Hyaluronic acid-modified Fe3O4 at Au core/shell nanostars for multimodal imaging and photothermal therapy of tumors

Biomaterials

Volumn 38, Issue , 2015, Pages 10-21

  Li, Jingchao ^a   Hu, Yong ^a   Yang, Jia ^b   Wei, Ping ^a   Sun, Wenjie ^a   Shen, Mingwu ^a   Zhang, Guixiang ^b   Shi, Xiangyang ^a  

^a DONGHUA UNIVERSITY   (China)

^b SHANGHAI FIRST PEOPLE S HOSPITAL   (China)

Author keywords

CT imaging; Fe3O4 at Au nanostars; Hyaluronic acid; MR imaging; Photothermal therapy; Tumors

Indexed keywords

BIOCOMPATIBILITY; CELLS; COMPUTERIZED TOMOGRAPHY; DIAGNOSIS; DISEASES; GOLD; INFRARED IMAGING; MAGNETIC RESONANCE; MAGNETIC RESONANCE IMAGING; NANOPROBES; ORGANIC ACIDS; SILVER; SYNTHESIS (CHEMICAL); TUMORS;

AU NANOSTARS; COLLOIDAL STABILITY; CT IMAGING; HYDROTHERMALLY SYNTHESIZED; MR IMAGING; MULTI-MODAL IMAGING; PHOTOTHERMAL ABLATION; PHOTOTHERMAL THERAPY;

HYALURONIC ACID;

GOLD NANOPARTICLE; HYALURONIC ACID; POLYETHYLENEIMINE; CONTRAST MEDIUM; GOLD; MAGNETITE NANOPARTICLE; NANOCAPSULE; NANOCOMPOSITE;

ARTICLE; BIOCOMPATIBILITY; CANCER CELL; CANCER THERAPY; COLLOID; COMPUTER ASSISTED TOMOGRAPHY; GENE OVEREXPRESSION; IN VITRO STUDY; MULTIMODAL IMAGING; NANOPROBE; NEAR INFRARED SPECTROSCOPY; NUCLEAR MAGNETIC RESONANCE; PHOTOTHERAPY; PHOTOTHERMAL THERAPY; SYNTHESIS; TUMOR MODEL; TUMOR XENOGRAFT; ANIMAL; CHEMISTRY; DIAGNOSTIC USE; HELA CELL LINE; HUMAN; HYPERTHERMIC THERAPY; MALE; MOUSE; NANOPORE; NEOPLASMS, EXPERIMENTAL; NUCLEAR MAGNETIC RESONANCE IMAGING; NUDE MOUSE; POROSITY; PROCEDURES; THERMOGRAPHY; TREATMENT OUTCOME; ULTRASTRUCTURE;

ANIMALS; CONTRAST MEDIA; GOLD; HELA CELLS; HUMANS; HYALURONIC ACID; HYPERTHERMIA, INDUCED; MAGNETIC RESONANCE IMAGING; MAGNETITE NANOPARTICLES; MALE; MICE; MICE, NUDE; MULTIMODAL IMAGING; NANOCAPSULES; NANOCOMPOSITES; NANOPORES; NEOPLASMS, EXPERIMENTAL; PHOTOTHERAPY; POROSITY; THERMOGRAPHY; TOMOGRAPHY, X-RAY COMPUTED; TREATMENT OUTCOME;

EID: 84912103862     PISSN: 01429612     EISSN: 18785905     Source Type: Journal    
DOI: 10.1016/j.biomaterials.2014.10.065     Document Type: Article

References (65)

