Sequential Growth Factor Delivery From Polymeric Scaffolds For Bone Tissue Engineering

Yilgor, Pinar

01 September 2009

Tissue engineering is a promising alternative strategy to produce artificial bone substitutes / however, the control of the cell organization and cell behavior to create fully functional 3-D constructs has not yet been achieved. To overcome these, activities have been concentrated on the development of multi-functional tissue engineering scaffolds capable of delivering the required bioactive agents to initiate and control cellular activities. The aim of this study was to prepare tissue engineered constructs composed of polymeric scaffolds seeded with mesenchymal stem cells (MSCs) carrying a nanoparticulate growth factor delivery system that would sequentially deliver the growth factors in order to mimic the natural bone healing process. To achieve this, BMP-2 and BMP-7, the osteogenic growth factors, were encapsulated in different polymeric nanocapsules (poly(lactic acid-co-glycolic acid) (PLGA) and poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV)) with different properties (degradation rates, crystallinity) and, therefore, different release rates to achieve the early release of BMP-2 followed by the release of BMP-7, as it is in nature. Initially, these nanoparticulate delivery systems were characterized and then the effect of single, simultaneous and sequential delivery of BMP-2 and BMP-7 from these delivery systems was studied in vitro using rat bone marrow MSCs. The effect of using these two growth factors in a sequential manner by mimicking their natural bioavailability timing was shown with maximized osteogenic activity results. BMP-2 loaded PLGA nanocapsules were subcutaneously implanted into Wistar rats and according to initial results, their biocompatibility as well as the positive effect of BMP-2 release on the formation of osteoclast-like cells was shown. To complete the construction of the bioactive scaffold, this nanoparticulate sequential delivery system was incorporated into two different types of polymeric systems / natural (chitosan) and synthetic (poly(&amp / #949 / -caprolactone) (PCL)). 3-D fibrous scaffolds were produced using these materials by wet spinning and 3-D plotting. Incorporation of nanocapsules into 3-D chitosan scaffolds was studied by two different methods: incorporation within and onto chitosan fibers. Incorporation into 3-D PCL scaffolds was achieved by coating the nanocapsules onto the fibers of the scaffolds in an alginate layer. With both scaffold systems, incorporation of nanocapsule populations capable of delivering BMP-2 and BMP-7 in single, simultaneous and sequential fashion was achieved. As with free nanocapsules, the positive effect of sequential delivery on the osteogenic differentiation of MSCs was shown with both scaffold systems, creating multi-functional scaffolds capable of inducing bone healing.

Isolation Of Antimicrobial Molecules From Agricultural Biomass And Utilization In Xylan-based Biodegradable Films

Cekmez, Umut

01 January 2010

Cotton stalk lignin extractions were performed via alkaline methods at different conditions. Crude and post treated cotton stalk lignins, olive mill wastewater and garlic stalk juice were examined in terms of antimicrobial activity. Antimicrobial lignin was isolated depending on alkaline extraction conditions. Lignin extracted at 60&deg / C exhibited significant antimicrobial effect towards both Escherichia coli and Bacillus pumilus. However different post treatments such as ultrasonication and TiO2-assisted photocatalytic oxidation did not result in antimicrobial compounds. Olive mill wastewater and garlic stalk juice exerted substantial antimicrobial effects towards tested microorganisms. Xylan-based biodegradable films containing lignin, garlic stalk juice, tannic acid and olive mill wastewater were characterized against both B. pumilus and E. coli by means of their antimicrobial activities. E. coli exhibited lesser sensitivity to all tested antimicrobial xylan films except tannic acid-integrated xylan film than B. pumilus. Antimicrobial lignin integrated-xylan film exhibited stronger effect towards tested microorganisms than tannic acid-integrated film. In the case of both antimicrobial lignin and tannic acid integrated xylan films, 4% was found to be the maximum antimicrobial compound percentage in film forming solutions to observe continuous film formation. Lignin samples with/without antimicrobial activity were characterized by means of their chemical structure via FTIR and LC-MS. FTIR results revealed that cotton stalk lignins were significantly broken down via alkaline treatment and this breakdown resulted in the formation of new fractions and also ester &amp / ether bonds between antimicrobial hydroxycinnamic acids and lignin were cleaved during the alkaline treatments of cotton stalk lignins. By FTIR results, C=C bonds were found to be characteristic for antimicrobial lignin sample and it was suggested that these bonds might be the reason of the antimicrobial activity. By LC-MS qualitative mass analysis, antibacterial lignin fractions were found to be quite different from non-antibacterial lignin fractions. LC-MS results indicated that the antimicrobial lignin fractions might be lignin-derived oligomers and/or might be flavonoids. Cotton stalk lignin fractions demonstrated different antimicrobial activities depending on the method of isolation and chemical treatment.

