Nanopore Technology for Biomedical Applications

Tejal A. Desai; Derek J. Hansford; Lawrence Kulinsky; Amir H. Nashat; Guido Rasi; Jay Tu; Yuchun Wang; Miqin Zhang; Mauro Ferrari

doi:10.1023/A:1009903215959

Nanopore Technology for Biomedical Applications

Tejal A. Desai, Derek J. Hansford, Lawrence Kulinsky, Amir H. Nashat, Guido Rasi, Jay Tu, Yuchun Wang, Miqin Zhang, Mauro Ferrari

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

175 Scopus citations

Abstract

The ability to create well-defined and controlled interfaces has been an area of great interest over the last few years, particularly in the biomedical arena. This paper will describe the development of technology for the fabrication of nanopore membranes, and their operation in biological environments. With monodisperse pores sizes as small as 10 nanometers, these membranes offer advantages in their reproducibility, and their ability to be integrated with controlled biochemical surface modification protocols. A comprehensive review of results in the areas of nanopore and biocapsule microfabrication technologies, biocompatibility of nanomembrane materials, biologically appropriate post-processing protocols (bonding, sterilization), surface modification protocols, and appropriate mass transport models will be presented. The results point to the potential of using such technologies for therapeutic applications including immunoisolation biocapsules, drug delivery devices, and targeted biorecognition platforms.

Original language	English (US)
Pages (from-to)	11-40
Number of pages	30
Journal	Biomedical Microdevices
Volume	2
Issue number	1
DOIs	https://doi.org/10.1023/A:1009903215959
State	Published - 1999

Keywords

BioMEMS
Membranes
Microfabrication
Nanotechnology
Silicon

ASJC Scopus subject areas

Medicine (miscellaneous)
Genetics
Neuroscience(all)

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10.1023/A:1009903215959

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title = "Nanopore Technology for Biomedical Applications",

abstract = "The ability to create well-defined and controlled interfaces has been an area of great interest over the last few years, particularly in the biomedical arena. This paper will describe the development of technology for the fabrication of nanopore membranes, and their operation in biological environments. With monodisperse pores sizes as small as 10 nanometers, these membranes offer advantages in their reproducibility, and their ability to be integrated with controlled biochemical surface modification protocols. A comprehensive review of results in the areas of nanopore and biocapsule microfabrication technologies, biocompatibility of nanomembrane materials, biologically appropriate post-processing protocols (bonding, sterilization), surface modification protocols, and appropriate mass transport models will be presented. The results point to the potential of using such technologies for therapeutic applications including immunoisolation biocapsules, drug delivery devices, and targeted biorecognition platforms.",

keywords = "BioMEMS, Membranes, Microfabrication, Nanotechnology, Silicon",

author = "Desai, {Tejal A.} and Hansford, {Derek J.} and Lawrence Kulinsky and Nashat, {Amir H.} and Guido Rasi and Jay Tu and Yuchun Wang and Miqin Zhang and Mauro Ferrari",

note = "Funding Information: Financial support for the development of nanomembrane and biocapsule micromachining, biocompatibility, and characterization protocols (TD, MF, DH, LK, JT, YW, MZ) was provided by MicroFab BioSystems, a wholly-owned subsidiary of Vion Pharmaceuticals. The study of antibody grafting and their quantitative detection by confocal microscopy (MF, AN) was supported by the National Science Foundation, through MF's National Young Investigator Award. The authors gratefully acknowledge the support of others that have participated in the projects of UC Berkeley's Biomedical Microdevices Center, and have directly influenced the research presented herein: Ruby Chen, Wen-Hua Chu, Tony Huen, Mario Moronne, and Robert Szema.",

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AU - Desai, Tejal A.

AU - Hansford, Derek J.

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AU - Rasi, Guido

AU - Tu, Jay

AU - Wang, Yuchun

AU - Zhang, Miqin

AU - Ferrari, Mauro

N1 - Funding Information: Financial support for the development of nanomembrane and biocapsule micromachining, biocompatibility, and characterization protocols (TD, MF, DH, LK, JT, YW, MZ) was provided by MicroFab BioSystems, a wholly-owned subsidiary of Vion Pharmaceuticals. The study of antibody grafting and their quantitative detection by confocal microscopy (MF, AN) was supported by the National Science Foundation, through MF's National Young Investigator Award. The authors gratefully acknowledge the support of others that have participated in the projects of UC Berkeley's Biomedical Microdevices Center, and have directly influenced the research presented herein: Ruby Chen, Wen-Hua Chu, Tony Huen, Mario Moronne, and Robert Szema.

PY - 1999

Y1 - 1999

N2 - The ability to create well-defined and controlled interfaces has been an area of great interest over the last few years, particularly in the biomedical arena. This paper will describe the development of technology for the fabrication of nanopore membranes, and their operation in biological environments. With monodisperse pores sizes as small as 10 nanometers, these membranes offer advantages in their reproducibility, and their ability to be integrated with controlled biochemical surface modification protocols. A comprehensive review of results in the areas of nanopore and biocapsule microfabrication technologies, biocompatibility of nanomembrane materials, biologically appropriate post-processing protocols (bonding, sterilization), surface modification protocols, and appropriate mass transport models will be presented. The results point to the potential of using such technologies for therapeutic applications including immunoisolation biocapsules, drug delivery devices, and targeted biorecognition platforms.

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Nanopore Technology for Biomedical Applications

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