1. Taylor-Pashow K.M., Della Rocca J., Huxford R.C., Lin W. Hybrid nanomaterials for biomedical applications. Chem Commun 2010, 46:5832-5849.
2. Shen M., Shi X. Dendrimer-based organic/inorganic hybrid nanoparticles in biomedical applications. Nanoscale 2010, 2:1596-1610.
3. Leung K.C.-F., Xuan S., Zhu X., Wang D., Chak C.-P., Lee S.-F., et al. Gold and iron oxide hybrid nanocomposite materials. Chem Soc Rev 2012, 41:1911-1928.
4. Du C., Zhao J., Fei J., Gao L., Cui W., Yang Y., et al. Alginate-based microcapsules with a molecule recognition linker and photosensitizer for the combined cancer treatment. Chem Asian J 2013, 8:736-742.
5. Qi W., Duan L., Li J. Fabrication of glucose-sensitive protein microcapsules and their applications. Soft Matter 2011, 7:1571-1576.
6. Li D., He Q., Yang Y., Möhwald H., Li J. Two-stage pH response of poly (4-vinylpyridine) grafted gold nanoparticles. Macromolecules 2008, 41:7254-7256.
7. Qi W., Wang A., Yang Y., Du M., Bouchu M.N., Boullanger P., et al. The lectin binding and targetable cellular uptake of lipid-coated polysaccharide microcapsules. JMater Chem 2010, 20:2121-2127.
8. + lymphocytes. Biomaterials 2008, 29:4003-4011.
9. 4 nanoparticles for protein separation. ACS Nano 2007, 1:293-298.
10. Samanta B., Yan H., Fischer N.O., Shi J., Jerry D.J., Rotello V.M. Protein-passivated Fe3O4 nanoparticles: low toxicity and rapid heating for thermal therapy. JMater Chem 2008, 18:1204-1208.
11. 4 composite nanospheres for invivo imaging and hyperthermia. Adv Mater 2009, 21:2170-2173.
12. 4 nanoparticles and their enhanced catalysis for oxygen reduction reaction. Nano Lett 2009, 9:1493-1496.
13. Pan B., Cui D., Sheng Y., Ozkan C., Gao F., He R., et al. Dendrimer-modified magnetic nanoparticles enhance efficiency of gene delivery system. Cancer Res 2007, 67:8156-8163.
14. Chen Y., Chen H., Zeng D., Tian Y., Chen F., Feng J., et al. Core/shell structured hollow mesoporous nanocapsules: a potential platform for simultaneous cell imaging and anticancer drug delivery. ACS Nano 2010, 4:6001-6013.
15. Li J., Zheng L., Cai H., Sun W., Shen M., Zhang G., et al. Polyethyleneimine-mediated synthesis of folic acid-targeted iron oxide nanoparticles for invivo tumor MR imaging. Biomaterials 2013, 34:8382-8392.
16. Li J., He Y., Sun W., Luo Y., Cai H., Pan Y., et al. Hyaluronic acid-modified hydrothermally synthesized iron oxide nanoparticles for targeted tumor MR imaging. Biomaterials 2014, 35:3666-3677.
17. Cai H., An X., Cui J., Li J., Wen S., Li K., et al. Facile hydrothermal synthesis and surface functionalization of polyethyleneimine-coated iron oxide nanoparticles for biomedical applications. ACS Appl Mater Interfaces 2013, 5:1722-1731.
18. Guo R., Wang H., Peng C., Shen M., Pan M., Cao X., et al. X-ray attenuation property of dendrimer-entrapped gold nanoparticles. JPhys Chem C 2010, 114:50-56.
19. Peng C., Li K., Cao X., Xiao T., Hon W., Zheng L., et al. Facile formation of dendrimer-stabilized gold nanoparticles modified with diatrizoic acid for enhanced computed tomography imaging applications. Nanoscale 2012, 4:6768-6778.
20. Peng C., Zheng L., Chen Q., Shen M., Guo R., Wang H., et al. PEGylated dendrimer-entrapped gold nanoparticles for invivo blood pool and tumor imaging by computed tomography. Biomaterials 2012, 33:1107-1119.
21. Wang H., Zheng L., Peng C., Guo R., Shen M., Shi X., et al. Computed tomography imaging of cancer cells using acetylated dendrimer-entrapped gold nanoparticles. Biomaterials 2011, 32:2979-2988.
22. Wang H., Zheng L., Peng C., Shen M., Shi X., Zhang G. Folic acid-modified dendrimer-entrapped gold nanoparticles as nanoprobes for targeted CT imaging of human lung adenocarcinoma. Biomaterials 2013, 34:470-480.
23. Wen S., Li K., Cai H., Chen Q., Shen M., Huang Y., et al. Multifunctional dendrimer-entrapped gold nanoparticles for dual mode CT/MR imaging applications. Biomaterials 2013, 34:1570-1580.
