Produ????o heter??loga de polihidroxialcanoato sintase (PhaC), biocatalisador da s??ntese de Poli (??cido l??tico) (PLA) em Komagataella phaffii

Costa, Tha??s Duarte

03 April 2018

Submitted by Sara Ribeiro (sara.ribeiro@ucb.br) on 2018-06-06T14:01:03Z No. of bitstreams: 1 ThaisDuarteCostaDissertacao2018.pdf: 3076865 bytes, checksum: 13af7d694f07d7e2dcc9281907285b62 (MD5) / Approved for entry into archive by Sara Ribeiro (sara.ribeiro@ucb.br) on 2018-06-06T14:01:33Z (GMT) No. of bitstreams: 1 ThaisDuarteCostaDissertacao2018.pdf: 3076865 bytes, checksum: 13af7d694f07d7e2dcc9281907285b62 (MD5) / Made available in DSpace on 2018-06-06T14:01:33Z (GMT). No. of bitstreams: 1 ThaisDuarteCostaDissertacao2018.pdf: 3076865 bytes, checksum: 13af7d694f07d7e2dcc9281907285b62 (MD5) Previous issue date: 2018-04-03 / Polyethylene terephthalate (PET) based plastics are serious environmental problem due to long decomposition periods and petroleum-dependent origin. Therefore, bioplastics are a promising alternative as their synthesized by the polimerization of renewable raw materials, yeilding biodegradable and environmental-friendly products. One of the most relevant polymers in this scenario is the poly lactic acid (PLA) formed from lactic acid monomers. The main characteristics of PLA are low toxicity to humans due to high biocompatibility, for example in biomedical materials, and biodegradability, which reduces their time in landfills due to the faster decomposition process. These properties provide wide applicability of this polymer in various areas such as packaging, textiles and biomedical materials. Commonly, the chemical polymerization process of PLA can be carried out in two ways, (1) ring opening for further polymerization or (2) condensation of the lactic acids. In both cases, the presence of metal catalysts such as zinc, aluminum and magnesium is required. These, in addition to being toxic, hinder the use of the polymer, for instance, in the biomedical area, for generating metallic waste. An alternative to such catalysts is the use of biocatalysts. Polyhydroxyalkanoate synthase (phaC) has been previously used for the polymerization of lactic acid produced in recombinant strains of Escherichia coli. Thus, within the lactic acid production platform in recombinant Komagataella phaffi strains, the objective of this work is to produce the phaC enzyme with point mutations at the S325N and Q481I sites. These residue changes provide a greater specificity of the enzyme-substrate complex to act as a biocatalyst in the polymerization of lactic acid in Komagataella phaffi. In this study, three cloning strategies were performed between the phaCPs insert and pGAPZ??B vector. To date, there have been no transformants in any of the strategies. However, Strategy C has not yet been fully implemented, which also results in the possibility of cloning between phaCPs insert and pGAPZ??B expression vector with the correct sequence. It is expected that successful cloning, recombinant DNA sequencing and plasmid insertion into Komagataella phaffii genome can be performed to conclude this study. / Os problemas ambientais gerados por pl??sticos ?? base de tereftalato de polietileno (PET) se devem ao extenso tempo de decomposi????o desses materiais no meio ambiente e a sua fonte de origem que ?? dependente de petr??leo. Diante disso, biopl??sticos t??m sido uma alternativa promissora devido ao fato de serem biologicamente degrad??veis, al??m de terem como origem mat??rias-primas renov??veis, o que os tornam sustent??veis. Um dos pol??meros mais relevantes desse cen??rio ?? o poli (??cido l??tico) (PLA) formado a partir de mon??meros de ??cido l??tico. As principais caracter??sticas do PLA s??o baixa toxicidade aos humanos devido ?? alta biocompatibilidade, como por exemplo em mat??rias biom??dicos, e biodegradabilidade, o que reduz seu tempo em aterros devido ao processo mais r??pido de decomposi????o. Essas propriedades proporcionam uma ampla aplicabilidade deste pol??mero em diversas ??reas como embalagens, ??reas t??xteis e materiais biom??dicos. Comumente, o processo qu??mico de polimeriza????o do PLA pode ser realizado por meio de duas formas, (1) abertura do anel para posterior polimeriza????o ou (2) por condensa????o dos ??cidos l??ticos. Nos dois casos, ?? necess??ria a presen??a de catalisadores met??licos como zinco, alum??nio e magn??sio. Estes, al??m de serem t??xicos atrapalham na utiliza????o do pol??mero, por exemplo, na ??rea biom??dica, por gerar res??duos met??licos. Uma alternativa a esses catalisadores ?? a utiliza????o de biocatalisadores, como a polihidroxialcanoato sintase (phaC), j?? foi previamente utilizada para polimeriza????o de ??cido l??tico produzido em cepas recombinantes de Escherichia coli. Assim, dentro da plataforma de produ????o de ??cido l??tico, em cepas de Komagataella phaffii recombinantes, o objetivo deste trabalho ?? referente ?? produ????o da enzima phaC com muta????es pontuais nos s??tios S325N e Q481I, pois essas altera????es proporcionam uma maior especificidade do complexo enzima-substrato, para que atue como biocatalisador na polimeriza????o de ??cido l??tico em Komagataella phaffi. Neste estudo, foram realizadas tr??s estrat??gias de clonagem entre o inserto phaCPs e vetor pGAPZ??B. At?? o presente, n??o houve transformantes em nenhuma das estrat??gias. Entretanto, a Estrat??gia C ainda n??o foi executada completamente, o que resulta ainda na possibilidade de clonagem entre inserto phaCPs e vetor de express??o pGAPZ??B com a sequ??ncia correta. A expectativa deste estudo ?? a conclus??o da clonagem, verifica????o da sequ??ncia correta do DNA recombinante atrav??s do resultado do sequenciamento e inser????o do plasm??deo ao genoma da levedura Komagataella phaffii.

