Tailoring width of microfabricated nanochannels to solute size can be used to control diffusion kinetics.
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Nanostructured materials for ocular delivery: nanodesign for enhanced bioadhesion, transepithelial permeability and sustained deliveryMicroelectromechanical systems and nephrology: the next frontier in renal replacement technology.Emerging synergy between nanotechnology and implantable biosensors: a reviewUse of a nanoporous biodegradable miniature device to regulate cytokine release for cancer treatmentEnabling individualized therapy through nanotechnologyMembranes to achieve immunoprotection of transplanted islets.Analysis of gene expression on anodic porous alumina microarrays.Leveraging electrokinetics for the active control of dendritic fullerene-1 release across a nanochannel membrane.Nanoscale porosity in polymer films: fabrication and therapeutic applicationsModeling Pressure-Driven Transport of Proteins through a Nanochannel.Reservoir-based drug delivery systems utilizing microtechnology.Nanostructured thin film polymer devices for constant-rate protein deliveryControlled-release microchips.Microfabricated nanochannel implantable drug delivery devices: trends, limitations and possibilities.Sustained Administration of Hormones Exploiting Nanoconfined Diffusion through Nanochannel MembranesSilicon micro- and nanofabrication for medicineMicrofabricated implants for applications in therapeutic delivery, tissue engineering, and biosensing.Drug delivery from internally implanted biomedical devices used in traumatology and in orthopedic surgery.Drug delivery from structured porous inorganic materials.Silicon-polymer hybrid materials for drug delivery.Emerging microtechnologies for the development of oral drug delivery devices.Characterization of nanoporous surfaces as templates for drug delivery devices.Nanotemplating of biodegradable polymer membranes for constant-rate drug delivery.Size-selective molecular transport through silica colloidal nanopores.Controlled release of bupivacaine HCl through microchannels of biodegradable drug delivery device.Transition from single-file to two-dimensional diffusion of interacting particles in a quasi-one-dimensional channel.Bursts in single-file motion mediated conduction.Non-polymer drug-eluting coronary stents.Nanoflow hydrodynamics.Self-Assembled Nanoporous Membranes for Controlled Drug Release and Bioseparation
P2860
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P2860
Tailoring width of microfabricated nanochannels to solute size can be used to control diffusion kinetics.
description
2005 nî lūn-bûn
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2005年の論文
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2005年学术文章
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2005年学术文章
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2005年学术文章
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2005年学术文章
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2005年学术文章
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2005年學術文章
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name
Tailoring width of microfabric ...... to control diffusion kinetics.
@en
Tailoring width of microfabric ...... to control diffusion kinetics.
@nl
type
label
Tailoring width of microfabric ...... to control diffusion kinetics.
@en
Tailoring width of microfabric ...... to control diffusion kinetics.
@nl
prefLabel
Tailoring width of microfabric ...... to control diffusion kinetics.
@en
Tailoring width of microfabric ...... to control diffusion kinetics.
@nl
P2093
P1476
Tailoring width of microfabric ...... to control diffusion kinetics.
@en
P2093
Anthony Boiarski
Frank Martin
John Shapiro
Mauro Ferrari
Michael Cohen
Robbie Walczak
P304
P356
10.1016/J.JCONREL.2004.09.024
P407
P577
2005-01-01T00:00:00Z