24. Huang X., El-Sayed I.H., Qian W., El-Sayed M.A. Cancer cell imaging and photothermal therapy in the near-infrared region by using gold nanorods. JAm Chem Soc 2006, 128:2115-2120.
25. 2 nanocomposites. Biomaterials 2014, 35:3309-3318.
26. Ji X., Shao R., Elliott A.M., Stafford R.J., Esparza-Coss E., Bankson J.A., et al. Bifunctional gold nanoshells with a superparamagnetic iron oxide-silica core suitable for both MR imaging and photothermal therapy. JPhys Chem C 2007, 111:6245-6251.
27. Ma Y., Liang X., Tong S., Bao G., Ren Q., Dai Z. Gold nanoshell nanomicelles for potential magnetic resonance imaging, light-triggered drug release, and photothermal therapy. Adv Funct Mater 2013, 23:815-822.
28. Han J., Li J., Jia W., Yao L., Li X., Jiang L., et al. Photothermal therapy of cancer cells using novel hollow gold nanoflowers. Int J Nanomed 2014, 9:517-526.
29. Yang J., Shen D., Zhou L., Li W., Li X., Yao C., et al. Spatially confined fabrication of core-shell gold nanocages at mesoporous silica for near-infrared controlled photothermal drug release. Chem Mater 2013, 25:3030-3037.
30. Gao L., Fei J., Zhao J., Li H., Cui Y., Li J. Hypocrellin-loaded gold nanocages with high two-photon efficiency for photothermal/photodynamic cancer therapy invitro. ACS Nano 2012, 6:8030-8040.
31. Yuan H., Fales A.M., Vo-Dinh T. TAT peptide-functionalized gold nanostars: enhanced intracellular delivery and efficient NIR photothermal therapy using ultralow irradiance. JAm Chem Soc 2012, 134:11358-11361.
32. Wang S., Huang P., Nie L., Xing R., Liu D., Wang Z., et al. Single continuous wave laser induced photodynamic/plasmonic photothermal therapy using photosensitizer-functionalized gold nanostars. Adv Mater 2013, 25:3055-3061.
33. Hwang S., Nam J., Song J., Jung S., Hur J., Im K., et al. Sub 6 nanometer plasmonic gold nanoparticle for pH-responsive near-infrared photothermal cancer therapy. New J Chem 2014, 918-922.
34. 4 nanoroses with five unique functions for cancer cell targeting, imaging, and therapy. Adv Funct Mater 2013, 24:1772-1780.
35. 4 nanoparticles for dual-modal imaging and invivo photothermal cancer therapy. Small 2013, 10:1063-1068.
36. 4 core/Au shell nanoparticles for targeting and multimodal imaging of cancer cells. JMater Chem 2012, 22:470-477.
37. 4 at Au nanocomposite particles for dual mode magnetic resonance and computed tomography imaging applications. JMater Chem 2012, 22:15110-15120.
38. 2-xS core-shell nanoparticles for dual-modal imaging and photothermal therapy. JAm Chem Soc 2013, 135:8571-8577.
39. Wang Y., Guo R., Cao X., Shen M., Shi X. Encapsulation of 2-methoxyestradiol within multifunctional poly (amidoamine) dendrimers for targeted cancer therapy. Biomaterials 2011, 32:3322-3329.
40. Zhang X.-y., Chen J., Zheng Y.-f., Gao X.-l., Kang Y., Liu J.-c., et al. Follicle-stimulating hormone peptide can facilitate paclitaxel nanoparticles to target ovarian carcinoma invivo. Cancer Res 2009, 69:6506-6514.
41. Feng W., Zhou X., He C., Qiu K., Nie W., Chen L., et al. Polyelectrolyte multilayer functionalized mesoporous silica nanoparticles for pH-responsive drug delivery: layer thickness-dependent release profiles and biocompatibility. JMater Chem B 2013, 1:5886-5898.
42. Li D., Li C., Wang A., He Q., Li J. Hierarchical gold/copolymer nanostructures as hydrophobic nano tanks for drug encapsulation. JMater Chem 2010, 20:7782-7787.
43. Zheng Y., Fu F., Zhang M., Shen M., Zhu M., Shi X. Multifunctional dendrimers modified with alpha-tocopheryl succinate for targeted cancer therapy. Med Chem Commun 2014, 5:879-885.
44. Zhu J., Zheng L., Wen S., Tang Y., Shen M., Zhang G., et al. Targeted cancer theranostics using alpha-tocopheryl succinate-conjugated multifunctional dendrimer-entrapped gold nanoparticles. Biomaterials 2014, 35:7635-7646.
45. Zhu J., Shi X. Dendrimer-based nanodevices for targeted drug delivery applications. JMater Chem 2013, 1:4199-4211.
46. Zheng L., Zhu J., Shen M., Chen X., Baker J.R., Wang S.H., et al. Targeted cancer cell inhibition using multifunctional dendrimer-entrapped gold nanoparticles. Med Chem Commun 2013, 4:1001-1005.
