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Macromolecules
Dec 10, 2013;46 (23): 9169-9180.

Smart Nanoscale Drug Delivery Platforms from Stimuli-Responsive Polymers and Liposomes.

Sang-Min Lee, SonBinh T Nguyen
Author Information
  1. Sang-Min Lee: Department of Chemistry and Center of Cancer Nanotechnology Excellence, Northwestern University, 2145 Sheridan Road, Evanston, Illinois 60208-3113.
  2. SonBinh T Nguyen: Department of Chemistry and Center of Cancer Nanotechnology Excellence, Northwestern University, 2145 Sheridan Road, Evanston, Illinois 60208-3113.
PMID: 28804160 DOI: 10.1021/ma401529w

Abstract

Since the 1960's, stimuli-responsive polymers have been utilized as functional soft materials for biological applications such as the triggered-release delivery of biologically active cargos. Over the same period, liposomes have been explored as an alternative drug delivery system with potentials to decrease the toxic side effects often associated with conventional small-molecule drugs. However, the lack of drug-release triggers and the instability of bare liposomes often limit their practical applications, causing short circulation time and low therapeutic efficacy. This perspective article highlights recent work in integrating these two materials together to achieve a targetable, triggerable nanoscale platform that fulfills all the characteristics of a near-ideal drug delivery system. Through a , post-synthesis modification strategy, a network of stimuli-responsive polymers can be integrated onto the surface of liposomes to form polymer-caged nanobins, a multifunctional nanoscale delivery platform that allows for multi-drug loading, targeted delivery, triggered drug-release, and theranostic capabilities.

Keywords

drug delivery liposomes stimuli-responsive polymer gels triggered release

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Grants

  1. P30 CA060553/NCI NIH HHS
  2. U01 CA151461/NCI NIH HHS
  3. U54 CA151880/NCI NIH HHS
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