Biomimetic Biomaterials for Tissue Regeneration: Physico ...¾To implant a scaffold encouraging cell...
Transcript of Biomimetic Biomaterials for Tissue Regeneration: Physico ...¾To implant a scaffold encouraging cell...
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Biomimetic Biomaterials for Tissue Regeneration:Physico-chemical, Biochemical, and Construct
Strategies
Matteo Santin
School of Pharmacy & Biomolecular SciencesUniversity of Brighton
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Aim of the lecture
To highlight the societal and clinical needs for new biomaterials
To understand the main phases characterising tissue regeneration
To explore biomimetic strategies by models (examples)
To examine their pros and cons
To evaluate their industrial feasibility
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The impact of science in our life
Increasing longevity has been one of the major successes achieved by science and technology in the second half of the 20th
century
At the beginning of the 20th century life expectancy was of 58 years
Today life expectancy has risen to 78 years and this figure is expected to increase sharply in the near future
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The impact of technology in our life
In 1900 the top three causes of death in the US were pneunomia/influenza, tuberculosis etc.
Since 1940’s, most deaths in the US have results from heart disease, cancer, and other lifestyle diseases.
By the end of the 1990’s, lifestyle diseases accounted for more than 60% of all deaths
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Lifestyle diseases
Cardiovascular diseases
Atherosclerosis
Heart attack
Stroke
Cancer
Diabetes
Osteoporosis/Osteoarthritis
Nephritis
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Biomedical implants & clinical needs
Longer implantation times
Longer life expectancy
Insurgence of pathologies in younger subjects
Implantation in pathological tissues
Impaired tissue regeneration
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Paradigm shift
Tissue (re)placementConventional biomaterials substitute the damaged area
Tissue (re)generationBioactive/bioresponsive biomaterials and tissue engineering products able to intervene in the wound healing process and stimulate the physiological formation of new tissue
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Paradigm shift
Complete regenerationTissue engineering approach
Interfacial regeneration in re-placement approaches (e.g. load-bearing applications)
Regenerative surfaces
Regenerative coatings
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Tissue regeneration process
Clot formation Inflammatory response= Platelets =Macrophages
1 2
3 4New matrix formation
=osteblastsTissue regeneration
=Mineralised tissue
Fibrin GrowthFactors
Hyaluronan Collagen
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The inflammatory cells
Neutrophils (acute inflammation)
Monocytes/Macrophages (acute and chronic inflammation)
Giant cells (chronic inflammation)
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macrophage
endothelial and smooth muscle proliferation angiogenesis
IL-1 PDGF TGF-β TNF−α
Fibroblast migration, proliferation, activation
IL-1 PDGF TGF-β
fibroblast
Macrophages dominate the implant surface
ECM remodelling wound contraction
Antigen presentation to lymphocytes
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Events following implantation
Foreign body giant cells
macrophages
neovascularisation
fibroblasts
neutrophils
fibrosisinte
nsity
days weeks monthshours
acute chronic granulation tissue
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The foreign body reaction
“…the body react similarly to nearly all materials that we call biocompatible and walls them off in an avascular, tough, collagenousbag, roughly 50-200 mm thick.”
Castner DG, Ratner BD (2002) Surf. Sci. 500, 28
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The fibrotic capsule formation
a-c: PHEMAd-f: PHEMA/Gelatin IPN
Santin M., Huang S.J., Iannace S., Nicolais L., Ambrosio L. & Peluso G.Synthesis and Characterization of Poly(2-Hydroxyethylmethacrylate)-Gelatin Interpenetrating Polymer Network.Biomaterials, 17, 1459-1467, 1996.
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Blood: the early medium
Photosby Dr. A. MerolliUniversita’ CattolicaRome, Italy
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Tissue integration: a race to the surface
Impl
ant
Ions(mSec)
`
``
`
ProteinsLipids
(mSec)
Cells(h)
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Tissue regeneration approaches
To implant a scaffold encouraging cell adhesion, proliferation and differentiation (in situ regeneration)
Non-active scaffolds
Bioactive scaffolds (releasing growth factors or genes)
To deliver stem cells and differentiated cells (biohybrid)Individual cells
Small cell aggregates
Injected
Combined with a scaffold
To implant a tissue previously engineered in vitro (bioreactor)
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Ideal features of bio-active/responsive biomaterials
To regulate the regeneration of the damaged tissue by
minimising the inflammatory response
Balancing the proliferation/differentiation of tissue cells
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Introduction: Ideal characteristics of a biodegradable biomaterial
To promote the in-growth of the damaged tissue
To resorb at a rate comparable to the growth of the surrounding tissue
To minimise the inflammatory response
To release by-products which do not elicit inflammatory response or toxicity
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Biomaterials composition and engineering
BiomaterialsPolymers
Metals
Ceramics
EngineeringComposites/blends/interpenetrated polymer networks
Coatings
Moulding
Surface grafting of biofunctional molecules
Surface morphology modifications
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Types of biomimetic strategies
Biomimicking of animal structures and functions
Biomimicking of common natural strategies
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Biomimetic strategiesBiomimicking of cell components
Glycocalyx
Lipids
Biomimicking of extracellular matrix components
Fibrin
Hyaluronic acid
Collagen
Apatite of mineralized tissues
Biomimicking of biochemical signalling pathways
Growth factors
Clot formation Inflammatory response= Platelets =Macrophages
1 2
3 4New matrix formation
=osteblastsTissue regeneration
=
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Cell component biomimicking
The polycarboxybetaine model
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The carboxybetaine model
Betaines are a class of plant amino acids able to retain water in the cell
Used in biotechnology as cryoprotectants
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Polycarboxybetaine: advantages/disadvantages
AdvantagesInducing water structuring thus preserving the native conformation of the proteins
Absorbing wound exudates
DisadvantagesPoor mechanical properties
Inertness
Biocompatibility?
