about
pH Responsiveness of Multilayered Films and Membranes Made of Polysaccharides.Bending of layer-by-layer films driven by an external magnetic field.Polymer micro- and nanocapsules as biological carriers with multifunctional properties.Drug co-loading and pH-sensitive release core-shell nanoparticles via layer-by-layer assembly.Chitosan/siRNA functionalized titanium surface via a layer-by-layer approach for in vitro sustained gene silencing and osteogenic promotion.Nanostructured thin film polymer devices for constant-rate protein deliveryNanocoating for biomolecule delivery using layer-by-layer self-assembly.Red blood cells and polyelectrolyte multilayer capsules: natural carriers versus polymer-based drug delivery vehicles.Cholesterol--a biological compound as a building block in bionanotechnology.25th anniversary article: what can be done with the Langmuir-Blodgett method? Recent developments and its critical role in materials science.Bioresorbable polyelectrolytes for smuggling drugs into cells.Layer-by-Layer Assemblies for Cancer Treatment and Diagnosis"Smart" Materials Based on Cellulose: A Review of the Preparations, Properties, and Applications.Programmable biomaterials for dynamic and responsive drug delivery.Biomimetic Extracellular Environment Based on Natural Origin Polyelectrolyte Multilayers.Quantitative assessment of photostability and photostabilisation of Fluvoxamine and its design for actinometry.Immersive polymer assembly on immobilized particles for automated capsule preparation.Preparation of nano- and microcapsules by electrophoretic polymer assembly.Nanostructured hollow tubes based on chitosan and alginate multilayers.Encapsulation of Multiple Microalgal Cells via a Combination of Biomimetic Mineralization and LbL Coating.Dual growth factor delivery using biocompatible core-shell microcapsules for angiogenesis.Multicompartmental Microcapsules with Orthogonal Programmable Two-Way Sequencing of Hydrophobic and Hydrophilic Cargo Release.Construction, Enzyme Response, and Substrate Capacity of a Hyaluronan-Cyclodextrin Supramolecular Assembly.Near-incompressible faceted polymer microcapsules from metal-organic framework templates.Layer-by-layer assembled polymeric thin films as prospective drug delivery carriers: design and applicationsLight responsive multilayer surfaces with controlled spatial extinction capabilityLayer-by-Layer Assembly of Light-Responsive Polymeric Multilayer Systems“Smart” Surface Capsules for Delivery DevicesMultifunctional sensors based on silicone hydrogel and their responses to solvents, pH and solution compositionWater Sensitive Coatings Deposited by Aerosol Assisted Atmospheric Plasma Process: Tailoring the Hydrolysis Rate by the Precursor ChemistryPolyelectrolyte micro- and nanocapsules with varied shell permeability controlling the rate of esters hydrolysisLayer-by-layer microcapsules for pH-controlled delivery of small moleculesMechanical strength and intracellular uptake of CaCO3-templated LbL capsules composed of biodegradable polyelectrolytes: the influence of the number of layers
P2860
Q30316090-FE43C7F0-5BAF-4C5E-B3D0-F5177FA99946Q30542780-8033C3E1-5FDB-4FAE-8953-2072A1872B8DQ35116954-00C036A9-A26A-479C-B100-7884966AA2E7Q35192978-E805C578-3EBF-4ED8-B4E1-EE28238F2D0DQ35229022-DD9863A3-0448-40F2-A3D3-F0E89127DBDBQ36344850-98FFCB82-32F0-448C-8F34-588C2D96EEF6Q36807989-BAB16133-D644-49E6-8963-3380C84F72A4Q38053177-1068AA6B-3F87-41A1-A9BB-89A8A0B34963Q38061564-AC5B1D25-74F4-473E-83E5-1CF11D2B24C3Q38168492-23A7CF08-EED6-4296-829B-A8FC4D459B59Q38471660-CBF9A3C8-93E5-4B3D-B2A9-80A106DCD3C9Q38590390-2CA79269-D69A-448E-A6CE-ECF6AF437412Q38624141-41BC8390-0353-469A-82F2-F9684506A3CDQ38837032-1F0B210F-25BA-4D10-A746-7C321C2BF868Q38902524-C3828A17-DA63-4C88-BA30-2CC4FE0E124FQ41188725-10F1F445-BD11-4A90-B7E9-A700ED978A33Q43814160-EE6E944A-9C00-4D0E-ABF5-51B9E5A5F8C1Q44191503-56806376-E5CA-4A35-B75F-59F6968C027AQ46783181-8FD73538-DD99-4B6D-A4AA-0CA77AC9E5C6Q50041953-AB815B83-2A5E-46B1-84F9-8FF65974D861Q51068891-5B4A7EC8-4F2E-4EB2-B319-58B5420EAB8DQ51436011-2C1B4716-FAD8-487C-9D14-01B51E911B05Q51650321-535984C5-DBDB-4A6B-9CFF-3C08476A60CEQ51790983-E96D971E-A5F8-4EBA-A6AE-5B281FD54C2BQ57069036-2CB539FE-7BCE-4B77-B958-32A8E6DCB0BEQ57170829-7D239A69-EA88-4DBB-BAB4-D34AB5EAB9ADQ57171144-FD3DA22A-8D97-4AEB-A8AE-B7820FC8FFFEQ57341622-32C30137-76FF-4C8F-A92D-2916FC53ED69Q57343909-D75FBF88-A04D-41F7-AE7F-9D18A4B2F8E7Q57345298-2523973E-7E73-4FA0-8212-38FF5F29A3C1Q57351651-DA4A8EBD-CA98-4C32-8AF4-5A05D2653152Q57353636-9FE35DF0-8610-4F33-A10A-A02963331B93Q58036575-B0892B16-CA3E-4D6C-B935-394DDC40E7E5
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Responsive layer-by-layer materials for drug delivery.
@en
Responsive layer-by-layer materials for drug delivery.
@nl
type
label
Responsive layer-by-layer materials for drug delivery.
@en
Responsive layer-by-layer materials for drug delivery.
@nl
prefLabel
Responsive layer-by-layer materials for drug delivery.
@en
Responsive layer-by-layer materials for drug delivery.
@nl
P1476
Responsive layer-by-layer materials for drug delivery.
@en
P2093
Benjamin M Wohl
Johan F J Engbersen
P356
10.1016/J.JCONREL.2011.08.035
P407
P577
2011-09-06T00:00:00Z