Receptor-Targeted Nanoparticles for In Vivo Imaging of Breast Cancer

Lily, Yang, Emory University; Xianghong, Peng, Emory University; Y. Andrew, Wang, Department of Ocean Nanotech, LLC; Xiaoxia, Wang, Emory University; Zehong, Cao, Emory University; Chunchun, Ni, Emory University; Prasanthi, Karna, Emory University; Xinjian, Zhang, Georgia State University; William C, Wood, Emory University; Xiaohu, Gao, Emory University; Shuming, Nie, Emory University; Hui, Mao, Emory University

Persistent URL

https://open.library.emory.edu/purl/607gqnk999-emory

Last modified

02/20/2025

Type of Material

Article

Authors

Lily Yang, Emory University

Xianghong Peng, Emory University

Y. Andrew Wang, Department of Ocean Nanotech, LLC

Xiaoxia Wang, Emory University

Zehong Cao, Emory University

Chunchun Ni, Emory UniversityPrasanthi Karna, Emory UniversityXinjian Zhang, Georgia State UniversityWilliam C Wood, Emory UniversityXiaohu Gao, Emory UniversityShuming Nie, Emory UniversityHui Mao, Emory University

Language

English

Date

2009-07-15

Publisher

American Association for Cancer Research

Publication Version

Author Accepted Manuscript (After Peer Review)

Copyright Statement

© 2009 American Association fo Cancer research

Final Published Version (URL)

http://clincancerres.aacrjournals.org/content/15/14/4722

Title of Journal or Parent Work

Clinical Cancer Research

ISSN

1078-0432

Volume

15

Issue

14

Start Page

4722

End Page

4732

Grant/Funding Information

National Cancer Institute : NCI

Abstract

Purpose Cell surface receptor-targeted magnetic iron oxide (IO) nanoparticles provide molecular magnetic resonance imaging (MRI) contrast agents for improving specificity of the detection of human cancer. Experimental design The present study reports the development of a novel targeted IO nanoparticle using a recombinant peptide containing the amino-terminal fragment (ATF) of urokinase plasminogen activator conjugated to IO nanoparticles (ATF-IO). This nanoparticle targets urokinase plasminogen activator receptor (uPAR), which is overexpressed in breast cancer tissues. Results ATF-IO nanoparticles are able to specifically bind to and be internalized by uPAR-expressing tumor cells. Systemic delivery of ATF-IO nanoparticles into mice bearing subcutaneous and intraperitoneal mammary tumors leads to the accumulation of the particles in tumors, generating a strong MRI contrast detectable by a clinical MRI scanner at a field strength of 3 Tesla. Target specificity of ATF-IO nanoparticles demonstrated by in vivo MRI is further confirmed by near infrared (NIR) fluorescence imaging of the mammary tumors using NIR dye-labeled ATF peptides conjugated to IO nanoparticles. Furthermore, mice administered ATF-IO nanoparticles exhibit lower uptake of the particles in the liver and spleen compared to those receiving non-targeted IO nanoparticles. Conclusions Our results suggest that uPAR-targeted ATF-IO nanoparticles have potential as molecularly-targeted, dual modality imaging agents for in vivo imaging of breast cancer.

Author Notes

*Correspondence: Lily Yang, MD, PhD, Department of Surgery and Winship Cancer Institute, Emory University School of Medicine, C-4088, 1365 C Clifton Road NE, Atlanta, GA 30322. Phone: (404) 778-4269; Fax: (404) 778-5530; E-mail: Lyang02@emory.edu; Or Hui Mao, PhD, Department of Radiology, Emory Center for Systems Imaging, Emory University School of Medicine, 1841 Clifton Road, Atlanta, GA 30329. Phone: (404) 712-0357; Fax: (404) 712-5948; E-mail: hmao@emory.edu

Keywords

Research Categories

Chemistry, Physical
Chemistry, Biochemistry

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