QD Aromatic Compounds 330-341

Polyketals: a new drug delivery platform for treating acute liver failure

Yang, Stephen Chen

22 October 2008

Acute liver failure is a major cause of death in the world, and effective treatments are greatly needed. Liver macrophages (Kupffer cells) play a major role in the pathology of acute liver failure, and drug delivery vehicles that can target therapeutics to Kupffer cells have great therapeutic potential for treating acute liver failure. Microparticles, formulated from biodegradable polymers, are advantageous for treating acute liver failure because they can passively target therapeutics to Kupffer cells. However, existing biomaterials are not suitable for the treatment of acute liver failure because of their slow hydrolysis and acidic degradation products. In this dissertation, I present the development of a new class of biodegradable materials, termed aliphatic polyketals, which have considerable potential as drug delivery vehicles for the treatment of acute liver failure because of their neutral degradation products and tunable hydrolysis kinetics. The anti-inflammatory enzyme, superoxide dismutase (SOD), was delivered using polyketal microparticles to the liver for treating acute liver Failure. Our results demonstrated that polyketal microparticles significantly improved the efficacy of SOD in treating LPS-induced acute liver damage in vivo, as evidenced by decreased levels of serum alanine transaminase, which corresponds to the extent of damage in the liver, and serum level of tumor necrosis factor-alpha, which corresponds to the secretion of pro-inflammatory cytokines. The completion of this thesis research demonstrates the ability of polyketal-based drug delivery systems for treating acute inflammatory diseases and creates a potential therapy for enhancing the treatment of acute liver failure.

Acute liver failure

Microparticles

Biodegradable polymer

Drug delivery

Polyketal

Drug delivery systems

Polymeric drug delivery systems

Polymers in medicine

Liver Failure

Aliphatic compounds

PLA and cellulose based degradable polymer composites

Oka, Mihir Anil

06 April 2010

We studied PLA-microcrystalline cellulose composites, focusing on the effects of processing, particle size and surface modification. The thermal and mechanical properties of these PLA based composites were studied and the effect of cellulose addition on PLA degradation was analyzed. For our system, the degradation rate was found to depend on initial sample crystallinity, pH of the degradation media and cellulose content of the composite. Composites were prepared using solution processing and melt mixing methods. The processing methods influenced the polymer's ability to crystallize affecting the mechanical properties. Isothermal crystallization studies carried out to study the kinetics of crystallization showed melt processed samples to have lower half time for crystallization and higher value for the Avrami exponent. The crystallization rate of PLA was also found to depend on surface chemical composition of cellulose particles and the particle size. Influence of filler surface modification on the composite properties was studied via grafting of lactic acid and polylactic acid to cellulose particles and the effect of filler size was studied using hydrolyzed microcrystalline cellulose particles. A simple esterification reaction that required no external catalyst was used for surface modification of cellulose particles. Surface modification of cellulose particles enhanced the static and dynamic mechanical properties of the composite samples due to improvement in the PLA-cellulose compatibility that resulted in better interfacial interactions. The utility of cellulose, available from a renewable resource, as an effective reinforcement for PLA is demonstrated.