47. Zhou Z., Kong B., Yu C., Shi X., Wang M., Liu W., et al. Tungsten oxide nanorods: an efficient nanoplatform for tumor CT imaging and photothermal therapy. Sci Rep 2014, 4:3653.
48. Li B., Wang Q., Zou R., Liu X., Xu K., Li W., et al. Cu7.2S4 nanocrystals: a novel photothermal agent with a 56.7% photothermal conversion efficiency for photothermal therapy of cancer cells. Nanoscale 2014, 6:3274-3282.
49. Mackey M.A., Ali M.R., Austin L.A., Near R.D., El-Sayed M.A. The most effective gold nanorod size for plasmonic photothermal therapy: theory and invitro experiments. JPhys Chem B 2014, 118:1319-1326.
50. Chen H., Zhang X., Dai S., Ma Y., Cui S., Achilefu S., et al. Multifunctional gold nanostar conjugates for tumor imaging and combined photothermal and chemo-therapy. Theranostics 2013, 3:633-649.
51. Peng C., Qin J., Zhou B., Chen Q., Shen M., Zhu M., et al. Targeted tumor CT imaging using folic acid-modified PEGylated dendrimer-entrapped gold nanoparticles. Polym Chem 2013, 4:4412-4424.
52. Chen Q., Li K., Wen S., Liu H., Peng C., Cai H., et al. Targeted CT/MR dual mode imaging of tumors using multifunctional dendrimer-entrapped gold nanoparticles. Biomaterials 2013, 34:5200-5209.
53. Wang S.H., Shi X., Van Antwerp M., Cao Z., Swanson S.D., Bi X., et al. Dendrimer-functionalized iron oxide nanoparticles for specific targeting and imaging of cancer cells. Adv Funct Mater 2007, 17:3043-3050.
54. Shi X., Wang S.H., Swanson S.D., Ge S., Cao Z., Van Antwerp M.E., et al. Dendrimer-functionalized shell-crosslinked iron oxide nanoparticles for in-vivo magnetic resonance imaging of tumors. Adv Mater 2008, 20:1671-1678.
55. Shen M., Cai H., Wang X., Cao X., Li K., Wang S.H., et al. Facile one-pot preparation, surface functionalization, and toxicity assay of APTS-coated iron oxide nanoparticles. Nanotechnology 2012, 23:105601.
56. 4 at Au composite nanoparticles for dual-mode MR/CT imaging applications. ACS Appl Mater Interfaces 2013, 5:10357-10366.
57. Hu Y., Li J., Shen M., Shi X. Formation of multifunctional Fe3O4/Au composite nanoparticles for dual mode MR/CT imaging applications. Chin Phys B 2014, 23:078704.
58. Baginskiy I., Lai T.-C., Cheng L.-C., Chan Y.-C., Yang K.-Y., Liu R.-S., et al. Chitosan-modified stable colloidal gold nanostars for the photothermolysis of cancer cells. JPhys Chem C 2013, 117:2396-2410.
59. Wei Q., Song H.-M., Leonov A.P., Hale J.A., Oh D., Ong Q.K., et al. Gyromagnetic imaging: dynamic optical contrast using gold nanostars with magnetic cores. JAm Chem Soc 2009, 131:9728-9734.
60. Fan Z., Senapati D., Singh A.K., Ray P.C. Theranostic magnetic core-plasmonic shell star shape nanoparticle for the isolation of targeted rare tumor cells from whole blood, fluorescence imaging, and photothermal destruction of cancer. Mol Pharm 2013, 10:857-866.
61. Pan B., Gao F., Ao L., Tian H., He R., Cui D. Controlled self-assembly of thiol-terminated poly(amidoamine) dendrimer and gold nanoparticles. Colloid Surf A-Physicochem Eng Asp 2005, 259:89-94.
62. Yu M., Jambhrunkar S., Thorn P., Chen J., Gu W., Yu C. Hyaluronic acid modified mesoporous silica nanoparticles for targeted drug delivery to CD44-overexpressing cancer cells. Nanoscale 2013, 5:178-183.
63. Choi K.Y., Min K.H., Na J.H., Choi K., Kim K., Park J.H., et al. Self-assembled hyaluronic acid nanoparticles as a potential drug carrier for cancer therapy: synthesis, characterization, and invivo biodistribution. JMater Chem 2009, 19:4102-4107.
64. Cho H.-J., Yoon I.-S., Yoon H.Y., Koo H., Jin Y.-J., Ko S.-H., et al. Polyethylene glycol-conjugated hyaluronic acid-ceramide self-assembled nanoparticles for targeted delivery of doxorubicin. Biomaterials 2012, 33:1190-1200.
65. Liu H., Xu Y., Wen S., Chen Q., Zheng L., Shen M., et al. Targeted tumor computed tomography imaging using low-generation dendrimer-stabilized gold nanoparticles. Chem Eur J 2013, 19:6409-6416.