Biopl??stico

Biocatalisador

Komagataella phaffii

Poli (??cido l??tico) (PLA)

Polyhydroxyalkanoate synthase (phaC)

Poly lactic acid (PLA)

Biocatalyst

CNPQ::CIENCIAS BIOLOGICAS::BIOQUIMICA

Photocatalytic behaviour of nano sized titanium dioxide (TiO2) blended in poly (lactic acid) (PLA) via melt blending method : focus on textile applications

CHENGJIAO, ZHANG

January 2013

During this project, photocatalytic material, nano sized titanium dioxide, was introduced into poly (lactic acid) to produce functional surface capable of self-cleaning property. Samples containing 0%, 5%, 10%, 15% and 20% titanium dioxide were prepared and etched with proteinase K to expose the nano particles on the surface. It was shown that the nano titanium dioxide could dispersed in the polymer matrix pretty well, it was also found that the nano particles affected the thermal and mechanical properties of the polymer matrix differently , due to difference in concentrations of nano filler. The self-cleaning property was evaluated by decolouration of stains caused by coffee and red wine, also by detecting degradation of methylene blue via a UV-vis spectrophotometer. By measuring changes in absorbance of light at 664nm wavelength after a maximum of 24h UV irradiation, it was possible to measure the degradation property of the samples. / Program: Masterutbildning i textilteknik

Titanium dioxide (P25

poly(lactic acid)(PLA),

self-cleaning surface

photocatalyst

photocaltalytic activity

enzymatic degradation

methylene blue photo-degradation

Engineering and Technology

Teknik och teknologier

Biological Applications of Elastin- and Mussel-Inspired Polymers

Sydney E. Hollingshead (5929754)