Renewable

Cellulose nanowhiskers

Degradation

Surface modification

Cellulose

Polylactic acid (PLA)

Hydrolysis

Interfacial adhesion

Polymeric composites

Biodegradable plastics

Renewable natural resources

Cellulose

Lactic acid

Properties of biologically relevant nanocomposites: effects of calcium phosphate nanoparticle attributes and biodegradable polymer morphology

Kaur, Jasmeet

05 April 2010

This research is directed toward understanding the effect of nanoparticle attributes and polymer morphology on the properties of the nanocomposites with analogous nanoparticle chemistry. In order to develop this understanding, polymer nanocomposites containing calcium phosphate nanoparticles of different specific surface areas and shapes were fabricated and characterized through thermal and thermomechanical techniques. Nanoparticles were synthesized using reverse microemulsion technique. For nanocomposites with different surface area particles, the mobility of amorphous polymer chains was restricted significantly by the presence of particles with an interphase network morphology at higher loadings. Composites fabricated with different crystallinity matrices showed that the dispersion characteristics and reinforcement behavior of nanoparticles were governed by the amount of amorphous polymer fraction available. The study conducted on the effect of nanoparticle shape with near-spherical and nanofiber nanoparticles illustrated that the crystallization kinetics and the final microstructure of the composites was a function of shape of the nanoparticles. The results of this research indicate that nanoparticle geometry and matrix morphology are important parameters to be considered in designing and characterizing the structure-property relationship in polymer nanocomposites.

Matrix morphology

Nanoparticle attributes

Matrix crystallinity

Surface area

Nanofiber

Biodegradable

Polyhydroxybutyrate

Polycaprolactone

Nanocomposites

Calcium phosphate

Nanoparticles

Hydroxyapatite

Nanocomposites (Materials)

Calcium phosphate

Polymers

Morphology

Biodegradation

Strategies for building polymers from renewable sources : Using prepolymers from steam treatment of wood and monomers from fermentation of agricultural products

Söderqvist Lindblad, Margaretha

January 2003

<p>A strategic research area today is development of polymericproducts made from renewable sources. The ways of utilizingrenewable sources studied in this thesis are using 1)prepolymers obtained by steam treatment of wood and 2) monomersobtainable by fermentation of agricultural products.</p><p>Novel hemicellulose-based hydrogels were prepared by usingprepolymers obtained from steam treatment of spruce.Hemicellulose was first modified with well-defined amounts ofmethacrylic functions. Hydrogels were then prepared by radicalpolymerization with 2-hydroxyethyl methacrylate orpoly(ethylene glycol) dimethacrylate to form hydrogels. Theradical polymerization reaction was carried out in water usinga redox initiator system. The hydrogels were in generalelastic, soft and easily swollen in water. Frequency sweeptests indicated that the hydrogel system displayed prevailingsolid-like behavior. Comparison of the hemicellulose-basedhydrogels with pure poly(2-hydroxyethyl methacrylate)-basedhydrogels showed that it was possible to preparehemicellulose-based hydrogels with properties similar to thoseof pure poly(2-hydroxyethyl methacrylate)-based hydrogels.</p><p>Polyester-based materials were prepared by using themonomers 1,3- propanediol and succinic acid obtainable byfermentation. α,ω-Dihydroxyterminatedoligomeric polyesters produced by the thermal polycondensationof 1,3-propanediol and succinic acid were chain-extended toobtain sufficiently high molecular weight. Depending on thechain-extension technology adopted, poly(ester carbonate)s orpoly(ester urethane)s were obtained. In the case of poly(estercarbonate)s, the chain-extended products ofα,ω-dihydroxyterminated oligomeric copolyesters werealso produced using 1,3-propanediol/1,4-cyclohexanedimethanol/succinic acid mixtures toimprove thermal and mechanical properties. Segmented poly(esterether carbonate)s fromα,ω-dihydroxyterminated oligo(propylenesuccinate)s and poly(ethylene glycol) were also synthesized toincrease the hydrophilicity.</p><p>Molecular weights and polydispersity were analyzed by SECfor all materials. Their structures were also identified by NMRspectroscopy (1H NMR and 13C NMR). All characterizations werein agreement with the proposed structures. Thermal parameterswere characterized by DSC. Tensile testing anddynamic-mechanical tests were performed and in additionpreliminary processing trials were carried out in some cases.The results demonstrate the feasibility of using monomersderived from renewable sources to build up new polymericstructures endowed with a variety of physical and mechanicalproperties.</p>

