The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers

Carlee E. Ashley; Eric C. Carnes; Genevieve K. Phillips; David Padilla; Paul N. Durfee; Page A. Brown; Tracey N. Hanna; Juewen Liu; Brandy Phillips; Mark B. Carter; Nick J. Carroll; Xingmao Jiang; Darren R. Dunphy; Cheryl L. Willman; Dimiter N. Petsev; Deborah G. Evans; Atul N. Parikh; Bryce Chackerian; Walker Wharton; David S. Peabody; C. Jeffrey Brinker

doi:10.1038/nmat2992

The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers

Carlee E. Ashley, Eric C. Carnes, Genevieve K. Phillips, David Padilla, Paul N. Durfee, Page A. Brown, Tracey N. Hanna, Juewen Liu, Brandy Phillips, Mark B. Carter, Nick J. Carroll, Xingmao Jiang, Darren R. Dunphy, Cheryl L. Willman, Dimiter N. Petsev, Deborah G. Evans, Atul N. Parikh, Bryce Chackerian, Walker Wharton, David S. PeabodyC. Jeffrey Brinker

Research output: Contribution to journal › Article › peer-review

900 Scopus citations

Abstract

Encapsulation of drugs within nanocarriers that selectively target malignant cells promises to mitigate side effects of conventional chemotherapy and to enable delivery of the unique drug combinations needed for personalized medicine. To realize this potential, however, targeted nanocarriers must simultaneously overcome multiple challenges, including specificity, stability and a high capacity for disparate cargos. Here we report porous nanoparticle-supported lipid bilayers (protocells) that synergistically combine properties of liposomes and nanoporous particles. Protocells modified with a targeting peptide that binds to human hepatocellular carcinoma exhibit a 10,000-fold greater affinity for human hepatocellular carcinoma than for hepatocytes, endothelial cells or immune cells. Furthermore, protocells can be loaded with combinations of therapeutic (drugs, small interfering RNA and toxins) and diagnostic (quantum dots) agents and modified to promote endosomal escape and nuclear accumulation of selected cargos. The enormous capacity of the high-surface-area nanoporous core combined with the enhanced targeting efficacy enabled by the fluid supported lipid bilayer enable a single protocell loaded with a drug cocktail to kill a drug-resistant human hepatocellular carcinoma cell, representing a 10⁶-fold improvement over comparable liposomes.

Original language	English (US)
Pages (from-to)	389-397
Number of pages	9
Journal	Nature Materials
Volume	10
Issue number	5
DOIs	https://doi.org/10.1038/nmat2992
State	Published - May 2011
Externally published	Yes

ASJC Scopus subject areas

Chemistry(all)
Materials Science(all)
Condensed Matter Physics
Mechanics of Materials
Mechanical Engineering

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10.1038/nmat2992

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Ashley, C. E., Carnes, E. C., Phillips, G. K., Padilla, D., Durfee, P. N., Brown, P. A., Hanna, T. N., Liu, J., Phillips, B., Carter, M. B., Carroll, N. J., Jiang, X., Dunphy, D. R., Willman, C. L., Petsev, D. N., Evans, D. G., Parikh, A. N., Chackerian, B., Wharton, W., ... Brinker, C. J. (2011). The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers. Nature Materials, 10(5), 389-397. https://doi.org/10.1038/nmat2992

Ashley, CE, Carnes, EC, Phillips, GK, Padilla, D, Durfee, PN, Brown, PA, Hanna, TN, Liu, J, Phillips, B, Carter, MB, Carroll, NJ, Jiang, X, Dunphy, DR, Willman, CL, Petsev, DN, Evans, DG, Parikh, AN, Chackerian, B, Wharton, W, Peabody, DS & Brinker, CJ 2011, 'The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers', Nature Materials, vol. 10, no. 5, pp. 389-397. https://doi.org/10.1038/nmat2992

