Global ETD Search

331	Geometric induction of bone formation Chidarikire, Thato Nelly 16 February 2007 (has links) Student Number : 9501020M - M Sc dissertation - School of Clinical Medicine - Faculty of Health Sciences / An exciting and novel concept of tissue engineering and morphogenesis is the generation of bone by the implantation of smart biomaterials that in their own right can induce a desired and specific morphogenetic response from the host tissues without the addition of exogenously applied bone morphogenetic and osteogenic proteins. tissue engineering morphogenesis generation of bone smart biomaterials osteogenic proteins
332	Estudo da desacetilação da quitosana e obtenção de suas nanopartículas para aplicação em Engenharia de tecidos. / Study of the deacetylation of chitosan and the obtaining of its nanoparticles for application in Tissue Engineering. Souza, Juliana Rodrigues de 07 August 2017 (has links) Estima-se, que, no Brasil, ocorram cerca de um milhão de vítimas de queimaduras por ano, e mesmo com a dinâmica de inovações na área da saúde, a reparação deste tipo de lesão tecidual, permanece um grande desafio. Os queimados tendem a contrair infecções sistêmicas, as quais poderão levar a óbito, se não houver o tratamento adequado ao paciente. Desta forma, são necessários cuidados extremos nas etapas que envolvem este complexo reparo tissular. Diante das dificuldades na substituição ou regeneração de órgãos ou tecidos lesionados, surgiu um campo interdisciplinar chamado de engenharia de tecidos, com foco no estudo para o desenvolvimento de suportes tridimensionais, constituídos de materiais sintéticos ou naturais, onde são cultivadas células do próprio paciente, para posteriormente serem reinseridas reparando tecidos ou substituindo órgãos por inteiro. A quitosana é um dos biopolímeros mais utilizados hoje na área de engenharia de tecidos, devido a sua capacidade de agir de forma significativa nas três fases que envolvem a cicatrização de queimaduras, sendo elas: a fase inflamatória, a fase proliferativa e a fase reparadora, e por sua alta ação bacteriostática e fungistática. Diante das propriedades já existentes da quitosana, o objetivo desta pesquisa foi o estudo para intensificá-las, através do aumento do seu grau de desacetilação e modificando-a para uma escala nanométrica aumentando assim sua área superficial. Para isso, a quitosana foi submetida a meio altamente alcalino com variação de temperatura e variação do tempo de reação, utilizando a ferramenta estatística fatorial completo 23. Após a obtenção das amostras desacetiladas, foi verificado, através dos espectros obtidos por espectroscopia na região do infravermelho, que os maiores valores de grau de desacetilação ocorreram utilizando os níveis máximos em todos os fatores envolvidos na reação. Para analisar a cinética da reação e confirmar as informações obtidas do fatorial 23, foi feito um novo planejamento fatorial 22, fixando o tempo de seis horas de reação, e no decorrer deste tempo foram retiradas onze alíquotas, para análise de seus graus de desacetilação (GD). O padrão de resultados dos experimentos permitiu a aplicação de um modelo matemático que representou a realidade do que ocorreu durante a reação, sendo este o modelo do núcleo não reagido. Posteriormente, a quitosana com alto grau de desacetilação foi submetida ao método de ultrassom e pelas análises do diâmetro das partículas, potencial zeta e índice de polidispersão, foi possível verificar que a quitosana após ser submetida ao ultrassom e no pH adequado, foi possível atingir partículas em escala nanométrica. / It is estimated that in Brazil about one million burn victims occur per year, and even with the dynamics of innovations in the health area, the repair of this type of tissue injury, remains a great challenge. Burns tend to contract systemic infections, which can lead to death if the patient is not adequately treated. In this way, extreme care is required in the steps involved in this complex tissue repair. Faced with difficulties in the replacement or regeneration of injured organs or tissues, an interdisciplinary field called tissue engineering has emerged, focusing on the study for the development of three-dimensional supports, consisting of synthetic or natural materials, where the patient\'s own cells are cultured, subsequently reinserted by repairing tissues or replacing whole organs. Chitosan is one of the most widely used biopolymers nowadays in the field of tissue engineering, due to its capacity to act in a significant way in the three phases that involve the healing of burns, namely: inflammatory phase, proliferative phase and repair phase, and for its high bacteriostatic and fungiostatic action. In view of the existing properties of chitosan, the objective of this research was to intensify them by increasing its degree of deacetylation and modifying it to a gauge scale, thus increasing its surface area. For this, chitosan was submitted to a highly alkaline medium with temperature variation and reaction time variation, using the complete factorial statistical tool 23. After obtaining the deacetylated samples, it was verified by spectroscopy in the infrared region, that the highest values of deacetylation degree occurred after using the maximum levels in all factors involved in the reaction. In order to analyze the