03 January 2019

<div>Wounds are created in soft and hard tissue through surgery or disease. As the wound heals, the tissue is held in place using sutures or staples for soft tissue or plates, pins, or screws for hard tissues. These fixation methods inherently damage the surrounding healthy tissue. Surgical adhesives are a non-damaging alternative to these methods. In order to be effective, surgical adhesives must be biocompatible,</div><div>adhere strongly in a moist environment, and have mechanical properties similar to those of the native tissue.</div><div><br></div><div><div>To address the design criteria for surgical adhesives, we look to nature to find inspiration from compounds that provide these properties. Mussels use catechol-based</div><div>molecules to adhere to surfaces in wet and turbulent environments. Incorporating catechols into polymer systems can provide adhesion even in moist biological environments.</div><div>Mimics of elastomeric proteins from soft tissue can be used as backbones for soft and flexible adhesive systems. In particular, elastin-inspired proteins have a well-defined modular sequence that allows for a range of design choices. In this work, we explored the behavior of elastin- and mussel-inspired natural and synthetic polymers in biologically relevant environments.</div></div><div><br></div><div><div>First, the cytocompatibility of a catechol-containing poly(lactic acid) (cPLA) hard tissue adhesive was studied. The cPLA polymer was reacted with iron- or periodatebased</div><div>crosslinkers and compared to PLA. Fibroblasts grown directly on cPLA or cultured with leachate from cPLA had high viability but slower growth than cells on PLA. The periodate crosslinker was significantly cytotoxic, and cells grown on cPLA crosslinked with periodate had reduced metabolism and slowed growth. Cells grown on or in leachate from iron-crosslinked cPLA had similar viability, metabolism, and growth to cells on or in leachate from cPLA. The iron-crosslinked cPLA is a promising</div><div>cytocompatible adhesive for hard tissue applications.</div></div><div><br></div><div><div>Second, two elastin-like proteins (ELP) were developed that had pH-sensitive properties in solution and when crosslinked into hydrogels. Both ELPs had a large number of ionizable tyrosine and lysine residues, and one design also had a large number of ionizable histidine and aspartic acid residues. The stiffness of the hydrogels was maximized at pH values near the isoelectric point of the protein. The stoichometric ratio of crosslinker used affected hydrogel stiffness but did not significantly alter the pH-sensitivity of the gel. The crosslinked gel shrank when swelled at physiological pH. The pH-sensitive mechanical properties of hydrogels made from the two ELPs did not vary significantly. The tyrosine and lysine residues in one ELP were also</div><div>chemically blocked through acetylation to lower the isolectric point of the protein. The acetylated hydrogels had maximum stiffness at a pH near the isoelectric point of the acetylated ELP. The stiffness of both the native and acetylated gels were within the range of soft tissue. Through a combination of crosslinker ratio and chemical modification, the pH-responsive properties of the elastin-inspired hydrogels could be tuned.</div></div><div><br></div><div><div>Finally, adhesive proteins were created that were inspired by both elastin and mussels. An ELP was modified to include catechol groups (mELP). The ELP and mELP were optimized for adhesive use in a soft tissue system. A warm and humid environment was used to study the adhesion of these proteins on pig skin. Iron and (hydroxymethyl) phosphine crosslinkers increased the adhesive strength of both proteins, and periodate increased the adhesive strength of mELP. The adhesive strengths of the proteins were maximized when mELP was mixed with iron or when either protein were mixed with (hydroxymethyl)phosphine crosslinkers. These maximized adhesives were 12-17 times stronger than a commercially available sealant. In addition,</div><div>the iron and mELP adhesive formulation achieved high adhesive strengths even when cured for only ten minutes. This adhesive formula shows promise for adhesive</div><div>applications on soft tissue.</div></div>

Elastin-Like Polypeptide (ELP)

Mussel-Inspired Adhesion

L-3,4-dihydroxyphenylalanine (DOPA)

Surgical Adhesive

Hydrogel

pH-Sensitive

Smart materials.