renewable sources

biodegradable polymers

hemicellulose

2-hydroxyethyl methacrylate

modification of hemicellulose

methacrylation reaction

rheology measurements

dynamic-mechanical behavior

1

3-propanediol

1

4-cyclohexanedimethanol

succinic ac

Enhancing Interfacial Bonding of a Biodegradable Calcium Polyphosphate/Polyvinyl-urethane Carbonate Interpenetrating Phase Composite for Load Bearing Fracture Fixation Applications

Guo, Yi

06 April 2010

This thesis describe methods to improve the interfacial stability of an interpenetrating phase composite (IPC) polyvinylurethanecarbonate), and to increase the hydrophobicity of the polymer phase. The current IPCs introduce covalent bonding between the phases via silanizing agents to enhance the interfacial stability. Incorporation of the silanizing agents was also intended to reduce the IPC’s sensitivity to interfacial hydration, thereby enhancing the IPC’s resistance to degradation during aging. Lysine diisocyanate was used to increase the hydrophobic character in the polyvinylurethanecarbonate resin. The polymer resins were infiltrated into porous CPP blocks with 25 volume% interconnected porosity and polymerized to produce the IPCs. After mechanical testing following a aging study it was found that the silanizing agents contributed to stability of the mechanical properties under aqueous conditions. It was concluded that the mechanical properties and stability were comparable to available biodegradable composites, as well as being biocompatible to a preosteoblast model cell line.

Orthopaedic

Interpenetrating Phase Composite

Calcium Polyphosphate

Polyvinylurethane

Fracture Fixation

Load Bearing Bones

Biodegradable Composite

Mechanical Testing

silanizing agents

silane

0541

0794

Development and characterization of high performance solvent cast soy protein isolate composite films

Jensen, Alexander Matthew

25 May 2012

The application of current soy protein films are limited due to their low mechanical strength and high moisture sensitivity compared to synthetic materials. This research studied several methods to improve the mechanical properties [tensile strength (TS), elongation at break (EAB), Young’s modulus of elasticity (YM)] of solvent cast soy protein isolate (SPI) films. Drying times were significantly reduced through the use of a heated casting surface. Neutral (pH 7) SPI films were prepared but were found to have lower TS, EAB and YM than control films prepared under alkaline conditions. Cellulose was extracted from soybean wastes and transmission electron microscopy (TEM) verified the existence of nano-sized fibres. Composite SPI films were prepared using either extracted cellulose fibres or titanium dioxide (TiO2) nanoparticles and their mechanical and barrier properties (water vapour, and oxygen permeability) were evaluated under different relative humidity (RH) conditions. In general, TS and YM decreased and EAB increased with increasing RH. Films with 5% (w/w) added cellulose exhibited significant (p-value < 0.05) improvements in TS and YM but decreased EAB. TiO2 composites possessed similar TS, YM, and EAB values to control films. Barrier properties were comparable across all samples, and decreased with increasing RH. Samples were characterized using Fourier transform infrared (FTIR) spectroscopy, scanning electron microscopy (SEM), and atomic force microscopy (AFM). Preliminary work investigating synthesis of filler materials using cross-linked sodium alginate particles increased the TS and YM of SPI films to a similar extent as extracted cellulose. A method for electrospinning cellulose using ionic liquids was developed, but requires further process optimization to be used for fibre/filler synthesis. / OMAFRA; Hannam Soy Utilization Fund

protein films

soy protein isolate

cellulose

titanium dioxide

composite films

biodegradable films

mechanical properties

water vapour permeability

oxygen permeability

FTIR

SEM

TEM

AFM

relative humidity

electrospinning

ionic liquids

Materials and microfabrication approaches for completely biodegradable wireless micromachined sensors

