.cstc2020jcyj-msxmX0195).
文摘Photothermal therapy(PTT)has been widely used in the treatment of tumors,but its efficacy is greatly limited by the inability of precise drug delivery and the increase of heat shock proteins(HSPs)caused by high temperature.This article describes a therapeutic strategy to enhance PTT with starvation therapy in conjunction with ferroptosis mechanism.A nanoparticle platform ZIF-8@GA was constructed by wrapping together glucose oxidase(GOX)and gold nanospheres(AuNPs)loaded with dihydroartemisinin(DHA)with zeolitic imidazolate framework-8(ZIF-8).This platform can take advantage of the micro-environment of osteosarcoma(OS)cells,featuring low pH and high reactive oxygen species(ROS),for precision drug delivery.GOX can effectively catalyze glucose to produce gluconic acid and H_(2)O_(2),and DHA can also induce ROS production in OS cells.ROS produced by GOX and DHA can further generate lipid peroxidation(LPO)and lead to ferroptosis of OS cells.At the same time,ROS and LPO produced can inhibit the expression of HSPs,thereby increasing the therapeutic effect of PTT.In vitro experiments show that the nanoparticles are pH and ROS responsive.1μg/mL GOX combined with 0.2μg/mL DHA promotes ferroptosis of OS cells,and increases the killing effect of near-infrared(NIR)on OS cells.Further in vivo experiments showed that the nano drug-delivery platform combined with PTT can effectively inhibit the growth of OS cells.Meanwhile,this study provides a new idea for the treatment of OS with biomaterials combined with various treatment methods.
基金funding support from the National Key Research and Development Program of China(Nos.2022YFC2403501,2020YFA0210800)National Natural Science Foundation of China(No.22225401)+1 种基金Science and Technology Innovation Program of Hunan Province(No.2020RC4017)China Postdoctoral Science Foundation(No.2021M701145)。
文摘Plasmonic metal nanomaterials with intrinsic surface–enhanced Raman scattering(SERS)and photothermal properties,especially AuAg nanoalloys with both the outstanding merits of Au and Ag nanocrystals,show huge application prospects in bacterial theranostics.However,the direct exposure of AuAg nanoalloys in external conditions probably cause undesirable reactions and poisonous metal ion leakage during SERS detection and photothermal antibacterial therapy process,which severely hinder bacterial theranostics applications.Herein,we report an ultrastable graphene–isolated AuAg nanoalloy(GAA)with AuAg core confined in few–layer graphitic shell as a versatile platform for bacterial detection and therapy.The encapsulation of graphene ensures the good stability of AuAg core,that its superior SERS and photothermal properties are therefore further guaranteed.GAA is used for SERS detection of two vital bacterial biomarkers(including corrosive cyanide and pyocyanin),exhibiting good SERS quantitative and multiplexing ability.GAA is further used for photothermal antibacterial therapy application,and ultrahigh antibacterial efficacies for both Gram–negative Escherichia coli and Gram–positive Staphylococcus aureus are achieved under 808 nm laser irradiation.This work proposes a valuable method to develop robust bacterial theranostic platform.
基金supported by the National Natural Science Foundation of China(Nos.51773231,81572726,and 82102977)Science and Technology Planning Project of Shenzhen Municipality(JCYJ20190807160801664,China)。
文摘Biofilms are closely associated with the tough healing and dysfunctional inflammation of chronic wounds.Photothermal therapy(PTT)emerged as a suitable alternative which could destroy the structure of biofilms with local physical heat.However,the efficacy of PTT is limited because the excessive hyperthermia could damage surrounding tissues.Besides,the difficult reserve and delivery of photothermal agents makes PTT hard to eradicate biofilms as expectation.Herein,we present a GelMA-EGF/Gelatin-MPDA-LZM bilayer hydrogel dressing to perform lysozyme-enhanced PTT for biofilms eradication and a further acceleration to the repair of chronic wounds.Gelatin was used as inner layer hydrogel to reserve lysozyme(LZM)loaded mesoporous polydopamine(MPDA)(MPDA-LZM)nanoparticles,which could rapidly liquefy while temperature rising so as to achieve a bulk release of nanoparticles.MPDA-LZM nanoparticles serve as photothermal agents with antibacterial capability,could deeply penetrate and destroy biofilms.In addition,the outer layer hydrogel consisted of gelatin methacryloyl(GelMA)and epidermal growth factor(EGF)promoted wound healing and tissue regeneration.It displayed remarkable efficacy on alleviating infection and accelerating wound healing in vivo.Overall,the innovative therapeutic strategy we came up with has significant effect on biofilms eradication and shows promising application in promoting the repair of clinical chronic wounds.
