Porous silicon advances in drug delivery and immunotherapy

David J. Savage; Xuewu Liu; Steven A. Curley; Mauro Ferrari; Rita E. Serda

doi:10.1016/j.coph.2013.06.006

Porous silicon advances in drug delivery and immunotherapy

David J. Savage, Xuewu Liu, Steven A. Curley, Mauro Ferrari, Rita E. Serda

Research output: Contribution to journal › Review article › peer-review

59 Scopus citations

Abstract

Biomedical applications of porous silicon include drug delivery, imaging, diagnostics and immunotherapy. This review summarizes new silicon particle fabrication techniques, dynamics of cellular transport, advances in the multistage vector approach to drug delivery, and the use of porous silicon as immune adjuvants. Recent findings support superior therapeutic efficacy of the multistage vector approach over single particle drug delivery systems in mouse models of ovarian and breast cancer. With respect to vaccine development, multivalent presentation of pathogen-associated molecular patterns on the particle surface creates powerful platforms for immunotherapy, with the porous matrix able to carry both antigens and immune modulators.

Original language	English (US)
Pages (from-to)	834-841
Number of pages	8
Journal	Current Opinion in Pharmacology
Volume	13
Issue number	5
DOIs	https://doi.org/10.1016/j.coph.2013.06.006
State	Published - Oct 2013

ASJC Scopus subject areas

Pharmacology
Drug Discovery

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title = "Porous silicon advances in drug delivery and immunotherapy",

abstract = "Biomedical applications of porous silicon include drug delivery, imaging, diagnostics and immunotherapy. This review summarizes new silicon particle fabrication techniques, dynamics of cellular transport, advances in the multistage vector approach to drug delivery, and the use of porous silicon as immune adjuvants. Recent findings support superior therapeutic efficacy of the multistage vector approach over single particle drug delivery systems in mouse models of ovarian and breast cancer. With respect to vaccine development, multivalent presentation of pathogen-associated molecular patterns on the particle surface creates powerful platforms for immunotherapy, with the porous matrix able to carry both antigens and immune modulators.",

author = "Savage, {David J.} and Xuewu Liu and Curley, {Steven A.} and Mauro Ferrari and Serda, {Rita E.}",

note = "Funding Information: This research was supported by the National Institute of Health Grant U54CA151668 and U54CA143837 . ",

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AU - Savage, David J.

AU - Liu, Xuewu

AU - Curley, Steven A.

AU - Ferrari, Mauro

AU - Serda, Rita E.

N1 - Funding Information: This research was supported by the National Institute of Health Grant U54CA151668 and U54CA143837 .

PY - 2013/10

Y1 - 2013/10

N2 - Biomedical applications of porous silicon include drug delivery, imaging, diagnostics and immunotherapy. This review summarizes new silicon particle fabrication techniques, dynamics of cellular transport, advances in the multistage vector approach to drug delivery, and the use of porous silicon as immune adjuvants. Recent findings support superior therapeutic efficacy of the multistage vector approach over single particle drug delivery systems in mouse models of ovarian and breast cancer. With respect to vaccine development, multivalent presentation of pathogen-associated molecular patterns on the particle surface creates powerful platforms for immunotherapy, with the porous matrix able to carry both antigens and immune modulators.

AB - Biomedical applications of porous silicon include drug delivery, imaging, diagnostics and immunotherapy. This review summarizes new silicon particle fabrication techniques, dynamics of cellular transport, advances in the multistage vector approach to drug delivery, and the use of porous silicon as immune adjuvants. Recent findings support superior therapeutic efficacy of the multistage vector approach over single particle drug delivery systems in mouse models of ovarian and breast cancer. With respect to vaccine development, multivalent presentation of pathogen-associated molecular patterns on the particle surface creates powerful platforms for immunotherapy, with the porous matrix able to carry both antigens and immune modulators.

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Porous silicon advances in drug delivery and immunotherapy

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