@article{4a0ec22834e64347b6ff202e614b359b,

title = "The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers",

abstract = "Encapsulation of drugs within nanocarriers that selectively target malignant cells promises to mitigate side effects of conventional chemotherapy and to enable delivery of the unique drug combinations needed for personalized medicine. To realize this potential, however, targeted nanocarriers must simultaneously overcome multiple challenges, including specificity, stability and a high capacity for disparate cargos. Here we report porous nanoparticle-supported lipid bilayers (protocells) that synergistically combine properties of liposomes and nanoporous particles. Protocells modified with a targeting peptide that binds to human hepatocellular carcinoma exhibit a 10,000-fold greater affinity for human hepatocellular carcinoma than for hepatocytes, endothelial cells or immune cells. Furthermore, protocells can be loaded with combinations of therapeutic (drugs, small interfering RNA and toxins) and diagnostic (quantum dots) agents and modified to promote endosomal escape and nuclear accumulation of selected cargos. The enormous capacity of the high-surface-area nanoporous core combined with the enhanced targeting efficacy enabled by the fluid supported lipid bilayer enable a single protocell loaded with a drug cocktail to kill a drug-resistant human hepatocellular carcinoma cell, representing a 106-fold improvement over comparable liposomes.",

author = "Ashley, {Carlee E.} and Carnes, {Eric C.} and Phillips, {Genevieve K.} and David Padilla and Durfee, {Paul N.} and Brown, {Page A.} and Hanna, {Tracey N.} and Juewen Liu and Brandy Phillips and Carter, {Mark B.} and Carroll, {Nick J.} and Xingmao Jiang and Dunphy, {Darren R.} and Willman, {Cheryl L.} and Petsev, {Dimiter N.} and Evans, {Deborah G.} and Parikh, {Atul N.} and Bryce Chackerian and Walker Wharton and Peabody, {David S.} and Brinker, {C. Jeffrey}",

note = "Funding Information: This work was supported by the NIH/Roadmap for Medical Research under grant PHS 2 PN2 EY016570B; NCI Cancer Nanotechnology Platform Partnership grant 1U01CA151792-01; the Air Force Office of Scientific Research grant FA 9550-07-1-0054/9550-10-1-0054; the US Department of Energy, Office of Basic Energy Sciences, Division of Materials Sciences and Engineering; the Sandia National Laboratories{\textquoteright} Laboratory Directed Research and Development (LDRD) programme; the President Harry S. Truman Fellowship in National Security Science and Engineering at Sandia National Laboratories (C.E.A.); the UCLA Center for Nanobiology and Predictive Toxicology (NIEHS grant 1U19ES019528-01) and the NSF ERC Center for Environmental Implications of Nanotechnology at UCLA (NSF:EF-0820117). C.E.A. was supported by IGERT Fellowship Grant NSF DGE-0504276, and E.C.C. and N.J.C. were supported by NSF IGERT grant DGE-0549500. T.N.H. was supported by NSF Nanoscience and Microsystems REU program (grant DMR-0649132) at the University of New Mexico Center for Micro-Engineered Materials. N.J.C and D.N.P. were supported by NSF PREM/DMR 0611616. R. Lee provided guidance for imaging protocols and FRAP experiments, M. Aragon created schematic diagrams, R. Sewell carried out nitrogen sorption experiments and Y-B. Jiang carried out TEM imaging. Cryogenic TEM was carried out at Baylor College of Medicine (Houston, TX) by C. Jia-Yin Fu, H. Khant and W. Chiu. Some images in this paper were generated in the University of New Mexico Cancer Center Fluorescence Microscopy Facility, supported by NCRR, NSF and NCI as detailed at http://hsc.unm.edu/crtc/microscopy/Facility.html. Data were generated in the Flow Cytometry Shared Resource Center supported by the University of New Mexico Health Sciences Center and the University of New Mexico Cancer Center. Sandia is a multiprogramme laboratory operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin Company, for the US Department of Energy{\textquoteright}s National Nuclear Security Administration under contract DE-AC04-94AL85000.",

year = "2011",

month = may,

doi = "10.1038/nmat2992",

language = "English (US)",

volume = "10",

pages = "389--397",

journal = "Nature Materials",

issn = "1476-1122",

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number = "5",

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T1 - The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers

AU - Ashley, Carlee E.

AU - Carnes, Eric C.

AU - Phillips, Genevieve K.

AU - Padilla, David

AU - Durfee, Paul N.

AU - Brown, Page A.

AU - Hanna, Tracey N.

AU - Liu, Juewen

AU - Phillips, Brandy

AU - Carter, Mark B.

AU - Carroll, Nick J.

AU - Jiang, Xingmao

AU - Dunphy, Darren R.

AU - Willman, Cheryl L.

AU - Petsev, Dimiter N.

AU - Evans, Deborah G.

AU - Parikh, Atul N.

AU - Chackerian, Bryce

AU - Wharton, Walker

AU - Peabody, David S.

