Spatiotemporal Controlled Delivery of Nanoparticles to Injured Vasculature

Overview

Journal Proc Natl Acad Sci U S A

Specialty Science

Date 2010 Feb 6

PMID 20133865

Citations 85

Authors

Juliana M Chan

Liangfang Zhang

Rong Tong

Debuyati Ghosh

Weiwei Gao

Grace Liao

Kai P Yuet

David Gray

June-Wha Rhee

Jianjun Cheng

Gershon Golomb

Peter Libby

Robert Langer

Omid C Farokhzad

Affiliations

Soon will be listed here.

Abstract

There are a number of challenges associated with designing nanoparticles for medical applications. We define two challenges here: (i) conventional targeting against up-regulated cell surface antigens is limited by heterogeneity in expression, and (ii) previous studies suggest that the optimal size of nanoparticles designed for systemic delivery is approximately 50-150 nm, yet this size range confers a high surface area-to-volume ratio, which results in fast diffusive drug release. Here, we achieve spatial control by biopanning a phage library to discover materials that target abundant vascular antigens exposed in disease. Next, we achieve temporal control by designing 60-nm hybrid nanoparticles with a lipid shell interface surrounding a polymer core, which is loaded with slow-eluting conjugates of paclitaxel for controlled ester hydrolysis and drug release over approximately 12 days. The nanoparticles inhibited human aortic smooth muscle cell proliferation in vitro and showed greater in vivo vascular retention during percutaneous angioplasty over nontargeted controls. This nanoparticle technology may potentially be used toward the treatment of injured vasculature, a clinical problem of primary importance.

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