Self-assembled PEG-IR-780-C13 micelle as a targeting, safe and highly-effective photothermal agent for invivo imaging and cancer therapy

Biomaterials

Volumn 51, Issue , 2015, Pages 184-193

  Yuan, Ahu ^a   Qiu, Xuefeng ^a   Tang, Xiaolei ^a   Liu, Wei ^a   Wu, Jinhui ^a   Hu, Yiqiao ^a  

^a NANJING UNIVERSITY   (China)

Author keywords

Fluorescence; Micelle; NIR dye; Photothermal therapy; Tumor targeting

Indexed keywords

CARBON; COMPUTERIZED TOMOGRAPHY; FLUORESCENCE; HYDROPHOBICITY; INFRARED DEVICES; SOLUBILITY; TUMORS;

BIOLOGICAL APPLICATIONS; CELL VIABILITY ASSAYS; INTRAVENOUS ADMINISTRATION; INTRAVENOUS INJECTIONS; NEAR-INFRARED FLUORESCENCE; PHOTOTHERMAL THERAPY; STRUCTURAL MODIFICATIONS; TUMOR TARGETING;

MICELLES;

ADENOSINE DEAMINASE; ALANINE AMINOTRANSFERASE; ALBUMIN; ALKALINE PHOSPHATASE; ANTINEOPLASTIC AGENT; ASPARTATE AMINOTRANSFERASE; CARBON; CREATININE; FLUORESCENT DYE; GAMMA GLUTAMYLTRANSFERASE; IR 780; LACTATE DEHYDROGENASE; MACROGOL 2000; NANOCARRIER; UNCLASSIFIED DRUG; UREA; 2-(2-(2-CHLORO-3-((1,3-DIHYDRO-3,3-DIMETHYL-1-PROPYL-2H-INDOL-2-YLIDENE)ETHYLIDENE)-1-CYCLOHEXEN-1-YL)ETHENYL)-3,3-DIMETHYL-1-PROPYLINDOLIUM; INDOLE DERIVATIVE; MACROGOL DERIVATIVE; MICELLE; SOLUTION AND SOLUBILITY;

ANIMAL EXPERIMENT; ANIMAL MODEL; ANIMAL TISSUE; ARTICLE; CANCER THERAPY; CELL VIABILITY ASSAY; CONTROLLED STUDY; CRITICAL MICELLE CONCENTRATION; CYTOTOXICITY; DRUG SAFETY; DRUG SOLUBILITY; HYDROPHILICITY; IN VITRO STUDY; IN VIVO STUDY; LASER; LIVER FUNCTION; MALE; MICELLE; MORPHOLOGY; MOUSE; NONHUMAN; PARTICLE SIZE; PHOTOTHERAPY; PHOTOTHERMAL THERAPY; PRIORITY JOURNAL; PROTON NUCLEAR MAGNETIC RESONANCE; STATIC ELECTRICITY; THERAPY EFFECT; TUMOR XENOGRAFT; ZETA POTENTIAL; ANIMAL; BAGG ALBINO MOUSE; CELL DEATH; CHEMISTRY; DIAGNOSTIC IMAGING; DRUG EFFECTS; HYPERTHERMIC THERAPY; NEOPLASMS; SOLUTION AND SOLUBILITY; SYNTHESIS; TEMPERATURE; TISSUE DISTRIBUTION; TUMOR CELL LINE;

ANIMALS; CELL DEATH; CELL LINE, TUMOR; DIAGNOSTIC IMAGING; HYPERTHERMIA, INDUCED; INDOLES; MALE; MICE, INBRED BALB C; MICELLES; NEOPLASMS; PHOTOTHERAPY; POLYETHYLENE GLYCOLS; SOLUTIONS; TEMPERATURE; TISSUE DISTRIBUTION;

EID: 84924873034     PISSN: 01429612     EISSN: 18785905     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2015.01.069     Document Type: Article

References (39)

