Surface analysis of novel biomedical polymers

McGurk, Simon L.

January 1998

No description available.

615.1

ENHANCED BURN WOUND HEALING THROUGH CONTROLLED AND SUSTAINED DELIVERY OF BIOACTIVE INSULIN FROM ALGINATE SPONGE DRESSINGS

Hrynyk, MICHAEL

04 January 2013

Skin is a dynamic and complex organ that relies on the interaction of different cell types,biomacromolecules and signaling molecules. Upon injury, a cascade of events occurs to quickly restore the skin’s integrity. Depending on the size and severity of the wound, a dressing is used to provide a temporary barrier to protect from dehydration, microorganisms and debris. Current wound dressings however, cannot accelerate wound healing beyond the natural rate, require frequent dressing changes, and cannot be easily removed without triggering additional pain ortissue destruction. Insulin, a peptide used to treat Type 1 diabetes, has been reported to improve the recovery of severe burn wounds. Yet, no one has successfully demonstrated a convenient and effective insulin delivery vehicle that can be used to accelerate burn wound healing. Poly(lactic-co-glycolic acid) microparticles, were shown to release bioactive insulin for a period of 25 days, stimulating human keratinocyte migration in vitro. A wound dressing made from poly(ethylene glycol) and alginate was formulated incorporating the insulin-loaded poly(lactic-co-glycolic acid) microparticles. Bioactive insulin release was achieved for nearly 3 weeks, along with favourable water handling and physical properties conducive for wound healing. Finally, in vivo testing confirmed that a constant dose of insulin from alginate-PEG sponge dressings loaded with 0.125mg, or 0.04mg/cm2 insulin, with dressing changes every 3 days, was sufficient to significantly improve wound healing by 25%, as compared to an alginate- PEG sponge dressing without insulin. Insulin releasing alginate-PEG sponge dressings are therefore, an effective method of improving burn wound healing and may serve as a delivery vehicle platform to incorporate other therapeutic molecules in the future. / Thesis (Ph.D, Chemical Engineering) -- Queen's University, 2012-12-20 17:50:47.872

Wound Healing

Drug Delivery

Biomaterials

Insulin

Engineering 2D Cardiac Tissues Using Biomimetic Protein Micropatterns Based on the Extracellular Matrix in the Embryonic Heart

Batalov, Ivan

01 April 2017

Cardiovascular disease is the leading cause of death worldwide. Due to the extremely low natural regeneration rate of heart muscle, development of new therapeutics directed towards heart repair is challenging. A potential approach to regenerate damaged heart is offered by cardiac tissue engineering. Specifically, it aims at engineering cardiac muscle in vitro and implanting it into the site of injury so that it can be integrated into the host tissue and restore the heart’s function. To ensure the effectiveness of this technique, the engineered tissue needs to recapitulate structural and functional properties of the native myocardium. Myocardium consists of laminar sheets of uniaxially aligned cardiac muscle cells (cardiomyocytes) wrapped around the heart. Therefore, achieving high cardiomyocyte alignment in engineered muscle is crucial. In this study we aimed at stimulating cardiomyocyte alignment by mimicking their niche in the embryonic heart. We hypothesized that recapitulating the extracellular cues that guide myocardial development in the embryo can guide cardiac tissue organization in vitro. To test this hypothesis, we imaged the structure of fibronectin – the most abundant protein in embryonic heart’s extracellular matrix (ECM) – and derived a 2D pattern from it that was then microcontact printed onto a substrate to guide cell alignment. We compared chick cardiomyocyte alignment on the biomimetic pattern and line patterns that have been extensively studied in the past. Results revealed a unique cell density-dependent response of cardiomyocytes to the biomimetic pattern that allowed us to elucidate the role of cell-cell and cell-ECM interactions in cardiomyocyte alignment on fibronectin patterns by looking at the effect of local pattern features on alignment and inhibiting N-cadherin-based cell-cell junctions. Further, to engineer more clinically relevant tissues, we differentiated human induced pluripotent stem cells (iPSCs) and embryonic stem cells (ESCs) into cardiomyocytes and seeded them onto the fibronectin patterns. Cardiac tissues produced with these cells showed significant differences compared to the chick tissues due to their immature phenotype. We showed that co-culture with cardiac fibroblasts (CFBs) as well as maturation of iPSC-derived cardiomyocytes (iPSC-CMs) increased tissue alignment, indicating the important role of both of these factors in developing novel methods to engineer functional cardiac tissues.

biomaterials

biomimetic

cardiac

embryonic heart

tissue engineering

Characterization of Fibrin Matrix Incorporated Electrospun Polycaprolactone Scaffold

