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91	Mechanically-Conditioned Biphasic Composite Scaffolds to Augment Healing of Tendon-Bone Interface Subramanian, Gayathri Gowri January 2017 (has links) No description available. Biomedical Engineering Biomedical Research
92	DESARROLLO Y CARACTERIZACION DE PELÍCULAS DE ALMIDÓN DE MAÍZ POR MEZCLADO CON COMPUESTOS MÁS HIDROFÓBICOS / Development and characterization of corn starch films by blending with more hydrophobic compounds Ortega Toro, Rodrigo 01 July 2015 (has links) Tesis por compendio / [EN] Different strategies were used to improve physical properties of corn starch based films, with glycerol (30%) as plasticizer, based on increasing their hydrophobic character in order to reduce the materials' water sensitivity. Starch was blended with different components (surfactants and more hydrophobic polymers), with and without compatibilizers, to obtain blend films through different processing techniques (casting, melt blending, compression molding and extrusion). Bilayer film formation by compression molding with starch and poly(e-caprolactone) (PCL) was also studied. The addition of surfactants to starch films obtained by casting gave rise to a decrease in water vapor permeability (WVP), but an increase in the film fragility was observed. Surfactants with lower hydrophilic-lipophilic balance (HLB), solid at room temperature, promoted a fine microstructure in the matrix with smaller lipid particle, which enhanced water vapor barrier properties. Thermo-processing was used to obtain the other films due to its broader industrial application. Starch blends with hydroxypropyl methylcellulose (HPMC) showed an HPMC dispersed phase in the starch matrix and better water barrier properties, but they were more permeable to oxygen, especially when they contained citric acid (CA) as compatibilizer. CA induced cross-linking in the polymeric matrix, thus slightly increasing film hardness, but decreasing its extensibility. The incorporation of PCL in different ratios to starch films obtained by compression molding gave rise to polymer phase separation, although a small PCL miscibility in the starch rich phase was detected, which reduced the glass transition temperature of the starch phase. The structural heterogeneity and lack of interfacial adhesion between polymers gave rise to fragile films. Nevertheless, small amounts of PCL (10%) reinforced the matrix (increase in the elastic modulus). When the PCL ratio increased, WVP was reduced but oxygen permeability increased. The incorporation of CA as compatibilizer of these blends provoked an increase in the water solubility of the films, by hydrolysis, and improved the mechanical properties of the films when PCL ratio was low (10%), but it did not affect the film barrier properties. The incorporation of polyethylene glycol (PEG 4000) to the blends with a low proportion of PCL did not imply an improvement in the film properties, since it promoted phase separation. Starch-PCL blends with 1:0.05 mass ratio, without compatibilizer, were quite homogenous and exhibited good mechanical properties and stability. In order to incorporate greater amounts of PCL, thus improving film hydrophobicity and stability, PCL was chemically modified by grafting glycidyl methacrylate or glycidyl methacrylate and maleic anhydride (PCL-g), to be used as compatibilizers. Films with 20 % PCL and 2.5 or 5 % of PCL-g showed very good mechanical and barrier properties and stability, inhibiting starch retrogradation. Their barrier properties met the food packaging requirements for a wide number of food products. Bilayer films obtained by compression molding of starch (or starch with 5% PCL) and PCL layers showed very low WVP and oxygen permeability and adequate mechanical properties. The adhesion of bilayers was greatly improved by the application of ascorbic acid and, especially, potassium sorbate, as aqueous solutions, at the interface before compression molding. These compounds, in turn, imparted antioxidant and antimicrobial properties, respectively, to the films, thus improving their potential use as active packaging material for food uses. / [ES] Se han utilizado diversas estrategias para mejorar las propiedades físicas de films a base de almidón de maíz, con glicerol (30 %) como plastificante, basadas en el incremento de su carácter hidrofóbico, para reducir su sensibilidad al agua. El almidón se mezcló con diferentes compuestos (surfactantes y polímeros más hidrofóbicos), con y sin compatilizadores, para la obtención de films mixtos por diferentes técnicas de procesado (casting, mezclado en fundido, moldeo por compresión y extrusión). Se estudió también la formación de films bicapa almidón-poli-e-caprolactona (PCL) mediante moldeo por compresión. La adición de surfactantes a los films de almidón elaborados por casting dio lugar a una disminución de su permeabilidad al vapor de agua (WVP), pero aumentó su fragilidad. Los surfactantes con menor balance hidrófilo-lipófilo (HLB), y sólidos a temperatura ambiente, proporcionaron una microestructura de los films con menor tamaño de partícula, que potenció las propiedades barrera al vapor de agua. Por su mayor aplicabilidad industrial, se emplearon técnicas de termo-procesado para la obtención del resto de films estudiados. Los obtenidos por mezcla con hidroxipropil metilcelulosa (HPMC) presentaron una fase dispersa de HPMC en la matriz de almidón y mejores propiedades barrera al vapor de agua, pero fueron algo más permeables al oxígeno, sobre