Krystalizace dvousložkových směsí polylaktidu a jejich morfologie / Crystallization of binary polylactide blends and their morphology

Debnáriková, Michaela

January 2021

Master thesis deals with the influence of polyvinylacetate, polycaprolactone, poly(butylene-adipate-co-terephtalate) and talc, ethylenevinylacetate, polyethylene glycol and monosodium citrate on the flow properties, mechanical properties and crystallization ability of PLA. The flow properties were studied using the melt flow index and mechanical properties were studied using a tensile test. The crystallinity was studied by differential scanning calorimetry and on a polarization optical microscope equipped with hot stage. Isothermal crystallization was performed at 95 and 105 °C for 3 h and non-isothermal crystallization was performed with a calorimeter at two cooling rates (1 and 10 °C/min). Upon the isothermal crystallization at 95 °C, the formation of denser crystalline structure was observed and the content of crystalline phase increased in most of the samples. The formation of spherulitic structure was observed at 105 °C in samples with 30 % PVAc, 30 % EVA and PEG. Reducing the cooling rate to 1 °C/min at non-isothermal crystallization had nearly no effect on the crystallization process of the most samples; the content of crystalline phase increased in the samples containing PBAT and PEG, which revealed double melting peak during subsequent heating. The crystalline fraction was the most significantly affected by the addition of PEG. All added polymers except PVAc affected the mechanical properties; PBAT, PCL, EVA and PEG increased the strain and decreased the strength and modulus of elasticity. The samples containing monosodium citrate showed unsatisfactory mechanical properties and could not be measured. The samples containing higher concentration of EVA copolymer showed the phase separation.

Využití nanomateriálů k fortifikaci anastomóz gastrointestinálního traktu - experiment na velkém zvířeti / Use of Nanomaterials in Fortification of Anastomoses on the Gastrointestinal Tract

Rosendorf, Jáchym

January 2021

Background: The main focus of the dissertation is the use of nanofibrous biodegradable materials for the healing support of intestinal anastomoses in colorectal surgery. The altered healing process of intestinal anastomosis leads to several types of local complications. Anastomotic leakage is one of the most feared ones. Severe anastomotic leakage causes peritonitis, sepsis and is a life-threatening condition. Reoperation is necessary in many cases, bringing the need for intensive care, and hospital stays prolongation. Extensive peritoneal adhesions are another source of postoperative complications. These adhesions are a frequent cause of bowel obstruction and abdominal discomfort and are the most common reason for readmission after colorectal procedures. Nanofibrous biodegradable materials showed positive effects on the healing process in various locations. We aimed to develop and perfect a biodegradable patch for both prevention of anastomotic leakage and the formation of extensive peritoneal adhesions. Methods: We conducted 3 subsequential experiments on porcine models. In Experiment A, we managed to develop polycaprolactone and polylactic acid- polycaprolactone copolymer nanofibrous patches and applied them on anastomoses on the small porcine intestine. The animals were observed for 3 weeks....

Electrospun Polycaprolactone Scaffolds for Small-Diameter Tissue Engineered Blood Vessels

Lee, Carol Hsiu-Yueh

January 2013

No description available.

Biomedical Engineering

Biomedical Research

Materials Science

Polymers

Comprehensive histological evaluation of bone implants

Rentsch, Claudia, Schneiders, Wolfgang, Manthey, Suzanne, Rentsch, Barbe, Rammelt, Stefan

14 July 2014

To investigate and assess bone regeneration in sheep in combination with new implant materials classical histological staining methods as well as immunohistochemistry may provide additional information to standard radiographs or computer tomography. Available published data of bone defect regenerations in sheep often present none or sparely labeled histological images. Repeatedly, the exact location of the sample remains unclear, detail enlargements are missing and the labeling of different tissues or cells is absent. The aim of this article is to present an overview of sample preparation, staining methods and their benefits as well as a detailed histological description of bone regeneration in the sheep tibia. General histological staining methods like hematoxylin and eosin, Masson-Goldner trichrome, Movat’s pentachrome and alcian blue were used to define new bone formation within a sheep tibia critical size defect containing a polycaprolactone-co-lactide (PCL) scaffold implanted for 3 months (n = 4). Special attention was drawn to describe the bone healing patterns down to cell level. Additionally one histological quantification method and immunohistochemical staining methods are described.

