Sn2 Lipase Labile Prodrugs and Contact-Facilitated Drug Delivery for Lipid-Encapsulated Nanomedicines

D. Pan; G. Cui; C. T. N. Pham; M. H. Tomasson; K. N. Weilbaecher; G. M. Lanza

doi:10.1021/bk-2017-1271.ch008

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Sn2 Lipase Labile Prodrugs and Contact-Facilitated Drug Delivery for Lipid-Encapsulated Nanomedicines

Conference proceeding

Peer reviewed

Sn2 Lipase Labile Prodrugs and Contact-Facilitated Drug Delivery for Lipid-Encapsulated Nanomedicines

D. Pan, G. Cui, C. T. N. Pham, M. H. Tomasson, K. N. Weilbaecher and G. M. Lanza

CONTROL OF AMPHIPHILE SELF-ASSEMBLING AT THE MOLECULAR LEVEL: SUPRA-MOLECULAR ASSEMBLIES WITH TUNED PHYSICOCHEMICAL PROPERTIES FOR DELIVERY APPLICATIONS, Vol.1271, pp.189-209

ACS Symposium Series

01/01/2017

DOI: 10.1021/bk-2017-1271.ch008

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Abstract

The concept of achieving Paul Erhlich's inspired vision of a "magic bullet" to treat disease is now materializing with select monoclonal antibody therapies, but this achievement is not well replicated by current nanomedicine clinical candidates. Nanomedicine technologies have often proven unstable in vivo due to premature release of drug cargoes during circulation resulting in low therapeutic delivery to targeted cells. Compounding this nanoparticle payloads that reach target cells are typically internalized within endosomes, contributing to further drug loss and diminished intracellular drug bioavailability. Historically, size limited extravasation of nanoparticles beyond the circulation followed by inhomogeneous and inadequate deep penetration into disease sites has been the major nanoparticle biological barrier. However, nanomedicines can function as excipients and prolonged release systems to favorably alter drug pharmacokinetics and volume of distributions for greater efficacy and lower toxicity. Sn2 phospholipid prodrugs in conjunction with a contact-facilitated drug delivery mechanism have been found to minimize premature drug diffusional loss during circulation and to increase target cell bioavailability. The Sn2 phospholipid prodrug approach has been applied equally well for vascular constrained lipid-encapsulated particles delivering anti-angiogenic therapies, such as fumagillin or docetaxel, and to micelles penetrating through inflamed endothelium into disseminated cancers, such as in multiple myeloma with anti-cMYC payloads. Innovations like Sn2 phospholipid prodrugs in combination with the contact-facilitated drug delivery mechanism are poised to contribute to the translational success of nanomedicines by increasing efficacy and safety for an array of poorly treated diseases.

Chemistry

Chemistry, Multidisciplinary

Chemistry, Physical

Life Sciences & Biomedicine

Pharmacology & Pharmacy

Physical Sciences

Science & Technology

Details

Title: Subtitle: Sn2 Lipase Labile Prodrugs and Contact-Facilitated Drug Delivery for Lipid-Encapsulated Nanomedicines
Creators: D. Pan - University of Illinois Urbana-Champaign
G. Cui - Washington University in St. Louis
C. T. N. Pham - Washington University in St. Louis
M. H. Tomasson - University of Iowa
K. N. Weilbaecher - Washington University in St. Louis
G. M. Lanza - Washington University in St. Louis
Contributors: M A Ilies (Editor)
Resource Type: Conference proceeding
Publication Details: CONTROL OF AMPHIPHILE SELF-ASSEMBLING AT THE MOLECULAR LEVEL: SUPRA-MOLECULAR ASSEMBLIES WITH TUNED PHYSICOCHEMICAL PROPERTIES FOR DELIVERY APPLICATIONS, Vol.1271, pp.189-209
Publisher: Amer Chemical Soc
Series: ACS Symposium Series
DOI: 10.1021/bk-2017-1271.ch008
ISSN: 0097-6156
eISSN: 1947-5918
Number of pages: 21
Language: English
Date published: 01/01/2017
Academic Unit: Hematology, Oncology, and Blood & Marrow Transplantation; Health and Human Physiology; Internal Medicine
Record Identifier: 9984359858702771

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