Wong, Cho Yi

01 January 2016

Specific objective: Guided tissue regeneration (GTR) aims to regenerate the lost attachment apparatus caused by periodontal disease through the use of a barrier membrane. For the GTR procedures to be successful, barrier membranes are required to be present at the surgical site for an extended period of time (weeks to months). Synthetic membranes have the advantage of prolonged presence in a wound site; however, they do not actively contribute to wound healing. Biologic membranes are recognized by the host tissue and participate in wound healing but have the disadvantage of early resorption. Therefore, the goal of this study is to create and characterize a hybrid barrier membrane that contains biologically active fibrin matrix within a synthetic polymeric electrospun scaffold. Method: Fibrin matrices and fibrin-incorporated electrospun scaffold were created from fresh frozen plasma at three different centrifugation conditions 400g for 12 minutes, 1450g for 15 minutes and 3000g for 60 minutes. Following centrifugation, half of the membranes were crosslinked with 1% genipin. Biological stability of these scaffolds was evaluated by resistance to trypsin while their mechanical properties were characterized by MTS Bionix Uniaxial Tensile Testing System. Continuous data was analyzed by ANOVA to detect differences between groups (p=0.05). Results: The addition of an electrospun scaffold to the fibrin matrix led to improvements in the mechanical properties as evidenced by an increase in the modulus (p<0.0001), strain at break (p<0.0001) and energy to break (p<0.0001). The effect of crosslinking was marginal but not statistically significant to the mechanical properties of fibrin matrices or the fibrin incorporated scaffold. However, crosslinking did significantly increase resistance against enzymatic degradation by trypsin (p<0.0001). Lastly, centrifugation speeds at 400g and 1450g showed similar mechanical properties and biologic stability; meanwhile 3000g negatively impacted the properties of the scaffold. Conclusion: Fibrin-incorporated electronspun scaffold exhibits enhanced mechanical and biologic stability compared to fibrin matrices alone. Moreover, crosslinking improves the biologic stability of the novel biomaterial. All these characteristics of the fibrin-incorporated matrix make this membrane a potentially more ideal barrier for GTR procedures to enhance periodontal wound healing.

Fibrin

electrospun scaffold

membrane

mechanical properties

Biomaterials

Obtenção e caracterização de misturas do polímero biodegradável P[3HB] e seu copolímero P[3HB-co-3HV] com elastômeros. / Obtention and characterization of polymer blends based on P[3HB] and its copolymer P[3HB-co-3HV] with elastomers.