Knochenimplantate

Polycaprolacton

PCL

Schafe

Histologie

TU Dresden

Publikationsfonds

bone implants

polycaprolactone-co-lactide scaffold

sheep

histology

Technical University Dresden

Publication funds

ddc:570

rvk:WA 15000

Blendas biodegradáveis de poli (ácido láctico) e poli (ε-caprolactona) tenacificadas por compatibilização não-reativa: influência do teor de compatibilizante / Biogradable blends of poly(lactic acid) and poly(ε-caprolactone) toughening by non-reactive compatibilization

Dias, Paula do Patrocínio

01 September 2016

O Poli(ácido láctico) (PLA) é um polímero biodegradável, biocompatível e biorreabsorvível proveniente de fontes renováveis. Constitui uma excelente alternativa sustentável para os polímeros provenientes de petróleo, atualmente dominantes no mercado industrial. Porém, apresenta baixas ductilidade e tenacidade como principais limitações mecânicas. Um dos métodos mais utilizados para modificar essas propriedades é a mistura mecânica do PLA com polímeros flexíveis, como a poli(ε-caprolactona) (PCL). Entretanto, o alto desempenho mecânico de blendas PLA/PCL é difícil de ser atingido devido à imiscibilidade dos polímeros. A melhoria de propriedades, neste caso, só é conseguida por meio de compatibilização. Este trabalho visa avaliar o efeito compatibilizante do copolímero tribloco de baixo peso molecular derivado de ε-caprolactona e tetrametileno éter glicol disponível comercialmente em blendas imiscíveis de PLA com PCL. Blendas binárias e ternárias foram preparadas por mistura mecânica no estado fundido via processo de extrusão em rosca simples. O teor de PLA nas blendas variou em 75, 50 e 25% (% em massa) e a concentração do copolímero em 0, 1,5, 3 e 5% (% em massa). A avaliação morfológica e o comportamento térmico e mecânico das blendas PLA/PCL foram realizados por microscopia eletrônica de varredura (MEV), calorimetria exploratória diferencial (DSC), análise térmica dinâmico-mecânica (DMTA) e ensaios mecânicos de tração, flexão e impacto Izod. O efeito compatibilizante do copolímero foi mais bem observado nas blendas com 75% (% em massa) de PLA, enquanto que nas blendas com 50% e 25% (% em massa) de PLA esse efeito não foi tão evidente. Os resultados obtidos no ensaio de tração mostraram que com o aumento do teor de compatibilizante, a tensão no escoamento, a tensão na ruptura e o módulo elástico das blendas com 75% (% em massa) de PLA se mantiveram praticamente constantes, enquanto que a deformação na ruptura evoluiu de 20% na blenda com 1,5% (% em massa) de copolímero para 84% na blenda com 5% (% em massa) de copolímero. As análises morfológicas indicaram que o copolímero em bloco agiu na interface PLA/PCL, melhorando sua adesão. Esse resultado foi reforçado pelas análises térmicas, onde foi constatado que as Tg\'s e Tm\'s do PLA e do PCL nas blendas não apresentaram alterações, o que indica que o copolímero encontra-se na região interfacial da blenda. A resistência ao impacto Izod com entalhe, propriedade mecânica utilizada nesse trabalho como uma medida da tenacidade, da blenda PLA75C5 alcançou 42 J/m, valor significativamente superior ao determinado para o PLA puro, por volta de 28 J/m. Esses resultados mostram claramente que o copolímero tribloco derivado de ε-caprolactona e tetrametileno éter glicol é um eficiente compatibilizante para blendas PLA/PCL. / The Poly (lactic acid) (PLA) is a biodegradable, biocompatible and bioabsorbable polymer derived from renewable sources. It is an excellent sustainable alternative to polymers derived from oil, currently dominating the industry. However, PLA has low ductility and poor toughness as main mechanical limitations. Mechanical mixing of PLA with flexible polymers, such as poly (ε-caprolactone) (PCL), is one of the most used methods to modify these properties. However, a high mechanical performance of PLA/PCL blends is difficult to achieve due to the immiscibility of the polymers. The improvement of properties in this case is achieved only by compatibilization. This study aims to evaluate compatibilizer effect of a low molecular weight tri-block copolymer derived from ε-caprolactone and tetramethylene ether glycol, commercially available, on immiscible blends of PLA with PCL. Binary and ternary blends were prepared by mechanical blending in melt state through a single screw extrusion. The content of PLA in the blends ranged in 75, 50 and 25 wt% and the concentration of copolymer in 0, 1.5, 3 and 5 wt%. The morphological evaluation and the thermal and mechanical behavior of PLA/PCL blends were performed by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), dynamic mechanical thermal analysis (DMTA) and tensile test, flexural and Izod impact. The compatibilizer effect of the copolymer was more clearly observed in the blends with 75 wt% PLA, whereas in blends with 50 wt% to 25 wt% of PLA this effect was not so evident. The results of the mechanical tests showed that with the increase of the compatibilizer content, the yield stress, the stress at break and the elastic modulus of the blends with 75% (wt%) remained practically constant, while the elongation at break evolved from 20% in the blend with 1.5 wt% of copolymer to 84% in the blend to with 5 wt% of copolymer. Morphological analysis indicated that the block copolymer acted in the PLA/PCL interface, improving adhesion. This results were reinforced by thermal analysis, where it was found that the Tg and Tm of PLA and PCL in the blends showed no change, indicating that the copolymer is in the interfacial region of the blend. The Izod impact strength (Notched Izod), mechanical properties used in this work as a measure of toughness, of the blend PLA75C5 reached 42 J/m, significantly higher than the determined for pure PLA, about 28 J/m. These results clearly show that the triblock copolymer derived from ε-caprolactone and tetramethylene ether glycol is a good compatibilizer for blends PLA/PCL because it acts at the interfacial region, promoting the adhesion between the phases.