kinetics of the reaction and to confirm the information obtained from factorial 23, a new 22 factorial design was made, fixing the time of six hours of reaction, during which eleven aliquots were taken for analysis of their degree of desacetylation (GD). The pattern of results of the experiments allowed the application of a mathematical model that represented the reality of what occurred during the reaction, being this the model of the shrinking core model. Subsequently, the chitosan with a high degree of deacetylation was subjected to the ultrasound method and the analysis of particle diameter, zeta potential and polydispersion index allowed to verify that chitosan after being submitted to ultrasound at the appropriate pH achieved particles in nanometer scale. Burns Chitosan Engenharia tecidual nanoparticles. Nanopartículas Queimaduras Quitosana Tissue engineering
333	Desenvolvimento de membranas acelulares de colágeno derivadas de pericárdio porcino para uso em engenharia de tecido / Development of acellular collagen membranes derived from porcine pericardium with potential application in tissue engineering Rodrigues, Fabiana Tessari 10 June 2011 (has links) A utilização e o desenvolvimento de biomateriais para a regeneração tecidual são de grande importância, principalmente para a área médica e odontológica. Matrizes de colágeno derivadas de tecidos de origem animal são utilizadas devido o colágeno apresentar características como biodegradabilidade e biocompatibilidade. Essas matrizes podem ser obtidas a partir de várias fontes, sendo uma delas o pericárdio porcino, que apresenta vantagens como grande disponibilidade, baixo custo, fácil obtenção e possibilidade de sofrer modificações químicas. Além disso, tecidos de origem suína são muito similares aos tecidos humanos, podendo ser utilizados para a produção de biomateriais para a regeneração de tecido mole. Este trabalho teve como objetivo a preparação de membranas acelulares derivadas de pericárdio porcino por hidrólise alcalina em diferentes tempos, para posterior utilização em engenharia de tecido. As membranas de colágeno foram obtidas por hidrólise alcalina de pericárdio porcino durante 4, 8, 12 e 24 h e caracterizadas por análise histológica, microscopia eletrônica de varredura (MEV), avaliação da citoxicidade in vitro, estabilidade biológica in vitro (colagenase), titulação potenciométrica, porcentagem de absorção de água, calorimetria exploratória diferencial (DSC), termogravimetria (TG), análise térmica dinâmico-mecânica (DMTA) e ensaios de tração. A análise histológica mostrou que após 4h de hidrólise as células foram removidas das membranas. A avaliação da citotoxicidade in vitro mostrou que as membranas preparadas neste trabalho não são citotóxicas. Os ensaios de estabilidade biológica in vitro por colagenase mostraram que as membranas hidrolisadas degradaram mais rapidamente que a não hidrolisada e, quando comparadas com matrizes derivadas de pericárdio bovino, as derivadas de pericárdio porcino foram mais resistentes à degradação por colagenase. A titulação potenciométrica possibilitou determinar o número de grupos carboxílicos das membranas e o incremento desses grupos por molécula de colágeno. Os resultados mostraram que houve um aumento no número de grupos carboxílicos tituláveis nas membranas hidrolisadas e, consequentemente, houve um aumento do número de cargas negativas incorporadas na molécula de colágeno. As membranas hidrolisadas apresentaram uma maior absorção de água, uma diminuição das temperaturas de desnaturaçãoe e menor estabilidade térmica em função do aumento do tempo de hidrólise. Os ensaios de tração mostraram que após a hidrólise alcalina as membranas apresentaram maiores valores de resistência à tração e que a deformação é dependente do tempo de hidrólise alcalina. Esses resultados mostraram que a preparação de membranas de colágeno derivadas de pericárdio porcino com diferentes tempos de hidrólise alcalina é um procedimento viável para ser utilizado na produção de biomateriais para engenharia de tecido. / The use and development of biomaterials for tissue regeneration are of great importance, especially for medical and dental care. Collagen matrices derived from animal tissues are widely used because collagen has characteristics such as biodegradability and biocompatibility. These matrices can be obtained from various sources, such as porcine pericardium, which is a tissue that can be used due its low cost, wide availability and because it can be chemically modified. Besides, porcine tissues are very similar to human tissue and can be used to produce biomaterials for soft tissue regeneration. The aim of this study was the preparation and characterization acellular membranes by alkaline hydrolysis of porcine pericardium. Membranes were characterized by histological analysis, scanning electron microscopy (SEM), in vitro cytotoxicity evaluation, in vitro biological stability (collagenase), potentiometric titration, water absorption percentage, differential scanning calorimetry (DSC), thermogravimetry (TG), dynamic mechanical thermal analysis (DMTA) and tensile tests. Histological analysis showed that after 4h of hydrolysis, cells were totally removed from matrices. In vitro cytotoxicity showed that all matrices prepared in this work are not cytotoxic. In vitro biological stability