Calvão, Patrícia Schmid

15 September 2009

Neste trabalho foi desenvolvido um estudo com o poliéster biodegradável P[3HB] (poli[R-3-hidroxibutirato]) e seu copolímero P[3HB-co-3HV] (poli[R-3-hidroxibutirato-co-3- hidroxivalerato]). Esses materiais são conhecidos por seu grande potencial de biodegradabilidade, porém sua utilização pela indústria ainda é limitada em função de seu baixo desempenho mecânico. Visando a tenacificação desses materiais, optou-se por misturá-los com os elastômeros EPDM (terpolímero de etileno-propileno-dieno) e PVB (Poli(vinil butiral)). Foram estudados quatro grupos de blendas: P[3HB]/EPDM e P[3HB-co- 3HV]/EPDM processados em misturadores internos e posteriormente prensadas em filmes; P[3HB]/EPDM e P[3HB]/PVB extrudados e posteriormente injetados. As blendas foram obtidas nas concentrações de 10, 20 e 30% em peso de elastômeros. Inicialmente, estudou-se efeito da incorporação de elastômeros na cristalinidade, estrutura cristalina, propriedades térmicas e dinâmico-mecânicas das matrizes, e o efeito do tipo de processamento utilizado. Observou-se que a adição dos elastômeros às matrizes semicristalinas aumentou a nucleação de esferulitos, resultando em um aumento da cristalinidade das mesmas. O PVB apresentou um efeito plastificante na estrutura do PHB. Os filmes apresentaram uma degradação térmica maior que as amostras injetadas, resultando em uma cristalização mais lenta e um grau de cristalinidade maior. Em um outro estudo, avaliou-se a morfologia, tensão interfacial, comportamento reológico, propriedades mecânicas e a biodegradabilidade das amostras estudadas. Foi observada uma morfologia de dispersão de gotas para todas as misturas, exceto para a mistura P[3HB]/EPDM obtida por injeção que apresentou um certo grau de co-continuidade. No caso das misturas injetadas foi visto que o fator que parece influenciar mais fortemente em sua morfologia final são as razões de viscosidade observadas entre a matriz e a fase dispersa das mesmas. A adição de elastômeros aumentou a resistência ao impacto do P[3HB], principalmente no caso da mistura P[3HB]/EPDM, o que pode estar relacionado à morfologia co-contínua observada nesta blenda. A incorporação dos elastômeros resultou em uma redução do módulo de elasticidade e da resistência à tração do P[3HB], e aumento do alongamento, principalmente no caso da mistura com PVB. Foi visto que a biodegradação do P[3HB] e P[3HB-co-3HV] aumentou com a adição de elastômeros, devido à morfologia de dispersão e a diminuição do tamanho dos esferulitos que aumentam a área interfacial para a ação das enzimas, facilitando a biodegradação. / In this work a study with the biodegradable polyester P[3HB] (poly[R-3- hydroxybutyrate]) and its copolymer P[3HB-co-3HV] (poly[R-3-hydroxybutyrate-co-3- hydroxyvalerate]) was conducted. These materials are known for their high biodegradability but their use is still limited because of their poor mechanical properties. In order to improve these properties it was chosen to blend these biodegradable polymers with EPDM (Ethylene propylene diene monomer) and PVB (Polyvinyl butyral). Four groups of blends were obtained: P[3HB]/EPDM and P[3HB-co-3HV]/EPDM blends were prepared using an internal mixer and then compressed molded; P[3HB]/PVB and P[3HB]/EPDM blends were prepared using an extruder and further injected. The blend concentrations ranged from 10 to 30 wt. % of the rubbery phase. Initially, the effect of rubber type on the crystallinity, the crystalline structure, thermal and dynamic-mechanical properties of the matrices and the effect of processing method to obtain the blends were investigated. The addition of elastomers on P[3HB] (and P[3HB-co- 3HV]) increases the nucleation, resulting in an increase of matrix crystallinity. PVB showed a plasticizing effect on the P[3HB] structure. Film samples showed a higher thermal degradation than injected ones, resulting in a slower crystallization and higher crystallinity. The morphology, interfacial tension, rheological behavior, mechanical properties (tensile and impact) and biodegradability of samples were also studied. A droplet dispersion morphology type was obtained for all the blends except for P[3HB]/EPDM injected samples which presented some extent of degree of continuity. The experimental results indicated that the final morphology observed for the blends was controlled by the viscosity ratio between the matrix and dispersed phase. Elastomer addition increased P[3HB] impact strength mainly for P[3HB]/EPDM blends, probably due to its co-continuous morphology. Moreover, elastomer incorporation resulted in a decrease of P[3HB] elastic moduli and tensile strength and increase of elongation of break, mainly for P[3HB]/PVB blends. It was observed that P[3HB] and P[3HB-co-3HV] biodegradation increased with elastomer addition due to the droplet dispersion morphology and decrease of spherulites size witch causes an increase of interfacial area for enzymes, facilitating biodegradation.

Biomateriais (processamento)

Biomaterials

Blendas

Blends

Elastômeros

Elastomers

Desenvolvimento de géis e esponjas de quitosana e blendas quitosana/gelatina em ácido adípico / Development of gels and sponges of chitosan and blends chitosan/gelatin prepared in adipic acid