todo cuando se incorporó ácido cítrico (CA) como compatibilizador. Este provocó entrecruzamiento en la matriz polimérica, incrementado ligeramente su dureza y reduciendo su extensibilidad. La incorporación de PCL en diferentes proporciones a los films de almidón obtenidos por termo-compresión, dio lugar a la separación de fases polímericas, detectándose una pequeña miscibilidad de la PCL en la fase rica en almidón que redujo la temperatura de transición vítrea de la fase amilácea. La heterogeneidad de su estructura y la falta de adhesión entre fases dio lugar a films demasiado frágiles, aunque en pequeña proporción (10%), la PCL reforzó la matriz (aumentó el módulo de elasticidad). Al aumentar la proporción de PCL, disminuyó la WVP de los films, pero aumentó la permeabilidad al oxígeno. La incorporación de CA como compatibilizador de estas mezclas aumentó la solubilidad en agua de los films por efecto de hidrólisis y supuso una mejora en las propiedades mecánicas de los films con baja proporción de PCL (10 %), pero no afectó a sus propiedades barrera. La incorporación de polietilenglicol (PEG 4000) a las mezclas con baja proporción de PCL no mejoró las propiedades de los films, potenciando la separación de fases. Las mezclas almidón:PCL con proporción másica 1:0.05, sin compatibilizador, fueron bastante homogéneas y exhibieron buen comportamiento mecánico y estabilidad. Para incorporar una mayor proporción de PCL, y mejorar la hidrofobicidad y estabilidad de los films, se modificó la PCL por reacción con glicidil metacrilato o anhídrido maleico y glicidil metacrilato (PCL-g), para su uso como compatibilizadores. Los films con 20% de PCL y 2.5 y 5 % de los PCL-g presentaron muy buenas propiedades mecánicas y de barrera al vapor de agua y a los gases y buena estabilidad al inhibir la retrogradación del almidón. Sus propiedades de barrera cumplieron con los requisitos de envasado de un número importante de productos alimentarios. La obtención de films bicapa por termo-compresión a partir de almidón (o almidón con 5% PCL) y PCL proporcionó un material con muy baja permeabilidad al vapor de agua y al oxígeno y buenas propiedades mecánicas. La adhesión entre las capas mejoró en gran medida con la incorporación de ácido ascórbico, y sobre todo de sorbato potásico, en la interfase en forma de disolución acuosa antes de la termo-compresión. Estos compuestos impartieron, a su vez, propiedades antioxidantes y antimicrobianas, respectivamente, a los films, mejorando su uso potencial para el envasad / [CA] S'han utilitzat diverses estratègies per a millorar les propietats físiques de films a base de midó de dacsa, amb glicerol (30 %) com plastificant, basades en l'increment del seu caràcter hidrofòbic, per a reduir la seua sensibilitat a l'aigüa. El midó es va mesclar amb diferents compostos (surfactants i polímers més hidrofòbics), amb i sense compatibilitzadors, per l'obtenció de films mixtos mitjançant diferents tècniques de processat (càsting, mesclat en fos, modelatge per compressió i extrusió). Es va estudiar també la formació de films bicapa midó-poli-e-caprolactona (PCL) mitjançant modelatge per compressió. L'addició de surfactants als films de midó elaborats per càsting va donar lloc a una disminució de la seua permeabilitat al vapor d'aigüa (WVP), però va augmentar la seua fragilitat. Els surfactants amb menor balanç hidròfil-lipòfil (HLB), i sòlids a temperatura ambient, varen proporcionar una microestructura dels films amb menor grandària de partícula, que varen potenciar les propietats barrera al vapor d'aigüa. Per la seua major aplicabilitat industrial, es van emprar tècniques de termo-processat per l'obtenció de la resta de films estudiats. Aquells obtinguts per mescla amb hidroxipropil-metilcellulosa (HPMC) varen presentar una fase dispersa de HPMC en la matriu de midó i millors propietats barrera al vapor d'aigüa, però varen ser un poc més permeables a l'oxigen, sobretot quan es va incorporar àcid cítric (CA) com compatibilitzador. Aquest va provocar entrecreuament en la matriu polimérica, incrementant lleugerament la seua duresa i reduïnt la seua extensibilitat. La incorporació de PCL en diferents proporcions als films de midó obtinguts per termo-compressió, va donar lloc a la separació de fases polimèriques, detectant-se una xicoteta miscibilitat de la PCL en la fase rica en midó que va reduir la temperatura de transició vítria de la fase amilàcea. L'heterogeneïtat de la seua estructura i la falta d'adhesió entre fases va donar lloc a films massa fràgils, encara que en xicoteta proporció (10%), la PCL va reforçar la matriu (augmentant el mòdul d'elasticitat). Al augmentar la proporció de PCL, va disminuir la WVP dels films, però va augmentar la permeabilitat a l'oxigen. La incorporació de CA com compatibilitzador d'aquestes mescles va augmentar la solubilitat en aigüa dels films per efecte d'hidròlisi i va suposar una millora en les propietats mecàniques dels films amb baixa proporció de PCL (10 %), però no va afectar les propietats barrera. La incorporació de polietilenglicol (PEG 4000) a les mescles amb baixa proporció de PCL no va millorar les propietats dels films, potenciant la separació de fases. Les mescles midó:PCL amb proporció màssica 1:0.05, sense compatibilitzador, varen ser prou homogènies i varen exhibir un bon comportament mecànic i una bona estabilitat. Per a incorporar una major proporció de PCL i millorar l'hidrofobicitat i estabilitat dels films, es va modificar la PCL per reacció amb glicidil metacrilat o anhídrid maleic