1. Lovell J.F., Jin C.S., Huynh E., Jin H., Kim C., Rubinstein J.L., et al. Porphysome nanovesicles generated by porphyrin bilayers for use as multimodal biophotonic contrast agents. Nat Mater 2011, 10:324-332.
2. Zhou J., Lu Z., Zhu X., Wang X., Liao Y., Ma Z., et al. NIR photothermal therapy using polyaniline nanoparticles. Biomaterials 2013, 34:9584-9592.
3. Zha Z., Yue X., Ren Q., Dai Z. Uniform polypyrrole nanoparticles with high photothermal conversion efficiency for photothermal ablation of cancer cells. Adv Mater 2013, 25:777-782.
4. 5 nanocrystals: a photothermal agent with a 25.7% heat conversion efficiency for photothermal ablation of cancer cells invivo. ACS Nano 2011, 5:9761-9771.
5. Zha Z., Wang J., Qu E., Zhang S., Jin Y., Wang S., et al. Polypyrrole hollow microspheres as echogenic photothermal agent for ultrasound imaging guided tumor ablation. Sci Reports 2013, 3:2360.
6. Ju E., Li Z., Li M., Dong K., Ren J., Qu X. Functional polypyrrole-silica composites as photothermal agents for targeted killing of bacteria. Chem Commun (Camb) 2013, 49:9048-9050.
7. 4 particles with extremely low toxicity as highly efficient near-infrared photothermal agents for invivo tumor ablation. Nanoscale 2013, 5:8056-8066.
8. Wang Y., Black K.C., Luehmann H., Li W., Zhang Y., Cai X., et al. Comparison study of gold nanohexapods, nanorods, and nanocages for photothermal cancer treatment. ACS Nano 2013, 7:2068-2077.
9. Chen R., Wang X., Yao X., Zheng X., Wang J., Jiang X. Near-IR-triggered photothermal/photodynamic dual-modality therapy system via chitosan hybrid nanospheres. Biomaterials 2013, 34:8314-8322.
10. Khan S.A., Kanchanapally R., Fan Z., Beqa L., Singh A.K., Senapati D., et al. Agold nanocage-CNT hybrid for targeted imaging and photothermal destruction of cancer cells. Chem Commun (Camb) 2012, 48:6711-6713.
11. Zhang Z., Wang J., Chen C. Near-infrared light-mediated nanoplatforms for cancer thermo-chemotherapy and optical imaging. Adv Mater 2013, 25:3869-3880.
12. Huang X., Tang S., Mu X., Dai Y., Chen G., Zhou Z., et al. Freestanding palladium nanosheets with plasmonic and catalytic properties. Nat Nanotechnol 2011, 6:28-32.
13. Zhou F., Wu S., Song S., Chen W.R., Resasco D.E., Xing D. Antitumor immunologically modified carbon nanotubes for photothermal therapy. Biomaterials 2012, 33:3235-3242.
14. Yang K., Xu H., Cheng L., Sun C., Wang J., Liu Z. Invitro and invivo near-infrared photothermal therapy of cancer using polypyrrole organic nanoparticles. Adv Mater 2012, 24:5586-5592.
15. Sharifi S., Behzadi S., Laurent S., Forrest M.L., Stroeve P., Mahmoudi M. Toxicity of nanomaterials. Chem Soc Rev 2012, 41:2323-2343.
16. Nel A., Xia T., Madler L., Li N. Toxic potential of materials at the nanolevel. Science 2006, 311:622-627.
17. Ghosh P., Han G., De M., Kim C.K., Rotello V.M. Gold nanoparticles in delivery applications. Adv Drug Deliv Rev 2008, 60:1307-1315.
18. Yu J., Javier D., Yaseen M.A., Nitin N., Richards-Kortum R., Anvari B., et al. Self-assembly synthesis, tumor cell targeting, and photothermal capabilities of antibody-coated indocyanine green nanocapsules. JAm Chem Soc 2010, 132:1929-1938.
19. Zheng X., Xing D., Zhou F., Wu B., Chen W.R. Indocyanine green-containing nanostructure as near infrared dual-functional targeting probes for optical imaging and photothermal therapy. Mol Pharm 2011, 8:447-456.
20. Zheng X., Zhou F., Wu B., Chen W.R., Xing D. Enhanced tumor treatment using biofunctional indocyanine green-containing nanostructure by intratumoral or intravenous injection. Mol Pharm 2012, 9:514-522.