Pepino, Rebeka de Oliveira

04 March 2016

A quitosana é um biopolímero estudado em diversas áreas, tais como, ambiental, alimentícia, farmacêutica, biomédica e biotecnológica. Ela pode ser obtida de diferentes formas polimórficas de quitina, dentre as quais a forma &beta; tem se mostrado vantajosa, pois favorece modificações químicas mais homogêneas e leva a um produto final menos alergênico. A quitosana pode ser combinada com outros compostos a fim de interagir e/ou reagir com eles e modificar suas propriedades. O objetivo deste trabalho foi estudar como uso de ácido adípico, em substituição ao acético, afeta as propriedades de géis e esponjas de quitosana e de quitosana/gelatina, que foram posteriormente reticuladas com os agentes reticulantes EDC/NHS. As técnicas utilizadas para os estudos foram: reologia, FTIR, MEV, absorção em PBS e ensaios de citotoxicidade. Por reologia, observou-se que o aumento na concentração dos géis de quitosana tornou os géis mais elásticos e viscosos. O mesmo ocorreu na presença de gelatina ou EDC/NHS. O efeito do uso de ácido adípico em substituição ao acético também foi mostrado nos ensaios reológicos, pois os géis com 2% de quitosana e com quitosana/gelatina sem EDC/NHS se mostraram mais elásticos e mais viscosos quando o ácido adípico foi usado. Os espectros FTIR mostraram a presença de interações entre a quitosana e a gelatina e a formação de ligações amidas II após reticulação com EDC/NHS. Na preparação das esponjas observou-se que os géis de quitosana em ácido adípico geravam esponjas instáveis que se desfizeram durante a neutralização, mas essa instabilidade não ocorreu com a blenda. As esponjas preparadas com a blenda foram estudadas após neutralização e o MEV mostrou que o uso de EDC/NHS alterou a morfologia levando a formação de poros interconectados. Nos ensaios de absorção em tampão de PBS foi observado que o uso de ácido acético aumenta a absorção para as esponjas sem EDC/NHS, enquanto para as esponjas com EDC/NHS a absorção é maior quando se usa ácido adípico. Todas as esponjas foram não citotóxicas o que torna esses materiais promissores para serem estudados em aplicações na área médica, tais como material de curativo, implantes, liberação controlada de fármacos. / Chitosan is a natural polymer studied in various fields such as environmental, food, pharmaceutical, biomedical and biotechnology. It can be obtained from different polymorphic forms of chitin, of which the form &beta; has proven advantageous because it promotes more homogeneous and chemical modifications leads to a final product less allergenic. Chitosan can be combined with other compounds and thus further improve its properties. The aim of this study was to analyze how the use of adipic acid, replacing acetic acid affects the properties of gels and sponges of chitosan and chitosan/gelatin, which were subsequently crosslinked with EDC/NHS. The techniques used for these studies were: rheology, FTIR, SEM, absorption in PBS and cytotoxicity assays. In rheology, it was observed that increasing the concentration of chitosan was possible to prepare more elastic and viscous gels. The same occurs in the presence of gelatin or EDC/NHSO. The effect of the use of adipic acid to replace the acetic acid was also shown on rheological measurements, because the gels with 2% chitosan or chitosan/gelatin without EDC/NHS were more elastic and more viscous when the adipic acid has been used. The FTIR spectra showed the presence of interactions between chitosan and gelatin and the formation of amide II Bonds after crosslinking with EDC/NHS. In the preparation of the sponges it was observed that the gels of chitosan with adipic acid generated unstable sponges crumbled during neutralization, but this instability does not occur with the blend. Sponges prepared with the blend were studied after neutralization and SEM showed that the use of EDC/NHS altered the morphology leading to the formation of interconnected pores. The use of acetic acid increases the absorption in PBS for sponges without EDC/NHS, while for sponges with EDC/NHS the absorption is greater when adipic acid was used. All sponges were non-cytotoxic making them promising materials to be studied for applications in the medical field, such as dressing materials, implants, controlled drug release.

biomateriais

biomaterials

chitosan

gelatin

gelatina

quitosana

Development of Recombinant Human Collagen Type I and Type III Injectable Hydrogels for Cardiac Therapy

Podrebarac, James

January 2017

Functional biomaterials are being developed as scaffolds to support endogenous cells and to promote the regeneration of ischemic tissue. The aim for this study was to develop a new translational platform for injectable hydrogels using recombinant human collagen (rHC) of two types: type I (TI) and type III (TIII). The collagen solutions were characterized to ensure batch-to-batch consistency and protein integrity. The hydrogel preparation protocol was extensively monitored to ensure ease of use and high-quality production. Post-gelation, rHC TIII have a higher viscosity compared to rHC TI, yet water content was high for both hydrogels. The cross-linking degree is similar for both rHC hydrogels, which are stable well above physiological temperatures, but rHC TI is more susceptible to enzymatic degradation than rHC TIII. Furthermore, the micro-architecture differed with pore size dimensions of rHC TIII being significantly larger than that of rHC TI. Cardiac fibroblasts were cultured on the rHC hydrogels, and cells attached readily to the scaffold environment, which promoted proliferation. The rHC matrices mechanical and biological properties provide structural support, and demonstrate biodegradability and biocompatibility. The intrinsic physical differences between the rHC hydrogels will likely have implications in future studies. In conclusion, the rHC TI and TIII hydrogels are proven to be suitable matrices for continued investigation towards future translational applications.