Blendas poliméricas

Compatibilização não-reativa

Copolímero tribloco

Nonreactive compatibilization

Poli(ácido láctico)

Policaprolactona

Poly(lactic acid)

Polycaprolactone

Polymer blends

Triblock copolymer

The characterization of the microstructure of the aortic valve for tissue engineering applications

Tseng, Hubert

16 September 2013

The aortic valve maintains unidirectional blood flow between the left ventricle and the systemic circulation. When diseased, the valve is replaced either by a mechanical or a bioprosthetic heart valve, that carry issues such as thrombogenesis, long term structural failure, and calcification, necessitating the development of more structurally and biologically sufficient long-term replacements. Tissue engineering provides a possible avenue for development, combining cells, scaffolds, and biochemical factors to regenerate tissue. The overall goal of this dissertation was to create a foundation for the rational design of a tissue engineered aortic valve. The novel approach taken in this thesis research was to view each of the three leaflets as a laminate structure. The first three aims consider the leaflet as a laminate structure comprising of layers of collagen, elastin, and glycosaminoglycans (GAGs). In the first aim, the effect of GAGs on the tensile properties and stress relaxation in the leaflet was investigated, by removing GAGs through increasing amounts of hyaluronidase. A decrease in GAGs led to significantly higher elastic moduli, maximum stresses, and hysteresis in the leaflet. In the second aim, the 3D elastic fiber network of the leaflet was characterized using immunohistochemistry and scanning electron microscopy. This structure was found to have regionally varying thicknesses and patterns. In the third aim, a novel hydrogel-fiber composite design was proposed to match the anisotropy of the leaflet. This composite composed of aligned electrospun poly(ε-caprolactone) (PCL) within a poly(ethylene glycol) diacrylate (PEGDA) matrix. Surface modification and embedding of the PCL did not significantly alter the anisotropy or strength of the underlying PCL scaffold, providing the basis for an anisotropic, biocompatible scaffold. In the last aim, a novel co-culture model was designed using magnetic levitation as a layered structure of valvular endothelial cells and interstitial cells. This technique was used to create co-culture models within hours, while maintaining cell phenotype and function, and inducing extracellular matrix formation, as shown by immunohistochemical stains and their gene expression profiling. The overall result of this dissertation is a clearer understanding of the layered structure-function relationship of the aortic valve, and its application towards heart valve tissue engineering.

Aortic valve

tissue engineering

biomechanics

heart valves

valvular interstitial cell

valvular endothelial cell

glycosaminoglycans

elastic fibers

polyethylene glycol

polycaprolactone

magnetic levitation

co-culture

Development And Characterization Of Cortisone Derivative Drugcarrying Polymeric Microspheres