i glicidil metacrilat (PCL-g), per al seu ús com compatibilitzadors. Els films amb 20% de PCL i 2.5 i 5 % dels PCL-g varen presentar molt bones propietats mecàniques i de barrera al vapor d'aigüa i als gasos i bona estabilitat al inhibir la retrogradació del midó. Les seues propietats de barrera varen complir amb els requisits d'envasament d'un nombre important de productes alimentaris. L'obtenció de films bicapa per termo-compressió a partir de midó (o midó amb 5% PCL) i PCL va proporcionar un material amb molt baixa permeabilitat al vapor d'aigüa i al oxigen i bones propietats mecàniques. L'adhesió entre les capes va millorar en gran mesura amb l'incorporació d'àcid ascòrbic, i sobretot de sorbat de potassi, en la interfase en forma de dissolució aquosa abans de la termocompressió. Aquestos compostos varen impartir, a la vegada, propietats antioxidants i antimicrobianes, respec / Ortega Toro, R. (2015). DESARROLLO Y CARACTERIZACION DE PELÍCULAS DE ALMIDÓN DE MAÍZ POR MEZCLADO CON COMPUESTOS MÁS HIDROFÓBICOS [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/52521 / Compendio Starch Films Biodegradable Surfactants Hydroxypropyl methylcellulose Polycaprolactone Poly(ethylene glycol) Citric acid Casting Compression molding Extrusion Grafting Physical properties Chemical properties Structural properties. TECNOLOGIA DE ALIMENTOS
93	Biodegradable Polymer Composites of Metal Organic Framework-5 (MOF-5) for the Efficient and Sustained Delivery of Cephalexin and Metronidazole Anim, Anoff, Mahmoud, L.A.M., Kelly, Adrian L., Katsikogianni, Maria, Nayak, Sanjit 20 September 2023 (has links) Yes / The sustained and controlled delivery of antimicrobial drugs has been largely studied using nanomaterials, like metal organic frameworks (MOFs), and various polymers. However, not much attention has been given to combining MOFs and biodegradable polymers towards the potentially more sustained release of active pharmaceutical ingredients. Herein, we report a comparative study of two widely used antimicrobial drugs, cephalexin and metronidazole, from zinc-based MOF-5 incorporated into biodegradable polycaprolactone (PCL) and poly-lactic glycolic acid (PLGA) composites. Cephalexin and metronidazole were separately loaded into MOF-5 post-synthetically, followed by their integration into biodegradable PLGA and PCL composites. The pristine MOF-5 and the loaded MOFs were thoroughly characterised using Fourier-transformed infrared (FT-IR) spectroscopy, scanning electron microscopy (SEM), thermogravimetric analysis (TGA) and powder X-ray diffraction (PXRD). Ultraviolet-visible (UV-Vis) spectroscopy studies were carried out to assess the release of the drugs in PBS for up to 72 h, showing a cumulative release of 24.95 wt% and 27.84 wt% for cephalexin and metronidazole, respectively. The antibacterial properties of the pristine MOF, pure drugs, drug-loaded MOFs and the loaded composites were assessed against Gram-positive and Gram-negative bacterial strains, Staphylococcus aureus or Staphylococcus epidermidis and Escherichia coli or Acinetobacter baumanii, respectively. A cephalexin-loaded MOF-5 composite of PCL (PCL-ceph@MOF-5) showed the best efficiency for the controlled release of drugs to inhibit the growth of the bacteria compared to the other composites. This study demonstrates that the combination of MOFs with biodegradable polymers can provide an efficient platform for the sustained release of antimicrobial drugs and can be a promising tool to manage antimicrobial resistance (AMR). Metal organic frameworks Biodegradable composites Antibacterial Antimicrobial resistance Metal organic frameworks (MOFs) Polycaprolactone (PCL) Poly-lactic glycolic acid (PLGA) Drug delivery
94	Développement de biomatériaux poreux pour la régénération osseuse : Biomatériaux biphasiques à base de phosphate tricalcique béta (β-TCP) / Development of porous biomaterials for bone regeneration Arbez, Baptiste 17 December 2018 (has links) Avec plus de 2 millions d’interventions chirurgicales par an dans le monde, les actes de chirurgie osseuse sont les plus fréquents, ce qui pousse les entreprises du secteur des biomatériaux pour la régénération osseuse à investir massivement pour sans cesse améliorer leurs produits. Cette thèse est issue d’un contrat CIFRE effectué avec l’entreprise Kasios afin de l’aider dans le développement de céramiques et polymères poreux principalement pour des applications en chirurgie maxillo-faciale. Les travaux réalisés s’articulent autour du développement de biomatériaux biphasiques à base de phosphate tricalcique béta (β-TCP). En premier lieu, des microfibres de polycaprolactone (PCL) incorporant des particules élémentaires de β-TCP ont été fabriquées par électrospinning. Les principales applications des fibres concernent la régénération osseuse guidée pour la préservation alvéolaire ou les opérations de relevés de sinus. L’électrospinning des fibres a utilisé des solvants ne présentant pas de toxicité aiguë. Les fibres ont formé des membranes manipulables qui peuvent être facilement découpées et suturées même en environnement humide. Les études in vitro n’ont révélé aucune cytotoxicité et les membranes ont permis la prolifération de cellules ostéoblastiques. La seconde étude a permis la fabrication d’éponges de gélatine et d’acide hyaluronique saturées ou recouvertes en surface de granules de β-TCP pour le comblement alvéolaire. Les éponges étaient facilement façonnables pour correspondre à l’alvéole du patient. Le chirurgien pourrait alors bénéficier de la nature