Poly(Lactic Acid) (PLA)

Cytocompatibility

Evolutions moléculaires au cours de la dégradation biotique et abiotique de polymères bio-sourcés (PLA et PBS) et fossiles à l’aide de la viscoélasticité à l’état fondu / Molecular evolutions during biotic and abiotic degradation of bio-based polymers (PLA and PBS) and fossil polymers thanks to melt viscoelasticity

Ramoné, Audrey

11 December 2015

Pour limiter la production de déchets, la voie de polymères biodégradables est largement explorée. La biodégradation en compost est un phénomène complexe qui dépend de la température, de l’humidité, du soleil et du polymère lui-même. Dans un premier temps, les effets de ces différents paramètres sur la biodégradation de l’acide polylactique (PLA) sont étudiés à l’aide de la viscoélasticité à l’état fondu. Il en résulte que l’échantillon lui-même n’a que peu d’influence sur sa dégradation, mais les conditions de dégradation influencent d’avantage les phénomènes mis en jeu. Dans un deuxième temps, le PLA est associé au poly(butylène succinate) (PBS), un polymère plus favorable à la biodégradation afin d’améliorer la dégradation du PLA. Après s’être intéressée à la biodégradation de polymères « compostables », cette étude se tourne vers la biodégradation d’un polymère non-biodégradable : le polypropylène (PP). Afin d’initier un processus de bio assimilation, des charges sont ajoutées au PP pour dégrader préalablement le polymère et ainsi favoriser l’action des micro-organismes sur les chaines plus courtes. Les hydroxydes doubles lamellaires induisent bien une dégradation mais ce n’est pas assez pour permettre l’assimilation du polymère. Finalement, ce travail aborde la biodégradation de différents polymères dans le but de comprendre ce phénomène et d’améliorer la biodégradation des polymères étudiés. / Nowadays, to minimize our waste production, many studies are focused on environmentally friendly polymers. Degradation in compost is a complex phenomenon with unclear mechanism depending on temperature, micro-organism population, humidity and polymer it-self. In a first hand, these different parameter effects on poly(lactic acid)(PLA) biodegradation are studied with melt viscoelasticity to assess the molecular evolution of the materials during biodegradation. In a second hand, PLA is mixed with a polymer more biodegradable, poly(butylene succinate), to improve PLA biodegradation. After the biodegradation of a compostable polymer, a non biodegradable polymer is studied: polypropylene(PP). To achieve the initiation of its bio-assimilation, fillers are added to promote its degradation and therefore improve its assimilation by micro-organisms. Layered double hydroxides induce degradation but not enough to observe polymer biodegradation.

Biodégradation

Rhéologie

Acide polylactique

Poly(butylène succinate)

Polypropylène

Hydroxyde double lamellaire

Biodegradation

Rheology

Poly(lactic acid)

Poly(butylen succinate)

Polypropylene

Double layered hydroxide

Study of Polymer/Silver-Zeolite Composites For Anti-Microbial Applications / Etude de composites polymères et particules d’argent insérées dans des matrices zéolites en vue d’applications antimicrobiennes

