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    4. Jensen SA, Day ES, Ko CH, Hurley LA, Luciano JP, Kouri FM, Merkel TJ, Luthi AJ, Patel PC, Cutler JI, Daniel WL, Scott AW, Rotz MW, Meade TJ, Giljohann DA, Mirkin CA, Stegh AH. Spherical nucleic acid nanoparticle conjugates as an RNAi-based therapy for glioblastoma. Sci Transl Med 5:209ra152 (2013).

       2014-10-09 NWU-SJensenSTM2013SJensenSTM2013v1.2.zip

    5. Wen CY, Wu LL, Zhang ZL, Liu YL, Wei SZ, Hu J, Tang M, Sun EZ, Gong YP, Yu J, Pang DW. Quick-response magnetic nanospheres for rapid, efficient capture and sensitive detection of circulating tumor cells. ACS Nano. 8:941-9 (2014).

      2015-03-04 WU_HCH-CWenACSNano2014CWenACSNano2014v1.2.zip

   6. Han H, Davis ME. Targeted nanoparticles assembled via complexation of boronic-acid-containing  targeting moieties to diol-containing polymers. Bioconjug Chem. 24:669-77 (2013). Han, Davis ME. Single-antibody, targeted nanoparticle delivery of camptothecin. Mol Pharm. 10:2558-67 (2013).

     2015-02-04 Caltech-HHanBC2013HHanBC2013v1.2.zip

   7. Gaur S, Wang Y, Kretzner L, Chen L, Yen T, Wu X, Yuan YC, Davis M, Yen Y. Pharmacodynamic and pharmacogenomic study of the nanoparticle conjugate of camptothecin CRLX101 for the treatment of cancer.   Nanomedicine 10:1477-1486 (2014).

    2015-02-27 BRICH_Caltech_TMU-SGaurNNMB2014SGaurNNMB2014v1.2.zip

  8. Guan YY, Luan X, Xu JR, Liu YR, Lu Q, Wang C, Liu HJ, Gao YG, Chen HZ, Fang C. Selective eradication of tumor vascular pericytes by peptide-conjugated nanoparticles for antiangiogenic therapyof melanoma lung metastasis. Biomaterials 35:3060-3070 (2014).

   2015-08-26 SJTU-YGuanBM2014YGuanBM2014v1.2.zip

 9. Perica K, Tu A, Richter A, Bieler JG, Edidin M, Schneck JP. Magnetic-induced T cell receptor clustering by nanoparticles enhances T cell activation and stimulates antitumor activity. ACS Nano 8:2252-2260.

  2015-07-03 JHU_MB-KPericaACSNano2014KPericaACSNano2014v1.2.zip

10. Tang L, Yang X, Yin Q, Cai K, Wang H, Chaudhury I, Yao C, Zhou Q, Kwon M, Hartman JA, Dobrucki IT, Dobrucki LW, Borst LB, Lezmi S, Helferich WG, Ferguson AL, Fan TM, Cheng J. Investigating the optimal size of anticancer      nanomedicine Proc Natl Acad Sci U S A 111:15344-9 (2014).

  2015-10-01 UI-UC_GPC_NCSU-LTangPNAS2014LTangPNAS2014v1.2.zip

11.  Ayala-Orozco C, Urban C, Knight MW, Urban AS, Neumann O, Bishnoi SW, Mukherjee S, Goodman AM, Charron H, Mitchell T, Shea M, Roy R, Nanda S, Schiff R, Halas NJ, Joshi A. Au nanomatryoshkas as efficient near-infrared photothermal transducers for cancer treatment: benchmarking against nanoshells. ACS Nano. 8:6372-6381 (2014).

  2015-10-01 RU_BCM-CAyala-OrozcoACSNano2014OrozcoACSNano2014v1.2.zip

12. Sykes EA, Chen J, Zheng G, Chan WC Investigating the impact of nanoparticle size on active and passive tumor targeting efficiency. ACSNano 8:5698-5706 (2014).

 20152016-1201-31 14 UT_OCI-ASykesACSNano2014ASykesACSNano2014v1.2.zip

 

ISA-TAB-Nano Curated Examples (ISA-TAB-Nano Version 1.1)

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