biphasique du dispositif médical afin de faciliter l’implantation et éviter la manipulation séparée des éponges et des granules. L’utilisation des éponges permettrait par ailleurs d’assurer un positionnement idéal des granules pour la cicatrisation alvéolaire. La troisième étude, plus fondamentale, porte sur l’interaction des cellules osseuses avec le β-TCP et sa résorption. Des études de biomécanique et de biodégradation ainsi que de biodissolution ont également été réalisées sur des biomatériaux produits par l’entreprise. / With more than 2 million surgeries per year, bone tissue is one of the most concerned tissues and biomaterial companies have developed massive investments to continually improve bone regeneration.This thesis was conducted during a CIFRE contract (a tripartite contract linking a student, a university and acompany) and was done in association with the company Kasios for the development of new porous polymers and ceramics. This thesis was specifically centered in the development of biphasic biomaterials based upon beta tricalcium phosphate (β-TCP). First, polycaprolacton (PCL) microfibers incorporating β-TCP elementary particles were produced using electrospinning. These fibers were developed to provide membranes for guided bone regeneration usable in alveolar preservation and sinus lifting. Electrospinning of the fibers did not require any high toxicity solvent. Our fibers formed membranes that could easily be handled, cut and sutured in dry and wet environment. In vitrocytotoxicity studies confirmed the non-toxic nature of the material and showed the ability of the membranes to encourage survival and proliferation of osteoblastic cells. Secondly, freeze-dried gelatin and hyaluronicacid sponges saturated or embedded with β-TCP granules were developed for alveolar filling. Theses ponges could easily be shaped to fit the patient’s dental socket. The biphasic nature of the sponges could make the implantation easier and faster by avoiding surgeons to handle separately the granules and the sponges. This medical device could also insure a correct and optimal positioning of the granules for the patient healing. Lastly, a fundamental study was conducted on resorption of β-TCP and the interaction between bone cells and the biomaterial. Biomechanical and biodegradation/biodissolution studies were also done on different types of biomaterials produced by the company. Matériaux de comblement osseux Phosphate tricalcique béta (β-TCP) Polycaprolactone (PCL) Electrospinning Lyophilisation Morphologie cellulaire et résorption Bone filling materials Beta tricalcium phosphate (β-TCP) Polycaprolacton (PCL) Electrospinning Freeze-Drying Cell morphology and resorption 617.605
95	Preparation and Properties of Bio-Based Polyurethane Foam Prepared from Modified Natural Rubber and Poly(ε-caprolactone) / Préparation et Caractérisation des propriétés de mousses polyuréthane biobasées synthétisées à partir du caoutchouc naturel modifié et de la poly(ε-caprolactone) Rattanapan, Suwat 27 June 2016 (has links) L’objectif de ces travaux de recherche était de synthétiser de mousses polyuréthane (PUF) bio-basées à partir d’oligomères hydroxytéléchéliques issus du caoutchouc naturel (HTNR) ou à partir de poudrettes de pneus usagés (HTWT) et du diol de la polycaprolactone (PCL) comme segments soft. Les paramètres étudiés ont été le type de polyol et le rapport molaire entre HTNR/PCL et HTWT/PCL. La masse molaire de HTNR, HTWT et PCL étaient respectivement 1,800, 1400 et 2000 g/mol. L’effet du rapport molaire HTNR/PCL et HTWT/PCL (1/0, 1/0/5/, 1/1, et 0.5/1) sur la vitesse de formation des mousses et sur les propriétés chimiques et physiques a été étudié. Les structures chimiques de HTNR, HTWT et PUF ont été confirmées par FTIR et 1H-RMN. Le diol de la PCL était le plus réactif donc augmentant le contenu de PCL-diol la vitesse de formation des mousses a augmenté. La densité des mousses a changé légèrement avec le rapport molaire cependant la résistance à la traction reste dans la même gamme. Le diamètre moyen des cellules a augmenté en fonction du contenu de PCL-diol et la tendance inverse a été observée pour l’allongement à la rupture et la résistance à la compression. L’observation au microscope électronique à balayage (MEB) a montré que les mousses basées sur les HTNR étaient alvéolées et fermées. La biodégradabilité a été évaluée selon le test de Sturm. Polyéthylène à baisse densité et benzoate de sodium ont été utilisés respectivement comme témoins négatif et positif. Les mousses ont montré une période d’induction de 33 jours dans lequel le pourcentage de dégradation était ~ 7-10%. La biodégradation de PUF contenant seulement HTNR a été 8.4% après 28 jours et 31.89% après 60 jours ; les PUF contenants 1/0.5 HTNR/PCL ont montré un pourcentage supérieure : 11.31% après 28 jours et 45.6% après 60 jours. Le rapport molaire HTWT/PCL a influencé beaucoup la vitesse de formation des mousses et leur morphologie. Cellules fermées de forme polyédrique ont été observé par microscopie électronique à balayage. Les résultats de l’analyse thermogravimétrique ont montré que l’addition du diol de la PCL a augmenté la température de dégradation. Il a été observé qu’une basse vitesse de réaction génère des mousses à haute densité, petit diamètre de cellule et haute distribution des diamètres. La biodégradation des PUF contenant seulement HTWT a été 31.2% après 28 jours et 51.3% après 60 jours, tandis que les PUF contenant 1/0.5 HTWT/PCL ont montré une dégradation plus élevée : 