AU - Brinker, C. Jeffrey

N1 - Funding Information: This work was supported by the NIH/Roadmap for Medical Research under grant PHS 2 PN2 EY016570B; NCI Cancer Nanotechnology Platform Partnership grant 1U01CA151792-01; the Air Force Office of Scientific Research grant FA 9550-07-1-0054/9550-10-1-0054; the US Department of Energy, Office of Basic Energy Sciences, Division of Materials Sciences and Engineering; the Sandia National Laboratories’ Laboratory Directed Research and Development (LDRD) programme; the President Harry S. Truman Fellowship in National Security Science and Engineering at Sandia National Laboratories (C.E.A.); the UCLA Center for Nanobiology and Predictive Toxicology (NIEHS grant 1U19ES019528-01) and the NSF ERC Center for Environmental Implications of Nanotechnology at UCLA (NSF:EF-0820117). C.E.A. was supported by IGERT Fellowship Grant NSF DGE-0504276, and E.C.C. and N.J.C. were supported by NSF IGERT grant DGE-0549500. T.N.H. was supported by NSF Nanoscience and Microsystems REU program (grant DMR-0649132) at the University of New Mexico Center for Micro-Engineered Materials. N.J.C and D.N.P. were supported by NSF PREM/DMR 0611616. R. Lee provided guidance for imaging protocols and FRAP experiments, M. Aragon created schematic diagrams, R. Sewell carried out nitrogen sorption experiments and Y-B. Jiang carried out TEM imaging. Cryogenic TEM was carried out at Baylor College of Medicine (Houston, TX) by C. Jia-Yin Fu, H. Khant and W. Chiu. Some images in this paper were generated in the University of New Mexico Cancer Center Fluorescence Microscopy Facility, supported by NCRR, NSF and NCI as detailed at http://hsc.unm.edu/crtc/microscopy/Facility.html. Data were generated in the Flow Cytometry Shared Resource Center supported by the University of New Mexico Health Sciences Center and the University of New Mexico Cancer Center. Sandia is a multiprogramme laboratory operated by Sandia Corporation, a wholly owned subsidiary of Lockheed Martin Company, for the US Department of Energy’s National Nuclear Security Administration under contract DE-AC04-94AL85000.

PY - 2011/5

Y1 - 2011/5

N2 - Encapsulation of drugs within nanocarriers that selectively target malignant cells promises to mitigate side effects of conventional chemotherapy and to enable delivery of the unique drug combinations needed for personalized medicine. To realize this potential, however, targeted nanocarriers must simultaneously overcome multiple challenges, including specificity, stability and a high capacity for disparate cargos. Here we report porous nanoparticle-supported lipid bilayers (protocells) that synergistically combine properties of liposomes and nanoporous particles. Protocells modified with a targeting peptide that binds to human hepatocellular carcinoma exhibit a 10,000-fold greater affinity for human hepatocellular carcinoma than for hepatocytes, endothelial cells or immune cells. Furthermore, protocells can be loaded with combinations of therapeutic (drugs, small interfering RNA and toxins) and diagnostic (quantum dots) agents and modified to promote endosomal escape and nuclear accumulation of selected cargos. The enormous capacity of the high-surface-area nanoporous core combined with the enhanced targeting efficacy enabled by the fluid supported lipid bilayer enable a single protocell loaded with a drug cocktail to kill a drug-resistant human hepatocellular carcinoma cell, representing a 106-fold improvement over comparable liposomes.

AB - Encapsulation of drugs within nanocarriers that selectively target malignant cells promises to mitigate side effects of conventional chemotherapy and to enable delivery of the unique drug combinations needed for personalized medicine. To realize this potential, however, targeted nanocarriers must simultaneously overcome multiple challenges, including specificity, stability and a high capacity for disparate cargos. Here we report porous nanoparticle-supported lipid bilayers (protocells) that synergistically combine properties of liposomes and nanoporous particles. Protocells modified with a targeting peptide that binds to human hepatocellular carcinoma exhibit a 10,000-fold greater affinity for human hepatocellular carcinoma than for hepatocytes, endothelial cells or immune cells. Furthermore, protocells can be loaded with combinations of therapeutic (drugs, small interfering RNA and toxins) and diagnostic (quantum dots) agents and modified to promote endosomal escape and nuclear accumulation of selected cargos. The enormous capacity of the high-surface-area nanoporous core combined with the enhanced targeting efficacy enabled by the fluid supported lipid bilayer enable a single protocell loaded with a drug cocktail to kill a drug-resistant human hepatocellular carcinoma cell, representing a 106-fold improvement over comparable liposomes.

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The targeted delivery of multicomponent cargos to cancer cells by nanoporous particle-supported lipid bilayers

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