tests (collagenase) showed that the hydrolyzed membranes degraded more quickly than the non hydrolized matrix and more resistant to collagenase degradation when compared to matrices derived from bovine pericardium. The potentiometric titration allowed the determination carboxylic groups and the increase of these groups per collagen molecule. Hydrolyzed matrices had an increase in water absorption, a decrease in denaturation temperature and a small decrease in thermal stability with the increase of hydrolysis time. Tensile tests showed that after alkaline hydrolysis matrices showed higher tensile strength and the deformation was independent of the time of alkaline hydrolysis. These results showed that the preparation of collagen biological matrices derived from porcine pericardium with different times of alkaline hydrolysis is a viable procedure to be subsequently used in the production of biomaterials for tissue engineering. Colágeno Collagen Engenharia de tecido Pericárdio porcino Porcine pericardium Tissue engineering
334	Toward Rational Design of Functional Materials for Biological Applications Charng-yu Lin (5929970) 10 June 2019 (has links) Cellular activities are composite responses to stimuli from the surroundings. Materials for biological applications, therefore, must be designed with care such that undesired interactions between cells and the materials will not be elicited while cellular responses that are beneficial to the dedicated applications are promoted. Efforts have been made to construct such materials based on both synthetic polymers and natural polymers including poly(ethylene glycol) (PEG) and proteins. In particular, recombinant proteins have drawn great interest for their similar biocompatibility to natural proteins and the uniformity of material properties that is found in manufacturing of synthetic polymers. Recombinant proteins are designed at the DNA level, which allows precise control over the translated protein sequence. By assembling encoded DNA sequences of amino acids with desired functional groups or protein domains conferring desired functionalities, a recombinant protein-based material can be tailored. In this dissertation, works toward developing functional biomaterials based on both synthetic polymers and recombinant proteins are presented.<br>The first part of this thesis encompasses the development of a new thiol-based crosslinking approach to achieve independent control over degradability and mechanical properties of a hydrogel system. Thiol chemistry was chosen as the focus here because it can easily be incorporated into recombinant protein designs by inserting cysteine residues. In addition, the low frequency of cysteine residues in natural proteins can reduce unwanted reactions between the hydrogel material and encapsulated biomolecules or cells. We utilized divinyl sulfone (DVS) to form thioether crosslinking through thiol-ene addition and ferric ethylenediaminetetraacetic acid (ferric EDTA) to make disulfide crosslinking via thiol oxidation. By controlling the ratio between the non-reducible thioether bonds to reducible disulfide bonds, hydrogels with similar mechanical properties can be made with different degradability in reducing conditions. Accelerated degradation and increased release of encapsulated dextran was observed in response to an extracellular reducing condition. Good viability of encapsulated fibroblasts also suggested high cytocompatibility of the crosslinking approach. This work demonstrated the potential of thiol crosslinking by DVS and ferric EDTA for making redox-responsive drug delivery vehicles and tissue engineering scaffolds.<br>In the second part, we developed protein adhesives using thiol- or catechol-based adhesion. Every year more than 310 million surgeries are performed around the world, and more than 50% of these surgeries used sutures or staples for wound closure. Surgical sealants or adhesive can be applied together with sutures and staples to mitigate the risk of infection. Protein-based adhesives could have better biocompatibility than synthetic polymer-based adhesives and have the potential of providing biochemical cues for cellular responses. Many adhesive proteins have been found in nature. Among them, mussel adhesive proteins have been actively studied for their outstanding underwater adhesion. The capability of being able to cure in a wet environment is critical for an ideal surgical sealant and adhesive. Mussels uses both thiols and a catechol, 3, 4-dihydroxyphenylalanine (DOPA), to achieve underwater adhesion. Inspired by mussel adhesive proteins and modular recombinant design, we developed two proteins harboring thiol or DOPA groups with highly similar amino acid sequences. The adhesion performance, including curing kinetics, adhesion strength, and cytocompatibility, were compared between the two proteins. The similarity in the protein sequences allows us to focus on the performance difference between thiol- and DOPA-based adhesion. We also showed that a synergistic increase in the adhesion strength can be achieved when the two proteins are combined. This increase indicates a cross-reaction between thiol and DOPA groups. Our results provide insights into selecting the chemistry for designing adhesives based on the needs of the applications.