39.1% après 28 jours et 64.3% après 60 jours. La vitesse de formation des mousses basées sur les HTWT était supérieure à celle des mousses basées sur les HTNR. Toutes les mousses basées sur les HTWT ont une densité supérieure et une taille de cellule inférieure à celles basées sur HTNR. La structure des cellules des mousses basées sur les HTNR ou HTWT était différente cependant toutes les mousses ont montré des cellules quasi complètement fermées. Les mousses basées sur les HTWT ont montré des propriétés thermiques et de biodégradation meilleures par rapport aux mousses basées sur les HTNR. / The aim of this research was to prepare a bio-based polyurethane foam (PUF) containing hydroxyl telechelic oligomers from natural rubber (HTNR) and waste tire crumbs (HTWT) and polycaprolactone diol (PCL) as soft segments. The studied parameters included type of polyols and molar ratio between HTNR/PCL and HTWT/PCL. The molecular weight of HTNR and HTWT derived from 1H-NMR spectra were 1,800 and 1,400 g/mol, respectively. The molecular weight of PCL diol was 2000 g/mol. The effect of HTNR/PCL and HTWT/PCL molar ratio (1/0, 1/0.5, 1/1 and 0.5/1) on the foam formation rate and physical and chemical properties of the resulting PUF was investigated. The chemical structure of HTNR, HTWT and PUF were confirmed by FTIR and 1H-NMR. PCL diol provided faster reaction, thus higher PCL diol content showed higher foam formation rate. The foam density slightly changed with the molar ratio whereas the specific tensile strength of all samples was in the same range. The average diameter of cell increased with increasing contents of PCL diol. The addition of PCL diol resulted in reduced elongation at break and compressive strength. The cellular structure observed by SEM micrographs of HTNR based foams showed an almost closed cell. The biodegradability was assessed according to a modified Sturm test. Low density polyethylene and sodium benzoate were used as a negative and positive control sample, respectively. PUF samples showed an induction time of 33 days in which the percentage of biodegradation was  7-11%. The biodegradation of PUF containing only HTNR was 8.4% and 31.89% at 28 days and 60 days of testing respectively whereas the PUF containing 1/0.5 HTNR/PCL (by mole) showed a higher biodegradation: 11.31% and 45.6% at 28 days and 60 days of testing respectively. The molar ratio of HTWT/PCL strongly affected the kinetic rate of foam formation and foam morphology. According to SEM micrographs, polyhedral closed cells were observed. The addition of the PCL diol increased the thermal degradation temperature of the PUF based on TGA results. A low kinetic rate provided PUF with a high density, small cell size and a broad cell size distribution. The biodegradation of PUF containing only HTWT was 31.2% and 51.3% at 28 days and 60 days of testing respectively whereas the PUF containing 1/0.5 HTWT/PCL diols (by mole) showed a higher biodegradation: 39.1% and 64.3% at 28 days and 60 days of testing respectively. The foam formation rate of HTWT based PUF was higher than the one of HTNR based PUF. All HTWT based PUF have a higher density than HTNR based PUF. The HTWT based PUF had an inferior cell size in comparison to HTNR based PUF. The cellular structure of HTNR based and HTWT based PUF were different, but all PUFs showed almost closed cells. The HTWT based PUF had a higher thermal degradation temperature and biodegradation properties than foams from HTNR. / วัตถุประสงค์ของงานวิจัยนี้ เพื่อทำการเตรียมโฟมพอลิยูรีเทนชีวภาพ (PUF) จากยางธรรมชาติดัดแปรที่มีหมู่ปลายไฮดรอกซิล (HTNR) ยางคลัมบ์ดัดแปรที่มีหมู่ปลาย ไฮดรอกซิล (HTWT) และพอลิคาโปรแลคโทน (PCL) ศึกษาผลของชนิดพอลิออล และสัดส่วนโดยโมลระหว่าง HTNR/PCL และ HTWT/PCL ที่สัดส่วน 1/0, 1/0.5, 1/1 และ 0.5/1 โดยโมล นํ้าหนักโมเลกุลของ HTNR, HTWT และ PCL ที่ใช้สำหรับงานวิจัยนี้ คำนวณจาก 1H-NMR คือ 1,800, 1,400 และ 2,000 g/mol ตามลำดับ ลักษณะโครงสร้างทางเคมีของ HTNR, HTWT และPUF สามารถวิเคราะห์และยืนยันด้วยเทคนิค FTIR และ 1H-NMR รวมถึงทำการวัดอัตราการก่อโฟม (Foam formation rate) ทดสอบสมบัติทางกายภาพ ทางเคมี และสมบัติการย่อยสลายทางชีวภาพ พบว่าในกรณีของโฟมพอลิยูรีเทนจาก HTNR/PCL เมื่อใช้ PCL ในปริมาณที่มากขึ้นจะส่งผลให้อัตราการก่อโฟมเร็วขึ้น และขนาดของเซลโฟมมีขนาดใหญ่ขึ้นด้วย ในขณะที่ค่าความหนาแน่น และความต้านทานต่อแรงดึงจำเพาะมีการเปลี่ยนแปลงเล็กน้อย การเติม PCL ในส่วนผสมของโฟมยังส่งผลให้ความสามารถในการยืด ณ จุดขาด และความทนทานต่อการกดมีค่าลดลง การคืนตัวหลังการกดของโฟม PUF2 (สัดส่วนระหว่าง HTNR/PCL = 1/0.5) จะให้ค่าตํ่าที่สุดคือ 40% ลักษณะของโฟมที่ได้จากการทดลองนี้โดยส่วนใหญ่จะเป็นแบบเซลปิด ความสามารถในการย่อยสลายทางชีวภาพของโฟม ทดสอบโดยใช้วิธี Sturm Test มี LDPE เป็นตัวเปรียบเทียบเชิงลบ และใช้ Sodium benzoate เป็นตัวเปรียบเทียบเชิงบวก พบว่าโฟมเริ่มมีการย่อยสายเกิดขึ้นอย่างเห็นได้ชัดที่เวลา 33 วัน มีเปอร์เซ็นต์การย่อยสลายในช่วง 7-11 เปอร์เซ็นต์ เปอร์เซ็นต์การย่อยสลายของโฟมจาก HTNR (PUF1) อยู่ที่ระดับ 8.4 และ 31.89 เปอร์เซ็นต์ และเปอร์เซ็นต์การย่อยสลายของโฟมจาก HTNR/PCL (1/0.5) อยู่ที่ระดับ 11.31 และ 45.6 เปอร์เซ็นต์ ที่เวลาในการทดสอบ 28 และ 60 วัน ตามลำดับ กรณีของโฟมพอลิยูรีเทนจาก HTWT/PCL เมื่อใช้ PCL ในปริมาณที่มากขึ้นจะส่งผลให้ค่าความหนาแน่นสูงขึ้น ขนาดของเซลโฟมลดลงมีการกระจายของเซลในวงกว้างไม่สมํ่าเสมอ เปอร์เซ็นต์การย่อยสลายทางชีวภาพของโฟมจาก HTWT (PUF5) อยู่ที่ระดับ 31.2 และ 51.3 เปอร์เซ็นต์ และเปอร์เซ็นต์การย่อยสลายของโฟมจาก HTWT/PCL (1/0.5) อยู่ที่ระดับ 39.1 และ 64.3 เปอร์เซ็นต์ ที่เวลาในการทดสอบ 28 และ 60 วัน ตามลำดับ เมื่อทำการเปรียบเทียบโฟมที่ได้จากการเตรียมโดยใช้พอลิออลหลักเป็น HTNR และ HTWT พบว่าโฟมจากพอลิออลหลัก HTWT ให้อัตราการก่อตัวของโฟมเร็วกว่า ขนาดของเซลโฟมเล็กกว่า ความหนาแน่น ความต้านทานต่อความร้อน และเปอร์เซ็นต์การย่อยสลายทางชีวภาพสูงกว่า เมื่อเทียบกับโฟมจากพอลิออลหลัก HTNR Polymères bio-basés Mousse polyuréthane bio-basée Polymères biodégradables Caoutchouc naturel Polycaprolactone Recyclage pneumatiques usagés Biodégradabilité Bio-based polymer Bio-based polyurethane foam Biodegradable polymer Natural rubber Waste tire recycle Biodegradability 668.493