Biomaterials

Cardiovascular disease

Collagen

Injectable

Recombinant protein

Photoembossing for biomedical applications

Hughes-Brittain, Nanayaa Freda

January 2014

Surface topography is known to be important in biomedical applications such as scaffolds for tissue regeneration and has been shown to affect wettability and cell behaviour. Traditionally, topographical effects such as surface texturing have been generated using methods such as photolithography, soft lithography, thermal embossing, and laser/electron beam techniques. This thesis introduces a relatively new technique known as photoembossing to create surface texturing for biomedical applications. Photoembossing is used to produce surface texturing on polymer surfaces by patterned ultraviolet (UV) exposure of a photopolymer blend without an etching step or an expensive mould. After a short general introduction and a literature review, the first experimental chapters describe surface patterning of poly(methyl methacrylate) (PMMA) photopolymer substrates by photoembossing. PMMA is blended with an acrylate monomer and photoinitiator by dissolution in a volatile solvent and processed into films by wire bar coating, and fibres are produced by electrospinning. Surface texture is achieved on both films and fibres by photoembossing. Endothelial cell culture shows that the substrates are biocompatible and cells readily adhere to the surface. In tissue regeneration applications, scaffold degradation is often important to allow tissue in-growth. Thus, in subsequent studies polylactide-co-glycolide (PLGA) is used as a polymer binder. PLGA blended with a triacrylate monomer showed partial degradation after 10 weeks, with a cross-linked acrylate network remaining. Endothelial cell adhesion was even better on the PLGA photopolymer substrates compared to PMMA. Furthermore, surface texture improved cell adhesion and proliferation on the PLGA photopolymer. To obtain completely degradable substrates, thiol monomer was used in addition to the acrylate to produce ester bonds after the thiol-ene reaction, which is cleavable by hydrolysis. Accelerated degradation in sodium hydroxide (NaOH) showed complete degradation of this photopolymer system. The degradation rate of the photopolymer could be tuned by the molecular weight of the acrylate monomer, with low molecular weight monomers degrading more slowly than high molecular weight species. Furthermore, the height of the surface relief structures could be enhanced by using low-molecular-weight acrylate monomers. Endothelial cell culture revealed biocompatibility of the blend and cells were able to adhere after 24 hours of seeding. This thesis demonstrates that photoembossing is a viable technique in producing surface texture for tissue engineering applications. This surface texture can be achieved on both biocompatible and biodegradable photopolymer films and fibres.

610.28

Electrically active ceramics for bone graft substitution

Baxter, Frances R.

January 2008

Hydroxyapatite (HA) bioceramics are commercially available as bone graft substitute materials. The aim of the current research was to characterise the electrical properties of hydroxyapatite-barium titanate (HABT) composites and to assess in vitro biological responses to the composites in order to investigate their potential use as bone graft substitutes. A range of HABT ceramics of different compositions was manufactured and their electrical properties were measured. The microstructure and piezoelectric properties of the ceramics were both dependent on the proportion of barium titanate (BT) present. Composites containing more than 70% BT displayed piezoelectric charge coefficients (d33) of up to 86.3±7.9pCN-1 (95% BT). The ferroelectric nature of the 90 and 95% BT materials was confirmed by assessment of their ferroelectric hysteresis loops. The highest piezoelectric voltage coefficient (g33) recorded was 14x10-3Vm-1Pa-1 (90% BT). Following the assessment of the electrical properties, the HABT ceramic containing 90% BT was selected for the assessment of biological responses to the composites. The proliferation, viability, activity and morphology of human osteoblast-like cells cultured on HABT were comparable to those cultured on hydroxyapatite (HA) up to 7 days after seeding. The remnant polarisation of poled HABT induced an increase in cell attachment. This influence was independent of the nature (positive or negative) of the polarisation. Poling was not found to influence cell morphology, activity or differentiation in the first 7 days of incubation. At 14 days after seeding, results were inconsistent, indicating some variations in cell population and differentiation depending on the composition and poling of the ceramics respectively. This study has substantially defined the electrical properties of a range of HABT ceramics. It indicates their in vitro biocompatibility and thus their potential for use as bone graft substitutes. These results provide a benchmark against which future work investigating the influence of mechanical loading and longer term studies may be measured.

612

In-situ analysis of nanoscale deformation mechanism in mutable collagenous tissue

Mo, Jingyi

January 2018

Echinoderms, for example sea cucumber, contain a unique collagenous tissue, with special biomechanical properties, which could near-instantly change their mechanical state (going from stiff to soft, and vice versa, in less than a second). However, the structure-function relation has so far not been exploited. Understanding how the material design of mutable collagenous tissue (MCT) enables this remarkable dynamical mechanical behaviour will help enable development of new biomaterials with adaptable mechanical properties. Currently, it is hypothesised that MCT can rapidly form crosslinks between the collagen fibrils and stiffen the interfibrillar matrix under neural control, but this had never been shown directly. In this thesis, we carried out an experimental study of quantifying how the interfibrillar matrix response to stimuli agents, to generate active forces and change conformation using a synchrotron in situ X-ray nanomechanical imaging method. By the uncovering of the mechanisms of active force generation, a valuable guideline, which could be applied in bioinspired constructs that response to external stimuli, can be obtained.