21. Yue C., Liu P., Zheng M., Zhao P., Wang Y., Ma Y., et al. IR-780 dye loaded tumor targeting theranostic nanoparticles for NIR imaging and photothermal therapy. Biomaterials 2013, 34:6853-6861.
22. Yuan A., Wu J., Tang X., Zhao L., Xu F., Hu Y. Application of near-infrared dyes for tumor imaging, photothermal, and photodynamic therapies. JPharm Sci 2013, 102:6-28.
23. Luo S., Zhang E., Su Y., Cheng T., Shi C. Areview of NIR dyes in cancer targeting and imaging. Biomaterials 2011, 32:7127-7138.
24. Yuan B., Chen N., Zhu Q. Emission and absorption properties of indocyanine green in intralipid solution. JBiomed Opt 2004, 9:497-503.
25. Zheng M., Yue C., Ma Y., Gong P., Zhao P., Zheng C., et al. Single-step assembly of DOX/ICG loaded lipid-polymer nanoparticles for highly effective chemo-photothermal combination therapy. ACS Nano 2013, 7:2056-2067.
26. Lu C., Das S., Magut P.K., Li M., El-Zahab B., Warner I.M. Irradiation induced fluorescence enhancement in PEGylated cyanine-based NIR nano- and mesoscale GUMBOS. Langmuir 2012, 28:14415-14423.
27. Bouteiller C., Clave G., Bernardin A., Chipon B., Massonneau M., Renard P.Y., et al. Novel water-soluble near-infrared cyanine dyes: synthesis, spectral properties, and use in the preparation of internally quenched fluorescent probes. Bioconjug Chem 2007, 18:1303-1317.
28. Peng C.L., Shih Y.H., Lee P.C., Hsieh T.M., Luo T.Y., Shieh M.J. Multimodal image-guided photothermal therapy mediated by 188Re-labeled micelles containing a cyanine-type photosensitizer. ACS Nano 2011, 5:5594-5607.
29. Wilk K.A., Zielinska K., Pietkiewicz J., Skolucka N., Choromanska A., Rossowska J., et al. Photo-oxidative action in MCF-7 cancer cells induced by hydrophobic cyanines loaded in biodegradable microemulsion-templated nanocapsules. Int J Oncol 2012, 41:105-116.
30. Lowery A.R., Gobin A.M., Day E.S., Halas N.J., West J.L. Immunonanoshells for targeted photothermal ablation of tumor cells. Int J Nanomedicine 2006, 1:149-154.
31. Robinson J.T., Tabakman S.M., Liang Y., Wang H., Casalongue H.S., Vinh D., et al. Ultrasmall reduced graphene oxide with high near-infrared absorbance for photothermal therapy. JAm Chem Soc 2011, 133:6825-6831.
32. Singh A.K., Hahn M.A., Gutwein L.G., Rule M.C., Knapik J.A., Moudgil B.M., et al. Multi-dye theranostic nanoparticle platform for bioimaging and cancer therapy. Int J Nanomedicine 2012, 7:2739-2750.
33. Harris J.M., Chess R.B. Effect of pegylation on pharmaceuticals. Nat Rev Drug Discov 2003, 2:214-221.
34. Veronese F.M., Pasut G. PEGylation, successful approach to drug delivery. Drug Discov Today 2005, 10:1451-1458.
35. Pepinsky R.B., Lee W.C., Cornebise M., Gill A., Wortham K., Chen L.L., et al. Design, synthesis, and analysis of a polyethelene glycol-modified (PEGylated) small molecule inhibitor of integrin {alpha}4{beta}1 with improved pharmaceutical properties. JPharmacol Exp Ther 2005, 312:742-750.
36. Tan X., Luo S., Wang D., Su Y., Cheng T., Shi C. ANIR heptamethine dye with intrinsic cancer targeting, imaging and photosensitizing properties. Biomaterials 2012, 33:2230-2239.
37. Engel E., Schraml R., Maisch T., Kobuch K., Konig B., Szeimies R.M., et al. Light-induced decomposition of indocyanine green. Invest Ophthalmol Vis Sci 2008, 49:1777-1783.
38. Maeda H., Wu J., Sawa T., Matsumura Y., Hori K. Tumor vascular permeability and the EPR effect in macromolecular therapeutics: a review. JControl Release 2000, 65:271-284.
39. Zhang C., Wang S., Xiao J., Tan X., Zhu Y., Su Y., et al. Sentinel lymph node mapping by a near-infrared fluorescent heptamethine dye. Biomaterials 2010, 31:1911-1917.