Ocal, Yigit

01 February 2011

In this study, it is aimed to develop an injectable controlled release system of PCL and P(L,DL)LA microspheres loaded with TA and/or Ral for local treatment of rheumatoid arthritis which will avoid from systemic side effects of traditional administration and eliminate problems caused by direct local injections. Rheumatoid arthritis (RA) is a chronic, systemic, autoimmune disorder that most commonly causes inflammation and tissue damage in joints and tendon sheaths. Current strategies for the disease are mainly towards relieving symptoms and increasing mobility. The microsphere form drug delivery systems were developed to enhance the treatment success of rheumatic diseases by providing these agents alone or together for long terms without causing systemic or local site effects upon injection to the RA joints. Microspheres were prepared with s/o/w solvent evaporation technique and optimized to achieve a suitable size for joint application, to sustain the delivery of the drug(s), to provide required amount of the agent with feasible amount of microsphere. In order to manage these, microspheres prepared with different combinations of polymers and drugs were examined for particle size analysis, surface and structural characterizations, time related drug release properties, and drug loading capacities. In vitro cytotoxicity tests using 3T3 fibroblast cells were done to evaluate the biocompatibility of drug loaded PCL microspheres. The degradation of polymers were conducted and evaluated by GPC analysis. In PCL:TA microspheres, as polymer:drug ratio decreased (from 10:1 towards 10:4), namely as the drug partition increased, it was seen that encapsulation efficiency and loading percentages increased. Meanwhile, percent release of the drug decreased, indicating more prolonged release. Among all microspheres, PCL:TA 10:4 and PCL:Ral 10:2 were found to be the most appropriate for dual release in terms of release values (ca 21% and 0.09%, respectively), loadings (ca 27% and ca 13%, respectively) and mean particle size values (ca 100 &mu / m and ca 95 &mu / m, respectively). After release studies, microspheres preserved their sphericity. These selected polymer:drug groups also represented no cytotoxic effect. The microspheres for dual drug study (PCL:TA:Ral 10:4:2) released app. 55% of its TA and 0.29% of Ral at the end of 4 weeks. Drug loading capacities of these microspheres were found to be ca 14% for TA and 8% for Ral. Furthermore, with dual loading case, smallest mean particle size (68 &mu / m) could be obtained among all studied groups. P(L,DL)LA microspheres caused high viscosity problems during microsphere preparation steps and resulted in the slowest release, which was unfavorable for the aim of the study. To our knowledge there is no microsphere study reported with P(L,DL)LA in literature. The TA and Ral delivery systems with PCL and P(L,DL)LA were developed and studied for the first time in literature and they were optimized for RA treatment purposes. The potential of these systems, should be further tested in experimental animal models of RA.

TA Bioengineering 164

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

Matériaux biodégradables à base d'amidon expansé renforcé de fibres naturelles - Application à l'emballage alimentaire

Stanojlovic Davidovic, Andréa

14 December 2006

Dans un contexte où le développement durable apparaît comme une priorité majeure, la mise au point de matériaux biodégradables, représente un enjeu majeur qui offre une alternative aux polymères synthétiques. L'objectif de cette thèse est donc de développer un système multicouche biodégradable susceptible de se substituer au polystyrène expansé dans le domaine de la barquette alimentaire. Ce multicouche est constitué de deux films de polycaprolactone en tant que couches externes et d'une âme en amidon de pomme de terre. Cet amidon a été expansé et renforcé par des fibres naturelles (chanvre, cellulose, paille de blé, linter de coton). L'influence d'agents de nucléation dans les formulations a été analysée. Après optimisation des conditions de mise en oeuvre par extrusion et laminage-couchage, la tenue mécanique du produit, ainsi que sa résistance à l'eau, sa microstructure (taille des cellules, épaisseur des parois) et sa biodégradabilité ont été déterminées et optimisées

amidon expansé

fibres naturelles

chanvre

cellulose

linter de coton

paille de blé

polycaprolactone

multicouche

biocomposite

extrusion

biodégradation

emballage alimentaire

Blendas biodegradáveis de poli (ácido láctico) e poli (ε-caprolactona) tenacificadas por compatibilização não-reativa: influência do teor de compatibilizante / Biogradable blends of poly(lactic acid) and poly(ε-caprolactone) toughening by non-reactive compatibilization