Taranamai, Phruedsaporn

04 July 2019

L’objectif de ce travail est de préparer des polymères composites antimicrobiens, utilisant de l’acide polylactique (PLA) et/ou du caoutchouc naturel époxydé et incluant des particules d’argent insérées dans des matrices zéolites (AgZ), agissant en tant que composé actif. Un des verrous contrôlant l’activité antibactérienne des matériaux synthétisés est relié à l’étude de l’absorption de l’eau. En effet la mise en œuvre de composites PLA antibactériens rencontre le problème du caractère faiblement hydrophile de PLA, induisant une faible efficacité antimicrobienne. Ainsi afin d’amplifier l’activité antibactérienne des composites AgZ/PLA, une solution prometteuse consiste à introduire un second polymère hautement polaire et flexible. Le caoutchouc naturel époxydé a été ainsi sélectionné pour être associé au composite AgZ/PLA et le taux d’absorption d’eau mesuré témoigne d’un accroissement notable. La morphologie et la distribution des particules AgZ a été étudiée. L’accroissement remarquable du caractère antibactérien des composites ENR/AgZ/PLA a été démontré ; ainsi des tests menés sur S. aureus montrent que la croissance bactérienne a été inhibée à hauteur de 98-99%. L’étude a aussi été menée en fonction de la proportion de caoutchouc et des particules AgZ. De plus les composites ENR/AgZ/PLA possèdent une plus haute résistance à l’impact comparés à l’emploi de PLA pur, suggérant ainsi que ces nouveaux composites pourront constituer des matériaux de choix pour des applications à la fois antibactériennes et nécessitant une résistance à l’impact forte. / The aim of this work is to prepare antibacterial polymers composites, involving especially poly(lactic acid) (PLA) and epoxidized natural rubber (ENR) in the presence of silver-substituted zeolites (AgZ) as an active ingredient. Herein, the key to control the antibacterial activity of the composites which is the water absorption characteristic was thoroughly studied. In general, the fabrication of antibacterial PLA composites encounters with the problem relating to the poor hydrophilicity of PLA which is the cause of antibacterial ineffectiveness. To enhance the antibacterial activity of the composites, blending with the second polymer having high polarity and flexibility is a promising way to produce the antibacterial AgZ/PLA composite. Herein, epoxidized natural rubber (ENR) was selected to blend with AgZ/PLA composites and the increase in the water absorption percentage could be observed. The morphology as well as the AgZ distribution in the composites were also investigated. The remarkable enhancement of antibacterial activity of ENR/AgZ/PLA composites was observed because more than 98-99% inhibition of S. aureus growth was found. Furthermore, the effects of rubber content and amount of AgZ on the antibacterial activity of the composites were investigated. Moreover, the ENR/AgZ/PLA composites possessed the higher impact resistance compared to neat PLA, suggesting that the improved composites might be a choice in applications at which both antibacterial activity and impact resistance property are of great importance.

Acide polylactique (PLA)

Caoutchouc Naturel Epoxyde

Ag/Zeolites

Activité antibactérienne

Poly(lactic acid)

Epoxidized Natural Rubber

Silver-Substituted Zeolites

Antibacterial Activity

620.118

Préparation et modification de composites thermoplastiques/tannins par extrusion réactive / Preparation and modification of thermoplastic/tannins composites via reactive extrusion

Liao, Jingjing

16 July 2019

Les tanins condensés sont largement répandus et très abondants dans la nature. Au cours des dernières décennies, ces tanins ont été abondamment utilisés pour la production de formulations thermodurcissables (par exemple, les adhésifs pour le collage du bois, les matériaux en mousse) en raison de leur réactivité chimique. Cependant, ils présentent également un grand potentiel en tant que composants pour la conception de matériaux polymères innovants en raison de leurs propriétés physico-chimiques (p. ex. antioxydantes, antimicrobiennes et stabilisantes). Afin d’étendre les domaines d’utilisation des tanins aux matériaux polymères, le principal verrou scientifique et technique réside dans leur incompatibilité avec les polymères hydrophobes. À cette fin, trois voies de modification ont été mises au point pour améliorer la compatibilité des tanins avec les matrices PP ou PLA. Dans la première partie, les PP/ tanins ont été modifiés avec du glyoxal par vulcanisation dynamique. Après extrusion réactive, les tanins vulcanisés présentent une meilleure compatibilité avec la matrice PP et des propriétés anti-UV. La deuxième approche consiste en une modification par estérification à l'aide d'anhydride acétique. Avec cette méthode, des teneurs élevées en AT ont pu être incorporées au PLA, jusqu'à 30 % en poids et jusqu'à 20 % sans diminution notable des propriétés mécaniques ni impact sur la morphologie de surface. Ces composites PLA/AT sont imprimables en impression 3D par dépôt de matière fondue. Dans la troisième partie, une compatibilisation réactive a été réalisée avec succès pour améliorer l'adhésion interfaciale entre PLA et les tanins condensés en utilisant du 3-aminopropytriéthoxysilane, du diisocyanate de méthylène diphényle et du peroxyde de dicumyle (DCP). / Condensed tannins are widely distributed and highly abundant in nature. In the past decades, such tannins have played an important role in thermosetting systems (e.g. adhesives for wood bonding, foam material) because of their chemical reactivity. However, they also exhibit great potential as a component of polymeric materials because of their physicochemical properties (e.g. antioxidant, antimicrobial and stabilizing properties), which are promising for material preparation. In order to transform tannins from traditional application to a broaden application in polymeric materials, the main challenge facing tannins are their incompatibility with hydrophobic polymer. For this purpose, three modification pathways were developed to improve the compatibility of tannins with PP or PLA matrix. In the first part, PP/ tannins were modified with hexamine or glyoxal via dynamic vulcanization technique. After vulcanized extrusion, vulcanized tannins present better compatibility and UV protective performance in PP matrix. The second approach is CTs modified with acetic anhydride. With this method, up to 30 wt% acetylated tannin (AT) can be well incorporated with PLA while PLA containing up to 20 wt% AT did not deteriorate the mechanical property and surface morphology. This PLA/AT composites are printable via fused deposition modeling process. In the third part, the efficient reactive compatibilization have been successful used to improve the interfacial adhesion between PLA and CTs by using 3-aminopropytriethoxysilane, methylene diphenyl diisocyanate, and dicumyl peroxide (DCP).