96	Charakterizace vyfukovaných fólií z měkčeného polylaktidu / Characterization of blowing films from softened polylactide Kubíček, Václav January 2020 (has links) The master's thesis focuses on preparation of blown films from polylactid acid (PLA) which was blended with selected polyesteres – poly(butylene adipate-co-terephtalate) (PBAT), polycaprolactone (PCL) and polybutylene succinate (PBS) – and thermoplastic starch (TPS) in amount of 30% in order to soften PLA films. The influence of the aditives on static and mechanical tensile properties, on structure, morphology and thermal properties of the films was determined and the obtained parameters were compared to properties of films prepared from neat PLA and high density polyethylene (HDPE). The results showed that the additives increased crystalinity of PLA and thus significantly influenced the properties of the films. In contrast to the film from neat PLA, softening in terms of lowering glass transition temperature occured only by adding PBS and TPS, in terms of increasing ductility only by adding PBAT. All PLA films showed nearly constant elastic modulus up to the beginning of glass transition enabling their potential application till 50 °C. Preparation of the film with TPS was problematic and the film showed the worst mechanical properties. Preparation of other films was without any problems. The most promising additive from the tested ones was PBAT which showed comparable mechanical properties as the film from HDPE.
97	Healing properties of surface-coated polycaprolactone-co-lactide scaffolds: A pilot study in sheep Rentsch, Claudia, Schneiders, Wolfgang, Hess, Ricarda, Rentsch, Barbe, Bernhardt, Ricardo, Spekl, Kathrin, Schneider, Konrad, Scharnweber, Dieter, Biewener, Achim, Rammelt, Stefan 11 October 2019 (has links) The aim of this pilot study was to evaluate the bioactive, surface-coated polycaprolactone-co-lactide scaffolds as bone implants in a tibia critical size defect model. Polycaprolactone-co-lactide scaffolds were coated with collagen type I and chondroitin sulfate and 30 piled up polycaprolactone-co-lactide scaffolds were implanted into a 3 cm sheep tibia critical size defect for 3 or 12 months (n¼5 each). Bone healing was estimated by quantification of bone volume in the defects on computer tomography and microcomputer tomography scans, plain radiographs, biomechanical testing as well as by histological evaluations. New bone formation occurred at the proximal and distal ends of the tibia in both groups. The current pilot study revealed a mean new bone formation of 63% and 172% after 3 and 12 months, respectively. The bioactive, surface coated, highly porous three-dimensional polycaprolactone-co-lactide scaffold stack itself acted as a guide rail for new bone formation along and into the implant. These preliminary data are encouraging for future experiments with a larger group of animals. info:eu-repo/classification/ddc/610 ddc:610
98	The effect of crude water extracts of Tulbaghia violacea Harv. on scaffolds with cardiovascular applications Madike, Lerato Nellvecia 02 1900 (has links) PhD (Department of Biotechnology, Faculty of Applied and Computer Sciences), Vaal University of Technology. / Tulbaghia violacea Harv. has found extensive uses in traditional medicine for the treatment of numerous ailments among which are tuberculosis, oesophageal cancer, diabetes and cardiovascular diseases. Current reports show that cardiovascular diseases are now the primary cause of mortality worldwide. Thus, the potential of T. violacea plant extracts against cardiovascular diseases should be explored. The objectives of this study were, (i) to conduct qualitative and quantitative preliminary phytochemical screening of T. violacea aqueous leaf extracts, (ii) to conduct Gas chromatography–mass spectrometry (GC-MS) analysis for screening of compounds present in the plant extract, (iii) to evaluate the antioxidant activity of the T. violacea crude extracts using the DPPH:1.1-diphenyl-2-picrylhydrazyl and ABTS: 2,2-azino-bis 3-ethylebenzthiazoline-6-sulfonic acid assays, (iv) to evaluate the antimicrobial activity of the T. violacea crude extracts using disk diffusion and Minimum inhibitory concentration/Minimum bactericidal concentration (MIC/MBC), (v) to evaluate the antithrombogenic properties of T. violacea crude extracts on polystyrene, (vi) to fabricate polycaprolactone (PCL) and PCL-T. violacea incorporated scaffolds, (vii) to evaluate the antithrombogenic properties of T. violacea crude extracts on the fabricated PCL and PCL-T. violacea fabricated scaffolds and, (viii) to evaluate the growth and differentiation of adipose derived stem cells (ADSCs) on the fabricated scaffolds. The qualitative and quantitative phytochemical screening was conducted using standard procedures. Folin-Ciocalteu method was used to evaluate both total phenolic content (TPC) and total tannin content (TTC), the Aluminium chloride method was used for total flavonoid content (TFC) and GC-MS was used to screen for compounds present in the plant extract. The antioxidant activity was evaluated