Paula do Patrocínio Dias

01 September 2016

O Poli(ácido láctico) (PLA) é um polímero biodegradável, biocompatível e biorreabsorvível proveniente de fontes renováveis. Constitui uma excelente alternativa sustentável para os polímeros provenientes de petróleo, atualmente dominantes no mercado industrial. Porém, apresenta baixas ductilidade e tenacidade como principais limitações mecânicas. Um dos métodos mais utilizados para modificar essas propriedades é a mistura mecânica do PLA com polímeros flexíveis, como a poli(ε-caprolactona) (PCL). Entretanto, o alto desempenho mecânico de blendas PLA/PCL é difícil de ser atingido devido à imiscibilidade dos polímeros. A melhoria de propriedades, neste caso, só é conseguida por meio de compatibilização. Este trabalho visa avaliar o efeito compatibilizante do copolímero tribloco de baixo peso molecular derivado de ε-caprolactona e tetrametileno éter glicol disponível comercialmente em blendas imiscíveis de PLA com PCL. Blendas binárias e ternárias foram preparadas por mistura mecânica no estado fundido via processo de extrusão em rosca simples. O teor de PLA nas blendas variou em 75, 50 e 25% (% em massa) e a concentração do copolímero em 0, 1,5, 3 e 5% (% em massa). A avaliação morfológica e o comportamento térmico e mecânico das blendas PLA/PCL foram realizados por microscopia eletrônica de varredura (MEV), calorimetria exploratória diferencial (DSC), análise térmica dinâmico-mecânica (DMTA) e ensaios mecânicos de tração, flexão e impacto Izod. O efeito compatibilizante do copolímero foi mais bem observado nas blendas com 75% (% em massa) de PLA, enquanto que nas blendas com 50% e 25% (% em massa) de PLA esse efeito não foi tão evidente. Os resultados obtidos no ensaio de tração mostraram que com o aumento do teor de compatibilizante, a tensão no escoamento, a tensão na ruptura e o módulo elástico das blendas com 75% (% em massa) de PLA se mantiveram praticamente constantes, enquanto que a deformação na ruptura evoluiu de 20% na blenda com 1,5% (% em massa) de copolímero para 84% na blenda com 5% (% em massa) de copolímero. As análises morfológicas indicaram que o copolímero em bloco agiu na interface PLA/PCL, melhorando sua adesão. Esse resultado foi reforçado pelas análises térmicas, onde foi constatado que as Tg\'s e Tm\'s do PLA e do PCL nas blendas não apresentaram alterações, o que indica que o copolímero encontra-se na região interfacial da blenda. A resistência ao impacto Izod com entalhe, propriedade mecânica utilizada nesse trabalho como uma medida da tenacidade, da blenda PLA75C5 alcançou 42 J/m, valor significativamente superior ao determinado para o PLA puro, por volta de 28 J/m. Esses resultados mostram claramente que o copolímero tribloco derivado de ε-caprolactona e tetrametileno éter glicol é um eficiente compatibilizante para blendas PLA/PCL. / The Poly (lactic acid) (PLA) is a biodegradable, biocompatible and bioabsorbable polymer derived from renewable sources. It is an excellent sustainable alternative to polymers derived from oil, currently dominating the industry. However, PLA has low ductility and poor toughness as main mechanical limitations. Mechanical mixing of PLA with flexible polymers, such as poly (ε-caprolactone) (PCL), is one of the most used methods to modify these properties. However, a high mechanical performance of PLA/PCL blends is difficult to achieve due to the immiscibility of the polymers. The improvement of properties in this case is achieved only by compatibilization. This study aims to evaluate compatibilizer effect of a low molecular weight tri-block copolymer derived from ε-caprolactone and tetramethylene ether glycol, commercially available, on immiscible blends of PLA with PCL. Binary and ternary blends were prepared by mechanical blending in melt state through a single screw extrusion. The content of PLA in the blends ranged in 75, 50 and 25 wt% and the concentration of copolymer in 0, 1.5, 3 and 5 wt%. The morphological evaluation and the thermal and mechanical behavior of PLA/PCL blends were performed by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), dynamic mechanical thermal analysis (DMTA) and tensile test, flexural and Izod impact. The compatibilizer effect of the copolymer was more clearly observed in the blends with 75 wt% PLA, whereas in blends with 50 wt% to 25 wt% of PLA this effect was not so evident. The results of the mechanical tests showed that with the increase of the compatibilizer content, the yield stress, the stress at break and the elastic modulus of the blends with 75% (wt%) remained practically constant, while the elongation at break evolved from 20% in the blend with 1.5 wt% of copolymer to 84% in the blend to with 5 wt% of copolymer. Morphological analysis indicated that the block copolymer acted in the PLA/PCL interface, improving adhesion. This results were reinforced by thermal analysis, where it was found that the Tg and Tm of PLA and PCL in the blends showed no change, indicating that the copolymer is in the interfacial region of the blend. The Izod impact strength (Notched Izod), mechanical properties used in this work as a measure of toughness, of the blend PLA75C5 reached 42 J/m, significantly higher than the determined for pure PLA, about 28 J/m. These results clearly show that the triblock copolymer derived from ε-caprolactone and tetramethylene ether glycol is a good compatibilizer for blends PLA/PCL because it acts at the interfacial region, promoting the adhesion between the phases.

Blendas poliméricas

Compatibilização não-reativa

Copolímero tribloco

Poli(ácido láctico)

Policaprolactona

Nonreactive compatibilization

Poly(lactic acid)

Polycaprolactone

Polymer blends

Triblock copolymer