Polypropylène

Poly(acide lactique)

Tannin condensé

Extrusion

Modélisation du dépôt fondu

Compatibilité réactive

Polypropylene

Poly (lactic acid)

Condensed tannin

Extrusion

Fused deposition modeling

Reactive compatibilization

668.422

668.413

Experimental Study of Structure and Barrier Properties of Biodegradable Nanocomposites

Bhatia, Amita, abhatia78@yahoo.com

January 2008

As nanocomposites provide considerable improvements in material properties, scientists and engineers are focussing on biodegradable nanocomposites having superior material properties as well as degradability. This thesis has investigated the properties of biodegradable nanocomposites of the aliphatic thermoplastic polyester, poly (lactide acid) (PLA) and the synthetic biodegradable polyester, poly (butylene succinate) (PBS). To enhance the properties of this blend, nanometer-sized clay particles, have been added to produce tertiary nanocomposite. High aspect ratio and surface area of clay provide significant improvement in structural, mechanical, thermal and barrier properties in comparison to the base polymer. In this study, a series of PLA/PBS/layered silicate nanocomposites were produced by using a simple twin-screw extruder. PLA/PBS/Cloisite 30BX nanocomposites were prepared containing 1, 3, 5, 7 and 10 wt% of C30BX clay, while PLA and PBS polymers compositions were fixed at a ratio of 80 to 20. This study also included the validation of a gas barrier model for these biodegradable nanocomposites. WAXD indicated an exfoliated structure for nanocomposites having 1 and 3 wt% of clay, while predominantly development of intercalated structures was noticed for nanocomposites higher than 5 wt% of clay. However, TEM images confirmed a mixed morphology of intercalated and exfoliated structure for nanocomposite having 1 wt% of clay, while some clusters or agglomerated tactoids were detected for nanocomposites having more than 3 wt% of clay contents. The percolation threshold region for these nanocomposites lied between 3-5 wt% of clay loadings. Liquid-like behaviour of PLA/PBS blends gradually changed to solid-like behaviour with the increase in concentration of clay. Shear viscosity for the nanocomposites decreased as shear rate increased, exhibiting shear thinning non-Newtonian behaviour. Tensile strength and Young's modulus initially increased for nanocomposites of up to 3 wt% of clay but then decreased with the introduction of more clay. At high clay content (more than 3 wt%), clay particles tend to aggregate which causes microcracks at the interface of clay-polymer by lowering the polymer-clay interaction. Percentage elongation at break did not show any improvement with the addition of clay. PLA/PBS blends were considered as immiscible with each other as two separate glass transition and melting temperatures were observed in modulated differential scanning calorimetry (MDSC) thermograms. MDSC showed that crystallinity of the nanocomposites was not much affected by the addition of clay and hence some compatibilizer is required. Thermogravimetric analysis showed that the nanocomposite containing 3 wt% of clay demonstrated highest thermal stability compared to other nanocomposites. Decrease in thermal stability was noticed above 3 wt% clay; however the initial degradation temperature of nanocomposites with 5, 7 and 10 wt% of clay was higher than that of PLA/PBS blend alone. Gas barrier property measurements were undertaken to investigate the transmission of oxygen gas and water vapours. Oxygen barrier properties showed significant improvement with these nanocomposites, while that for water vapour modest improvement was observed. By comparing the relative permeabilities obtained from the experiments and the model, it was concluded that PLA/PBS/clay nanocomposites validated the Bharadwaj model for up to 3 wt% of clay concentration.