Biodegradation rate?
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Cell component biomimicking
The phosphorylcholine model
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The phosporylcholine model
Mimicking of the red cell membrane
Relatively inert
Suitable as monolith or as coating for several applications
Ophthalmology devices
Cardiovascular devices
Drug delivery devices
Phospholipid Bilayer
ProteinCarbohydrate
OUTER SURFACE
INNER SURFACE
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The phosporylcholine polymers: limitations
AdvantagesReduced inflammatory response
Reduced bacterial adhesion
Matrix/coating for drug delivery (i.e. drug eluting cardiovascular stents)
DisadvantagesInert
Non-bioactive
Non-biodegradable
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Cell component biomimicking
The phosphatidylserine model
or
The calcium-binding phospholipid model
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The matrix vesicle model: the mineralization potential of calcium-binding phospholipids
Collagen
MatrixVesicles
Growth factors
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Role of matrix vesicles in bone formation
Ca2+ influx
PhosphateApatite
CollagenMatrixvesicle
ALP
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Biomineralization strategies
Calcium binding moleculelayer with high capacity and
low affinity
Formingcrystal nucleus
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Calcium-binding liposomes
Phosphatidylcholine : X : Cholesterol7 : 2 : 1
X= Phosphatidylserine, phosphatidylinositol
T.E.M. of PC:X:C liposomesin Simulated Body Fluid (SBF)
(Santin M et al, data not published)
Heywood BR, Eanes EDCalcif. Tissue Int. 50, 149-156, 1992
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Calcium-binding phospholipidmodel
Calcium-driven cross-linking of
phospholipid bilayers
Calcium-driven 3D organisationof
phospholipid bilayer
Ca 2+
Wilschut J, Hoekstra D, 1986
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Calcium-binding phospholipidmodel
Santin M et al.Journal of the Royal Society Interface
3, 277-281, 2006
Cryo-SEM of PC:PS:C titanium coatings:a= 7-days incubation in calcium-depleted SBFb= 7-days incubation in SBFc=7-days incubation in SBF after1-h pre-conditioning in serum
A.W. Lloyd, M. Santin, W.G. Love, S.P.Denyer, W. Rhys-Williams,2000, PCT/GB00/03290
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Calcium-binding phospholipids model
a
b c
Incubation of PC:PS:C partially-coated titanium disk in SBFa = visual inspection after7- days incubationb = Cryo-SEM after 1-h incubationc = Cryo-SEM after 1-h incubation in serum-enriched SBF
Santin M et al.Journal of the Royal Society Interface3, 277-281, 2006
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Calcium-binding phospholipids model
Cryo-SEM of PS coating after 7-days incubation in SBFa = exposed surfaceb = fracture surfacec = relative EDX analysis
a b
cSantin M et al.Journal of the Royal Society Interface3, 277-281, 2006
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Calcium-binding phospholipids model: in vitro biocompatibility
Monocytes/macrophagesadhesion and activation
Osteoblast adhesion&
mineralizationBosetti M, Lloyd AW, Santin M, Denyer SP, Cannas M Effects of phosphatidylserinecoatings on titanium on inflammatory cells and cell-induced mineralization in vitroBiomaterials, 26, 7572-7578, 2005
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level of sectioning
Dr. A. MerolliCatholic UniversityRome, Italy
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Calcium-binding phospholipids model: in vivo biocompatibility
Merolli A, Giannotta L, Tranquilli-Leali P, Lloyd AW, Denyer SP, Rhys-Williams R, Love WG, Gabbi C, Cacchioli A, Bosetti M,Cannas M, Santin M. J. Mater Sci: Mater Med, in press
Ti HA
PC:PS:C PS
a=Implant at 4 wksb-d=Implant interfacesb= 4 wksc= 8 wksd= 26 wks
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Calcium-binding phospholipid model: advantages
Liposomes containing calcium binding phospholipids are able to form aggregates with collagen and gelatingels and induce their fast mineralizationCalcium-binding phospholipids are able to self-aggregate in presence of calcium to form highly mineralized hydrogels when incubated in SBFCalcium-binding phospholipids can be used as bone fillers or coating materials
Controlling the inflammatory responsepromoting the deposition of bone mineral phaseFavouring the osteoblast adhesion and mineralization potentialInducing implant integration in vivo
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Poor mechanical properties
Eliciting of the host response tightly linked to the gel composition
Slow degradation/resorption
Calcium-binding phospholipidmodel: disadvantages
