Photofabrication of 3D Protein Hydrogels for Nanobiotechnology Applications
Hydrogels introduction and applications in biology and en
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Transcript of Hydrogels introduction and applications in biology and en
HYDROGELS: Introduction and
Applications in Biology and Engineering
Jorge E. Roldan Louisiana Tech University
Dept. of Biological SciencesJune 25, 2003
OVERVIEWWhat are Hydrogels?
IntroductionApplicationsTypesProperties Advantages and Disadvantages
Why Hydrogels?Tissue engineering Cell Culture SystemsDrug deliveryScaffolds
Conclusion
What are Hydrogels?
Water-swollen, crosslinked polymeric structure produced by reactions of monomers or by hydrogen bonding
Hydrophilic polymers that can absorb up to thousands of times their dry weight in H2O
Three-dimensional insoluble polymer networks
Applications of Hydrogels
Soft contact lensesPills/capsulesBioadhesive carriersImplant coatingsTransdermal drug deliveryElectrophoresis gelsWound healingChromatographic packaging material
Types of Hydrogels
Classification Method of preparation
Homo-polymer, Copolymer, Multi-polymer, Interpenetrating polymeric
Ionic chargeNeutral, Catatonic, Anionic, Ampholytic
Physical structureAmorphous, Semi-crystalline, Hydrogen-bonded
Types of Hydrogels
Physical Polyanion + Multivalent Cation = “Iontropic” Hydrogels
Chemical Polyanion + Polycation = Polyion Complex Hydrogels
Types of Hydrogels
Natural Polymers Dextran, Chitosan, Collagen, Dextran Sulfate
AdvantagesGenerally have high biocompatibilityIntrinsic cellular interactionsBiodegradableCell controlled degradabilityLow toxicity byproducts
DisadvantagesMechanical StrengthBatch variationAnimal derived materials may pass on viruses
Types of Hydrogels
Synthetic Polymers PEG-PLA-PEG, Poly (vinyl alcohol)
AdvantagesPrecise control and mass producedCan be tailored to give a wide range of properties (can be
designed to meet specific needs)Low immunogenecity Minimize risk of biological pathogens or contaminants
DisadvantagesLow biodegradabilityCan include toxic substances
Combination of natural and synthetic Collagen-acrylate, P (PEG-co-peptides)
Properties of Hydrogels
Swelling properties influenced by changes in the environment pH, temperature, ionic strength, solvent
composition, pressure, and electrical potential
Can be biodegradable, bioerodible, and bioabsorbable
Can degrade in controlled fashion
Properties of Hydrogels
Pore Size
Fabrication techniques
Shape and surface/volume ratio
H2O content
Strength
Swelling activation
Advantages of Hydrogels
Environment can protect cells and other substances (i.e. drugs, proteins, and peptides)
Timed release of growth factors and other nutrients to ensure proper tissue growth
Good transport properties
Biocompatible
Can be injected
Easy to modify
Disadvantages of Hydrogels Low mechanical strength
Hard to handle
Difficult to load
Sterilization
Why Hydrogels?
Tissue EngineeringScaffolds for tissue engineering
Cell Culture Systems“In vivo conditions are not accurately mimicked
in the majority of cell culture systems”
Drug DeliveryTime released delivery
Why Hydrogels?: Background PhysiologyCell Phenotype
The expression of a specific trait.
Phenotype Regulation Environmental influences
ECM determines adhesion factors, mechanical signals, and growth factors (i.e. CTGF, TGFβ, and Activin)
Internal genetic programsDifferent combinations of receptors may cause differences in
gene expression
Cell Differentiation To become specialized
Dependent on biochemical signals & ECM moleculesDue to mechanical forces resulting from the spatial orientation
cells grow in
Why Hydrogels?: Background Physiology
An accurate understanding of the mechanisms by which cells interact with scaffold, is critical if one wishes to design and control cell phenotype and ultimate tissue structure (i.e. surface chemistry, 3-D space and tensional forces)
Why Hydrogels ?: Tissue Engineering/Cell Culture Systems
Scaffold provides extracellular matrix:Cell adhesion sitesControl of tissue form and thus functionDiffusion of growth factors, metabolites, and
nutrients
Build it, Shape it, and Seed it with cells and nutrients
Why Hydrogels ?: Tissue Engineering BiocompatibleH2O content SterilizibiltyEase of useHigh mechanical
Strength Surface to volume ratioGood cell adhesion High nutrient transport
Why Hydrogels?: Cell Culture SystemsBiocompatible substrate
Non-toxic and have no immunological responses
Cytoarchitecture which favors cell growthFlexibility for cells to rearrange in 3-D
orientationSeeded with appropriate growth and adhesion
factorsPorosity (i.e. channels for nutrients to be
delivered)
Why Hydrogels?: Cell Culture SystemsMimic cytomechanical situations
3-D space provides balanced cytoskeleton forces
Dynamic loading to promote cell growth
FlexibilityProvide scaffold for various cells
Consistent, reproducible and easy to construct
Why Hydrogels?: Drug DeliverySafe degradation productsBiocompatible High loading with ensured molecule efficacy High encapsulationVariable release profile Stable Inexpensive High quality
Conclusion
Hydrogels are network polymers that swell through a variety of mechanisms in an aqueous environment
Environment controls mechanisms of swelling:pH, ionic strength, solvent composition,
pressure and even electric fieldsApplications in medicine, engineering, and
biology
Questions