Biodegradable nanocomposites

poly (lactic acid)

poly (butylene succinate)

organoclay

morphological

rheological

thermal properties

mechanical properties

gas barrier properties

gas barrier model

Constitutive modeling for biodegradable polymers for application in endovascular stents

da Silva Soares, Joao Filipe

10 October 2008

Percutaneous transluminal balloon angioplasty followed by drug-eluting stent implantation has been of great benefit in coronary applications, whereas in peripheral applications, success rates remain low. Analysis of healing patterns in successful deployments shows that six months after implantation the artery has reorganized itself to accommodate the increase in caliber and there is no purpose for the stent to remain, potentially provoking inflammation and foreign body reaction. Thus, a fully biodegradable polymeric stent that fulfills the mission and steps away is of great benefit. Biodegradable polymers have a widespread usage in the biomedical field, such as sutures, scaffolds and implants. Degradation refers to bond scission process that breaks polymeric chains down to oligomers and monomers. Extensive degradation leads to erosion, which is the process of mass loss from the polymer bulk. The prevailing mechanism of biodegradation of aliphatic polyesters (the main class of biodegradable polymers used in biomedical applications) is random scission by passive hydrolysis and results in molecular weight reduction and softening. In order to understand the applicability and efficacy of biodegradable polymers, a two pronged approach involving experiments and theory is necessary. A constitutive model involving degradation and its impact on mechanical properties was developed through an extension of a material which response depends on the history of the motion and on a scalar parameter reflecting the local extent of degradation and depreciates the mechanical properties. A rate equation describing the chain scission process confers characteristics of stress relaxation, creep and hysteresis to the material, arising due to the entropy-producing nature of degradation and markedly different from their viscoelastic counterparts. Several initial and boundary value problems such as inflation and extension of cylinders were solved and the impacts of the constitutive model analyzed. In vitro degradation of poly(L-lactic acid) fibers under tensile load was performed and degradation and reduction in mechanical properties was dependent on the mechanical environment. Mechanical testing of degraded fibers allowed the proper choice of constitutive model and its evolution. Analysis of real stent geometries was made possible with the constitutive model integration into finite element setting and stent deformation patterns in response to pressurization changed dramatically as degradation proceeded.

constitutive modeling

degradation

degradable polymer

stent

cardiovascular devices

hydrolysis

damage

poly(lactic acid)

elasticity

viscoelasticy

internal variable materials

nonlinear materials

scission

continuum mechanics

Materials and microfabrication approaches for completely biodegradable wireless micromachined sensors

Luo, Mengdi

12 January 2015

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

MEMS

Biodegradable sensors

Wireless passive sensors

RF pressure sensors

Galvanic corrosion

Poly(lactic acid)

Poly(lactic-co-glycolic acid)

In vitro degradation

S?ntese e caracteriza??o do poli(?cido l?ctico) para potencial uso em sistemas de libera??o controlada de f?rmacos

