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Engineering Nanocellulose Biointerfaces Toward Bioactivity and Strength
Maija Vuoriluoto
Not published at VTT
Aalto University
Research output
:
Thesis
›
Dissertation
›
Collection of Articles
Overview
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Dive into the research topics of 'Engineering Nanocellulose Biointerfaces Toward Bioactivity and Strength'. Together they form a unique fingerprint.
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Keyphrases
Nanocellulose
100%
Bioactivity
100%
Biointerface
100%
TEMPO-oxidized CNF
100%
EDC-NHS
75%
Copolymer
50%
Hemoglobin
50%
Adsorption
37%
Passivation
37%
Block Copolymer
25%
Wet Strength
25%
Quartz Crystal Microbalance with Dissipation (QCM-D)
25%
Nanopaper
25%
Surface Plasmon Resonance
25%
Random Copolymer
25%
Wet-spun
25%
Biomaterials
12%
Nanofibrils
12%
Cellulose
12%
TEMPO Oxidation
12%
Water Resistance
12%
High Density
12%
Fouling
12%
Functional Properties
12%
Material Properties
12%
Electrostatic Interaction
12%
Cellulosic Materials
12%
Biomedical Applications
12%
Poly(N,N-dimethylaminoethyl methacrylate)
12%
Low Density
12%
Anionic Groups
12%
Surface Analysis
12%
Application Development
12%
Cellulose Nanomaterials
12%
Oligo(ethylene glycol) Methyl Ether Methacrylate
12%
False Response
12%
Anti-human IgG
12%
Human IgG
12%
Antifouling
12%
Regenerated Cellulose
12%
Polymer Adsorption
12%
Surface Behavior
12%
Oligo
12%
Molecular Architecture
12%
Charge Neutralization
12%
Biosensor Development
12%
System Sensitivity
12%
Fluorescent Labeling
12%
Electrostatic Charge
12%
Nonspecific Adsorption
12%
Human Serum Albumin
12%
Blocking Ratio
12%
UV Activation
12%
Bioactivation
12%
Secondary Antibody
12%
Polymer Architecture
12%
Secondary Activation
12%
IgG Adsorption
12%
Anti-IgG
12%
Activation Cycle
12%
High Efficiency
12%
Bioactive Molecules
12%
Fold Increase
12%
Ultrathin Films
12%
Media Density
12%
Aminobenzophenone
12%
INIS
engineering
100%
copolymers
100%
adsorption
85%
surfaces
71%
hemoglobin
57%
filaments
42%
passivation
42%
architecture
28%
polymers
28%
water
28%
coupling
28%
cellulose
28%
sensitivity
28%
methacrylates
28%
monitoring
28%
charges
28%
resonance
28%
humans
28%
randomness
28%
crystals
28%
quartz
28%
electrostatics
28%
plasmons
28%
microbalances
28%
modifications
14%
efficiency
14%
density
14%
interactions
14%
applications
14%
interfaces
14%
substrates
14%
affinity
14%
molecules
14%
interference
14%
cross-linking
14%
oxidation
14%
nanomaterials
14%
thin films
14%
testing
14%
antibodies
14%
fouling
14%
tuning
14%
ethylene glycols
14%
fluorescence
14%
blocking
14%
methyl ether
14%
human serum albumin
14%
Agricultural and Biological Sciences
Surface Plasmon Resonance
100%
Cellulosic Materials
50%
Ethylene
50%
Biosensor
50%
Nanomaterial
50%
Fouling
50%
Propylene Glycol
50%
Human Serum Albumin
50%
Immunology
50%
Material Science
Nanocellulose
100%
Carbon Nanofiber
100%
Copolymer
26%
Surface Plasmons
8%
Surface (Surface Science)
8%
Materials Property
4%
Nanostructured Material
4%
Analytical Method
4%
Bioactive Material
4%
Polymer Architecture
4%
Electrostatic Interaction
4%
Polymer Adsorption
4%
Block Copolymer
4%
Density
4%
Oxidation Reaction
4%
Ultrathin Film
4%
Pharmacology, Toxicology and Pharmaceutical Science
Nanocellulose
100%
Carbon Nanofibre
100%
Copolymer
30%
Silicon Dioxide
8%
Surface Plasmon Resonance
8%
Methacrylate
4%
Bioactivation
4%
Human Serum Albumin
4%
2 Methoxyethanol
4%
Poly[2 (Dimethylamino)ethyl Methacrylate]
4%
Nanomaterial
4%
Chemistry
Bioactivity
100%
TEMPO
43%
Copolymer
17%
Chemical Passivation
13%
Filament
13%
Methacrylate
8%
Random Copolymer
8%
Cellulose
8%
Surface Plasmon Resonance
8%
Block Copolymer
8%
Crosslinking
4%
Adsorption Behavior
4%
Electrostatic Interaction
4%
Anionic Group
4%
Ethyl
4%
Antifouling
4%
Cellulosic Material
4%
Ethylene Glycol
4%
Nanomaterial
4%