using DPPH and ABTS and the antimicrobial activity was evaluated using disc diffusion and MIC/MBC assays. The antithrombogenic properties of the T. violacea aqueous leaf extracts was then evaluated using platelet activation and whole blood clotting kinetics on polystyrene discs which have been reported to induce platelet activation. The experiment was performed in the absence and presence of 100 and 1000 μg/ml T. violacea plant extracts for both the platelet activation study which used blood plasma and the whole blood clotting kinetics assay which used fresh whole blood. Platelet adhesion was evaluated using fluorescence microscopy and a scanning electron microscope (SEM) was used to evaluate their morphology. Three scaffolds designated as PCL, 10% Tvio and 15% Tvio were fabricated which consisted of a 10% PCL powder and 10% as well as 15% T. violacea aqueous plant extract with respect to the PCL powder weight. The scaffolds were then characterized using Fourier-transform infrared spectroscopy (FTIR) and Energy-dispersive x-ray spectroscopy (EDS). The scaffolds were then evaluated for their antithrombogenic properties in the presence and absence of 100 and 1000 μg/ml T. violacea plant extracts. Platelet adhesion was evaluated using a fluorescent microscope and the morphology was evaluated using SEM. For the cell study, adipose derived stem cells (ADSCs) were cultured on the designed scaffolds and evaluated for their toxicity, viability, adhesion, proliferation, morphology and differentiation into osteoblasts over a period of 3 weeks. Lactate dehydrogenase (LDH) assay was used for toxicity studies, alamar blue assay was used for viability, fluorescence microscopy was used to evaluate cellular adhesion and proliferation while the alkaline phosphate (ALP) assay was used to evaluate differentiation of the cells into osteoblasts. Cell morphology was evaluated using SEM. Phytochemical screening of the prepared T. violacea aqueous extract revealed the presence of terpenoids, flavonoids, cardiac glycosides, saponins, protein, phenols, tannins, carbohydrates and amino acids. This is the first study that has identified the presence of carbohydrates and amino acids in T. violacea aqueous leaf extracts. Different concentrations of 0.1, 1.0 and 10 mg/ml of plant extract were used to conduct the quantitative phytochemical screening assays. There was a concentration dependent increase in the amount of phenols, tannins and flavonoids as the concentration of the plant extracts increased. This was the first study that evaluated the total tannic content of T. violacea plant extracts. The amount of total phenols was higher than that of flavonoids and tannins at every concentration range studied followed by the total flavonoids and lastly total tannins. The GC-MS analysis showed the presence of 33 compounds among which were 2,4 – Dithiapentate - 2,2-dioxide, Cannabidiol, 2,4,5,7 –Tetrathiaoctane and 2,4,5,7 - Tetrathiaoctane 2-dioxide. The presence of sulphur compounds support the characteristic garlic-like smell as well as some of the biological activities of T. violacea plant extracts. The antioxidant activities based on DPPH (0.49 mg/ml) and ABTS (0.24 mg/ml) suggest that T. violacea can be used as potential antioxidant agents. For the antimicrobial activity using disc diffusion, the extracts exhibited appreciable antibacterial activities against Bacillus subtilis, Serratia marcescens, Staphylococcus aureus and S. epidermidis. The highest zone of inhibition was observed for S. epidermidis at 19.50 ± 0.87 mm. The MIC results revealed that the plant extract of T. violacea was moderately active against B. subtilis, S. aureus, S. epidermidis, E. coli, and S. marcescens with MIC value of 2.5 mg/ml. However, the antimicrobial effect of the extract on S. epidermidis was bactericidal when compared to the bacteriostatic effect on the other active microorganisms. The antithrombogenic results on the polystyrene discs showed a significant reduction in the number of platelets that adhered on the polystyrene surfaces treated with plasma mixed with 100 μg/ml of plant extract when compared to the untreated control and the 1000 μg/ml treatment. For the 1000 μg/ml treatment, there was a significant increase in the number of platelets that adhered to polystyrene surfaces. These results were confirmed by the fluorescence and SEM results which showed a higher platelet count for the 1000 μg/ml treatment when compared to the other groups. The whole blood clotting kinetics study showed delayed blood clotting with the 100 μg/ml treatment over a period of 60 min when compared to the untreated control and the 1000 μg/ml treatment. These results correspond with the lower platelet adhesion observation and thus confirm the anticlotting properties of T. violacea aqueous leaf extracts at lower concentrations. The mean diameter of the scaffolds was recorded on the SEM as 275.60 ± 60.65 nm, 193 ± 30 nm and 537 ± 138 nm for the PCL, 10% Tvio and 15% Tvio scaffolds, respectively. The FTIR spectrum revealed the presence of amide groups as well hydroxyl O–H stretching groups which were the characteristic groups for the presence of T. violacea plant extracts in the polycaprolactone. The EDS results showed the presence of potassium, chlorine and sulphur compounds which were only present in the T. violacea scaffolds in addition to the carbon, oxygen and silicon observed in the PCL scaffold. The fabricated scaffolds were then used to evaluate platelet adhesion and activation on blood plasma in the absence