Carvalho, Ana Cla?dia Medeiros de

11 November 2013

Made available in DSpace on 2014-12-17T14:07:18Z (GMT). No. of bitstreams: 1 AnaCMC_DISSERT.pdf: 3568281 bytes, checksum: 78b0d72ff4bc1b9774bb0c806de32258 (MD5) Previous issue date: 2013-11-11 / Conselho Nacional de Desenvolvimento Cient?fico e Tecnol?gico / With the advances in medicine, life expectancy of the world population has grown considerably in recent decades. Studies have been performed in order to maintain the quality of life through the development of new drugs and new surgical procedures. Biomaterials is an example of the researches to improve quality of life, and its use goes from the reconstruction of tissues and organs affected by diseases or other types of failure, to use in drug delivery system able to prolong the drug in the body and increase its bioavailability. Biopolymers are a class of biomaterials widely targeted by researchers since they have ideal properties for biomedical applications, such as high biocompatibility and biodegradability. Poly (lactic acid) (PLA) is a biopolymer used as a biomaterial and its monomer, lactic acid, is eliminated by the Krebs Cycle (citric acid cycle). It is possible to synthesize PLA through various synthesis routes, however, the direct polycondensation is cheaper due the use of few steps of polymerization. In this work we used experimental design (DOE) to produce PLAs with different molecular weight from the direct polycondensation of lactic acid, with characteristics suitable for use in drug delivery system (DDS). Through the experimental design it was noted that the time of esterification, in the direct polycondensation, is the most important stage to obtain a higher molecular weight. The Fourier Transform Infrared (FTIR) spectrograms obtained were equivalent to the PLAs available in the literature. Results of Differential Scanning Calorimetry (DSC) showed that all PLAs produced are semicrystalline with glass transition temperatures (Tgs) ranging between 36 - 48 ?C, and melting temperatures (Tm) ranging from 117 to 130 ?C. The PLAs molecular weight characterized from Size Exclusion Chromatography (SEC), varied from 1000 to 11,000 g/mol. PLAs obtained showed a fibrous morphology characterized by Scanning Electron Microscopy (SEM) / Com os avan?os na medicina, a expectativa de vida da popula??o mundial vem crescendo consideravelmente nas ?ltimas d?cadas. Pesquisas v?m sendo realizadas visando manter a qualidade de vida da popula??o atrav?s do desenvolvimento de novas drogas e novos procedimentos cir?rgicos. Os biomateriais s?o estudados atualmente, e sua utiliza??o vai desde a reconstru??o de tecidos e ?rg?os afetados por patologias ou outros tipos de falha, ? utiliza??o em sistema de libera??o de f?rmacos capazes de prolongar o tempo do medicamento no organismo e aumentar a sua biodisponibilidade. Os biopol?meros consistem em uma classe de biomateriais muito visada pelos pesquisadores, uma vez que apresentam propriedades ideais para tal aplica??o, como alta biocompatibilidade e biodegradabilidade. O Poli(?cido l?ctico) (PLA) ? um biopol?mero usado como biomaterial, e seu mon?mero, o ?cido l?ctico, ? eliminado pelo ciclo do ?cido c?trico (ciclo de Krebs). ? poss?vel sintetizar o PLA atrav?s de v?rias rotas de s?ntese, no entanto, a policondensa??o direta ? a rota mais barata devido ao uso de poucas etapas de polimeriza??o. Neste trabalho foi utilizada a ferramenta de planejamento fatorial para produzir PLAs com diferentes massas molares, a partir da policondensa??o direta do ?cido l?ctico, com caracter?sticas adequadas para a utiliza??o em sistema de libera??o de f?rmacos (SLFs). Por meio do planejamento observou-se que o tempo de esterifica??o ? o est?gio mais importante na obten??o de uma maior massa molar na rota de policondensa??o. Os Infravermelhos por Transformada de Fourier (FTIR) obtidos apresentaram espectrogramas equivalentes ao de PLAs dispon?veis na literatura. Resultados de Calorimetria Explorat?ria Diferencial (DSC) mostraram que todos os PLAs produzidos s?o semicristalinos, com temperaturas de transi??o v?treas (Tgs) variando entre 36 48?C e temperaturas de fus?o (Tm) variando entre 117 130?C. As massas molares, caracterizadas a partir de Cromatografia por Exclus?o de Tamanho (SEC), variaram entre 1000 11000 g/mol. Os PLAs obtidos apresentaram uma morfologia fibrosa caracterizada por meio de Microscopia Eletr?nica de Varredura (MEV)