Luo, Mengdi

12 January 2015

Implantable sensors have been extensively investigated to facilitate diagnosis or to provide a means to generated closed loop control of therapy by yielding in vivo measurements of physical and chemical signals. Biodegradable sensors which degrade gradually after they are no longer functionally needed exhibit great potential in acute or shorter-term medical diagnostic and sensing applications due to the advantages of (a) exclusion of the need to a secondary surgery for sensor removal, and (b) reduction of the risk of long-term infection. The objective of this research is to design and characterize microfabricated RF wireless pressure sensors that are made of completely biodegradable materials and degrade at time-controlled manner (in the order of years and months). This was achieved by means of investigation of appropriate biodegradable materials and development of appropriate fabrication processes for these non-standard (Microelectromechanical systems) MEMS materials. Four subareas of research are performed: (1) Design of sensors that operate wirelessly and are made of biodegradable materials. The structure of the wireless sensor consists a very compact and relatively simple design of passive LC resonant circuits embedded in a polymer dielectric package. To design the sensor with a particular resonant frequency range, an electromagnetic model of the sensor and a mechanical model for circular plate are developed. The geometry of the sensor is established based on the analytical and finite element simulations results. (2) Investigation of the biodegradable materials in the application of implantable biodegradable wireless sensors to achieve controllable degradation lifetimes. Commercially available and FDA approved biodegradable polymers poly(L-lactic acid) (PLLA) and a "shell-core" structure of poly(lactic-co-glycolic acid) (PLGA) and polyvinyl alcohol (PVA) are utilized as the dielectric package for slow and rapid degradation sensors, respectively. Biodegradable metallic zinc and zinc/iron couples are chosen as conductor materials. The degradation behavior of Zn and Zn/Fe-couple are investigated in vitro. (3) Development of novel fabrication processes. The process exploit the advantages of MEMS technology in fabricating miniaturized devices, while protecting vulnerable biodegradable materials from the strong and/or hazardous chemicals that are commonly used in conventional MEMS fabrication process. These new processes enable the fabrication of biocompatible and biodegradable 3-D devices with embedded, near-hermetic cavities. (4) Testing the pressure response functionality and studying the degradation behavior of the wireless biodegradable pressure sensors. Both PLLA-based and PLGA/PVA-based sensors are characterized in vitro by being immersed in 0.9% saline for prolonged time. All the sensors exhibit three stages of behavior in vitro: equilibration, functional lifetime, and performance degradation. During the functional lifetime, most sensors exhibit fully stable functionality. The PLLA-based sensors show no significant weight loss within 8 month and are expected to fully degrade after 2 years, while the PLGA/PVA-based sensors can degrade completely within 26 days.

MEMS

Biodegradable sensors

Wireless passive sensors

RF pressure sensors

Galvanic corrosion

Poly(lactic acid)

Poly(lactic-co-glycolic acid)

In vitro degradation

Enhancing Interfacial Bonding of a Biodegradable Calcium Polyphosphate/Polyvinyl-urethane Carbonate Interpenetrating Phase Composite for Load Bearing Fracture Fixation Applications

Guo, Yi

06 April 2010

This thesis describe methods to improve the interfacial stability of an interpenetrating phase composite (IPC) polyvinylurethanecarbonate), and to increase the hydrophobicity of the polymer phase. The current IPCs introduce covalent bonding between the phases via silanizing agents to enhance the interfacial stability. Incorporation of the silanizing agents was also intended to reduce the IPC’s sensitivity to interfacial hydration, thereby enhancing the IPC’s resistance to degradation during aging. Lysine diisocyanate was used to increase the hydrophobic character in the polyvinylurethanecarbonate resin. The polymer resins were infiltrated into porous CPP blocks with 25 volume% interconnected porosity and polymerized to produce the IPCs. After mechanical testing following a aging study it was found that the silanizing agents contributed to stability of the mechanical properties under aqueous conditions. It was concluded that the mechanical properties and stability were comparable to available biodegradable composites, as well as being biocompatible to a preosteoblast model cell line.

Orthopaedic

Interpenetrating Phase Composite

Calcium Polyphosphate

Polyvinylurethane

Fracture Fixation

Load Bearing Bones

Biodegradable Composite

Mechanical Testing

silanizing agents

silane

0541

0794