and presence of 100 and 1000 μg/ml T. violacea aqueous leaf extracts. The results showed that the 10% Tvio scaffold was more effective in inhibiting platelet adhesion and activation at every treatment group especially when plasma was used in the absence of T. violacea plant extracts. A similar observation to the polystyrene study was observed were addition of 1000 μg/ml of plant extract resulted in the highest number of activated platelets. The study suggests the potential of the 10% Tvio scaffold in the prevention of platelet adhesion and aggregation. The in vitro cell adhesion, proliferation and differentiation of adipose derived stem cells (ADSCs) on the fabricated T. violacea loaded PCL nanofibers was then evaluated. The LDH assay illustrated less activity on the 10% Tvio scaffold when compared to PCL and 15% Tvio scaffolds however, none of the scaffolds were considered as toxic. The alamar blue assay was used for viability after 4 and 7 days of culture. The results showed a significant increase in cell viability for all scaffolds from day 4 to day 7 with the 10% Tvio scaffold having the highest overall cell viability for both day 4 and day 7 of cell cultures. Immunofluorescence staining was then used to count the number of cells using DAPI (4′,6-diamidino-2-phenylindole) stained images and illustrated that the T. violacea incorporated scaffolds supported better cell growth compared to the PCL scaffold. Cell morphology on the T. violacea scaffolds was denser and spread out into cellular extensions when compared to the PCL scaffold after 7 days of cell culture, supporting the higher number of adhered cells from the fluorescence results. For the long term cell study after week 1 and 3, the ALP results showed a significant difference in ALP activity between week 1 and week 3 for all scaffolds. The highest ALP activity was observed for the 15% Tvio scaffolds which is a marker for initial phase of bone matrix deposition. The designed T. violacea scaffolds supported better cell growth compared to the PCL scaffold and their morphology was more spread out and covered the entire surface of the scaffolds after week 3. Lastly, the cell count and osteocalcin differentiation was more prominent on 10% Tvio scaffold indicating higher levels of the protein marker for bone formation. Thus, supporting the use of the 10% Tvio scaffold for long-term cell studies. In conclusion, the results of this study indicated that the aqueous extract of T. violacea is rich is phytochemicals and also possess a broad range of pharmaceutically important compounds which may be attributed to the high antioxidant and antimicrobial activities identified. The results from this study suggest that T. violacea aqueous extracts have antithrombogenic properties at lower concentrations. Scaffolds fabricated with the incorporation of T. violacea plant extract also confirm the potential antiplatelet activity of the fabricated 10% Tvio scaffold. The results also suggest the potential of the fabricated 10% Tvio scaffold to enhance cell adhesion, proliferation and differentiation over long-term cell studies. It can thus be recommended that T. violacea may be useful for tissue engineering applications and bone repair with prospects of preventing cardiovascular diseases associated with bone defects. This research study has provided the foundation for clinical evaluation and outlined the potential effects of T. violacea aqueous leaf extracts as a clinical drug. Adipose derived stem cells Alkaline phosphate Alamar blue Antimicrobial Antioxidants Antithrombogenic Antiplatelet Electrospinning Immunofluorescence Lactate dehydrogenase Osteoblasts Phytoconstituents Platelets Polycaprolactone Scanning electron microscopy Scaffolds Tulbaghia violacea Dissertations, Academic -- South Africa Anticoagulants (Medicine) Medicinal plants Cardiovascular agents Hypercholesteremia
99	Stabilita systémů pro řízené uvolňování léčiv na bázi plastifikovaného škrobu / Stability of controlled drug release systems based on plasticized starch Zhukouskaya, Hanna January 2022 (has links) The thesis is focused on the research of stability of controlled drug release systems based on a blend of plasticized starch/polycaprolactone (TPS/PCL) that served as a carrier. Antibiotic vancomycin was used as a model drug, and its release from TPS/PCL pellets into aqueous environment was followed by UV-spectroscopy and the obtained time dependences were treated by a simple kinetic model. Moreover, the simultaneous release of starch particles to the surrounding liquid phase was studied by static and dynamic light scattering as well as transmission electron microscopy (TEM) in order to obtain information on the stability of biodegradable matrix and on the structure of the products of the pellet decomposition on a nanoscale level. Key words: vancomycin, starch, drug delivery system, polycaprolactone (PCL), particle release, dynamic light scattering (DLS), static light scattering (SLS)
100	Micropatterning Neuronal Networks on Nanofiber Platforms Malkoc, Veysi 27 August 2013 (has links) No description available. Biomedical Engineering Biochemistry Biology Chemical Engineering Developmental Biology Electrical Engineering Engineering Neurobiology Neurosciences Technology Micropatterning Neuronal Networks PC12 Differentiation Neurite Vacuum Seeding Pattern Electrospinning Gelatin Polycaprolactone Nanofibers Photolithography Aligned Nanofibers Microfabrication Cell Patterning Nerve Growth Factor

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