基金This work was supported,in part,by the National Natural Science Foundation of China(Nos.32171173,32001074,and 82260473)the Key Research and Development Program in Ningxia Province of China(No.2022BEG03080)+6 种基金the Natural Science Basic Research Plan in Ningxia Province of China(No.2022AAC03522)the Health Commission of Ningxia Hui Autonomous Region Science and Technology Support Project for Quality Development of Medical Institutions(No.2023-NWKYT-019)the State Key Laboratory Grant of Space Medicine Fundamentals and Application(No.SMFA20A02)the Natural Science Basic Research Key Program of Shaanxi Province(No.2023-JC-ZD-53)the Natural Science Basic Research Plan in Shaanxi Province of China(No.2022JQ-201)the Fundamental Research Funds for the Central Universities(Nos.ZYTS23190 and xzy012022134)the Beijing Xisike Clinical Oncology Research Foundation.
文摘Tumor hypoxia is intimately associated with gliomas,which represents a significant threat to human health and are resistant to the first-line chemotherapeutic drug temozolomide(TMZ)due to hypoxia.In this work,to overcome TMZ resistance in orthotopic gliomas,aptamer-functionalized liposomes are manufactured to encapsulate TMZ and photothermal agent IR780,and can cross the blood-brain barrier and actively target gliomas.It is possible to employ liposomes for both fluorescence and photoacoustic imaging simultaneously due to their stability and excellent photothermal conversion capabilities.This chemo/photothermal synergistic therapeutic effect of liposomes on gliomas is demonstrated by their abilities to target orthotopic gliomas,alleviate tumor hypoxia and consequently reverse resistance of glioma cells to TMZ,thereby extending the survival time of tumor-bearing mice,making the nanoplatforms and their synergistic chemo/photothermal therapy as a potential clinical treatment for gliomas.
基金financially supported by the National Natural Sci-ence Foundation of China(No.52071120)the University Synergy Innovation Program of Anhui Province(Nos.GXXT-2019-045 and GXXT-2020-063)the Open Foundation of Shenzhen Bay Lab-oratory(No.SZBL2019062801005).
文摘Stanene,the two-dimensional form of elemental tin(Sn),is easily oxidized in the ambient environ-ment,significantly hindering its applications in biomedical fields.However,the degradation mechanism of stanene remains unclear.Herein,combined DFT calculations and proof-of-concept experiments were conducted to elucidate the underlying degradation mechanism of stanene.The results reveal that the degradation of stanene in an oxygenated water environment is a water-accelerated oxidation process.H_(2) O molecules could not only facilitate the electron transfer from stanene to O_(2) because of the polarization effect of H_(2) O,but also directly react with the defect sites of stanene due to enhanced absorption energy.Moreover,several protective strategies like alcohol protection were proposed to avoid or mitigate the oxidation of stanene for further applications.Finally,stanene was explored as the second near-infrared(NIR-II)photonic agents for ablation of 4T1 tumor,depicting a tumor-growth inhibition ratio up to 96.7%,much better than that of the first near-infrared(NIR-I)group(65.5%).This work reveals the degradation mechanism of stanene and demonstrates its biomedical applications in the NIR-II region.
