Probing nanoparticle translocation across the permeable endothelium in experimental atherosclerosis

YongTae Kim; Mark E. Lobatto; Tomohiro Kawahara; Bomy Lee Chung; Aneta J. Mieszawska; Brenda L. Sanchez-Gaytan; Francois Fay; Max L. Senders; Claudia Calcagno; Jacob Becraft; May Tun Saung; Ronald E. Gordon; Erik S. G. Stroes; Mingming Ma; Omid C. Farokhzad; Zahi A. Fayad; Willem J. M. Mulder; Robert Langer

doi:10.1073/pnas.1322725111

Contributed by Robert Langer, December 6, 2013 (sent for review November 6, 2013)

Significance

This study shows that an endothelialized microfluidic chip with controllable permeability can serve as a model for nanoparticle translocation across the permeable endothelium. Integration of this in vitro model and an in vivo rabbit model revealed that the extravasation of nanoparticles across the endothelium in atherosclerotic plaques depends on microvascular permeability. This approach represents a unique method for the assessment of nanoparticle behavior across the atherosclerotic endothelium, and may also serve as a valuable tool to study nanomedicine accumulation in a variety of other diseases.

Abstract

Therapeutic and diagnostic nanomaterials are being intensely studied for several diseases, including cancer and atherosclerosis. However, the exact mechanism by which nanomedicines accumulate at targeted sites remains a topic of investigation, especially in the context of atherosclerotic disease. Models to accurately predict transvascular permeation of nanomedicines are needed to aid in design optimization. Here we show that an endothelialized microchip with controllable permeability can be used to probe nanoparticle translocation across an endothelial cell layer. To validate our in vitro model, we studied nanoparticle translocation in an in vivo rabbit model of atherosclerosis using a variety of preclinical and clinical imaging methods. Our results reveal that the translocation of lipid–polymer hybrid nanoparticles across the atherosclerotic endothelium is dependent on microvascular permeability. These results were mimicked with our microfluidic chip, demonstrating the potential utility of the model system.

Footnotes

↵¹Y.K. and M.E.L. contributed equally to this work.
↵²To whom correspondence may be addressed. E-mail: rlanger{at}mit.edu or Willem.Mulder{at}mssm.edu.

Author contributions: Y.K., M.E.L., W.J.M.M., and R.L. designed research; Y.K., M.E.L., T.K., B.L.C., A.J.M., B.L.S.-G., F.F., M.L.S., C.C., J.B., and M.T.S. performed research; Y.K., M.E.L., T.K., B.L.C., A.J.M., B.L.S.-G., R.E.G., E.S.G.S., M.M., O.C.F., Z.A.F., W.J.M.M., and R.L. contributed new reagents/analytic tools; Y.K., M.E.L., T.K., O.C.F., Z.A.F., W.J.M.M., and R.L. analyzed data; and Y.K., M.E.L., W.J.M.M., and R.L. wrote the paper.
The authors declare no conflict of interest.
This article contains supporting information online at www.pnas.org/lookup/suppl/doi:10.1073/pnas.1322725111/-/DCSupplemental.