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Biomimicking of extracellular matrix components
Functionalised hydrogels
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Poly(ethylene glycol) injectable biomimeticgel for bone tissue engineering
• PEG characteristics:
RGD-modified (Arg-Gly-Asp)
Proteolytically-sensitive (metalloproteinase-sensitive)
carriers for bone marrow stem cellsCell adhesion/Migration motif
MP substrateSakiyama-Elbert SE, Hubbell JA et alAnn Rev Mater Res 31, 183-201, 2001
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Relevant biomimetic sequences
RGD (cell adhesion, integrin, non-specific)105 bioligand/cell
140 nm spacing
YIGSR (cell adhesion, laminin receptor)
REVD (endothelial cells adhesion)
FHRRIKA (osteoblast migration)
GVGVP (monocyte recruitment)
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Relevant biomimetic sequences
GAGAS/GVGVP (silk/elastin mimicking undergoing liquid/solid phase transition in aqueous medium, Cappello et al )
Self assembling peptide systems able to form gels in vivo (Stupp et al., Leon et al.)
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Biomimetic hydrogels
AdvantagesHighly controlled 3D biomimicking environment
Application of the technology to different clinical needs
DisadvantagesPoor mechanical properties
Storage conditions
Scale up/ costs
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Biomimicking of extracellular matrix components
Functionalised metals
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Metal biomimetic functionalisation
Kokubo’s method
TitaniumTiO2 HTiO3Na
NaOH SBFTi-OH
Kokubo T. (1997) USPatent n. 5,609,633
Nanci’s method
TitaniumTiO2
P
R Ti-O
P
R R= Si, S, etc
Nanci A. et al. (1998) US PATENT 5,824,651
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Surface functionalisation with calcium-binding moieties
POO
O
Vinylphosphonicacid
Tanahashi M., Matsuda T. (1997) J. Biomed. Mater. Res., 34: 305-315
Gold SH
RSelf-assembled monolayer
(SAM)
Methacrylicacid
O
O
-
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Metal biomimetic functionalisation
Sarikaya M et al. Ann Rev Mater Res 34:373-408, 2004
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Biomimicking of the biochemical signalling pathways
The growth factor models
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Growth FactorsTransforming Growth factor superfamily
Transforming Growth Factor-β1
Bone Morphogenetic Proteins/Osteopontins
Growth Differentiation Factors
Vascular Endothelial Growth Factor
Platelet Derived Growth Factor
Fibroblast Growth Factor/bFGF
Epithelial Growth Factor
Nerve Growth Factor
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Growth factors advantages
To modulate the different phases of the tissue regeneration process
To favour the selective regeneration of tissues
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Growth factor disadvantages
Effective at relatively high concentrations
Delivery to be controlled
Risk of tumours (?)
Unstable at room conditions
Expensive
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Combined biomimicking of extracellular matrix and biochemical signalling pathways
The soybean biomaterial model
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Soybean composition
Carbohydrates
38%
Minerals
4%Oil
18%
Proteins
40%
Isoflavones
Genistein
Genistin
Daidzein
Daidzin
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Isoflavone effect on eukaryotic cells
Inhibits immunocompetent cells
Plasmalemma receptors (Tyrosine kinase inhibition)
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Isoflavone effect on eukaryotic cells
Inhibits proliferation and induces differentiation of tissue cells
Nuclear membrane receptors (Oestrogen receptor β)
Inhibition of topoisomerase II and block of the G2/M phase
Osteoblast differentiation inducer (ALP, osteoprogeterin, BMP2)
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osteoclast inhibition
Indirect: Through osteoblast synthesis of osteoprogeterin and increased osteoprogeterin/RANKL ratio
Direct: through tyrosine kinaseinhibition?
Isoflavone effect on eukaryotic cells
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Scheme of Biomaterial Preparation by Thermosetting
De-fattedSoybean milk
Coagulationby calcium
PressingSoybean curd
FilmsMembranes
Blocks
setting
Plastic biodegradable material
patent PCT/GB01/03464
granules
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Conclusions
The understanding and modulation of the “Interface Biology” (J. Kirkpatrick) is key to improve both biomaterial and tissue engineering products
The development of a new generation of biomimetic/bio-responsive biomaterials is key to the improve the performances of biomedical devices
They have to respond to the needs for a better quality of life of the population worldwide…