<br>In the last part, we studied the lower critical solution temperature (LCST) behavior of elastin-like polypeptides (ELPs) with a series of ELPs with rationally designed charge distributions and chain lengths. The LCST behavior of ELPs are controlled by multiple factors including the amino acid composition, ELP chain length, protein concentration, salt identity, salt concentration, and pH of the solution. Fusion of other non-ELP recombinant protein domains to ELPs have also been shown to influence the LCST behavior of the fusion ELP protein. Inspired by this effect, we explored the use of short non-ELP sequences as a new way to tailor the LCST behavior of ELP-based proteins. We designed the non-ELP and the ELP sequences with different pH-dependent charge states and showed that pH sensitivity was introduced to the LCST behavior by electrostatic and hydrophobic interactions between the non-ELP and ELP sequences. The electrostatic interactions can be shielded by the ionic strength in the protein solution. The pH sensitivity was introduced by the non-ELP sequences, and this sensitivity decreased when the relative length of the ELP domain increased. We also found that the hydrophobicity of the non-ELP sequences changes the interactions between the proteins and Hofmeister ions in solution. Our results demonstrated the potential of using non-ELP sequences as a new factor in controlling the LCST behavior of ELP proteins.<br><br> Chemical Engineering Design tissue engineering technologies Recombinant proteins
335	Produção e caracterização de biomateriais acelulares bioativos obtidos a partir da decelularização de placentas / Production and characterization of bioactive biomaterials obtained from decellularized placentas Leonel, Luciano César Pereira Campos 11 February 2016 (has links) A bioengenharia de tecidos baseia-se no uso de moléculas bioativas, células-tronco e biomateriais para reparação de tecidos e/ou órgãos. Biomateriais podem ser classificados de acordo com sua origem em sintéticos ou biológicos. Biomateriais biológicos podem ser produzidos por decelularização, que visa a remoção de células da matriz extracelular (MEC), a qual deve manter sua integridade química e física. Placentas são órgãos de grande interesse na bioengenharia de tecidos visto que são descartadas após o parto e possuem grande volume de matriz extracelular. Métodos de decelularização podem ser classificados em químicos, físicos e enzimáticos. Todos conhecidamente causam alterações na MEC, sendo que a associação deles é comumente utilizada. Este trabalho comparou diferentes protocolos e estabeleceu um método mais favorável para a decelularização de placentas caninas, visando a produção de um biomaterial para futuras aplicações clínicas. Inicialmente ambas as porções - materna e fetal - das placentas foram submetidas à 10 protocolos, que avaliaram variáveis como concentração e tempo de incubação em detergentes, diferentes gradientes de temperatura e a influência da perfusão versus imersão das soluções, na MEC remanescente. Com base na transparência do tecido e na ausência de núcleo celular em cortes histológicos, dois protocolos foram selecionados (I e II). Além dos critérios já mencionados, ambos os protocolos foram comparados quanto à quantidade de DNA remanescente na MEC decelularizada e à permanência e distribuição de algumas das proteínas da matriz. O detergente SDS foi o mais eficaz na remoção de células, embora não tenha sido suficiente para promover uma decelularização tecidual completa. O congelamento prévio das placentas requereu um maior tempo de incubação posterior das amostras nos distintos detergentes. Ambos métodos de perfusão e imersão foram eficazes na remoção das células, embora grande concentração de proteínas do citoesqueleto tenham permanecido retidas na matriz. As amostras processadas pelo protocolo I (SDS 1%, 5mM EDTA + 50mM TRIS + 0,5% antibiótico, e Triton X-100 1%) apresentaram maior preservação da organização estrutural da MEC quando comparadas àquelas processadas de acordo com o protocolo II (que diferiu do anterior pela utilização de solução contendo 0,05% tripsina ao invés de 50mM TRIS), esse último método entretanto foi o que melhor removeu as células das placentas, conforme observado em lâminas histológicas e demonstrado pela menor concentração de DNA. Tanto as porções materna quanto fetal submetidas à ambos protocolos, mantiveram as proteínas laminina, fibronectina e colágeno tipo I. O colágeno tipo III foi observado somente na porção fetal. Conclui-se que o protocolo II foi o mais eficaz no processo de decelularização de placentas caninas tendo promovido a remoção do conteúdo celular e diminuição da concentração de DNA na MEC remanescente. No entanto é necessário otimizar o tempo de incubação das placentas em soluções enzimáticas visando maior conservação do arranjo da matriz decelularizada. A análise da capacidade da MEC decelularizada por tal método para ser utilizada em bioengenharia de tecidos ainda deve ser avaliada in vitro e in vivo / Tissue engineering is based on the use of bioactive molecules, stem cells and biomaterials to repair tissues and/organs. Biomaterials can be classified according to their origin in synthetic or biological. Biological biomaterials can be produced by decellularization wich aims at removing cells from the extracellular matrix (ECM), while maintain its chemical and physical integrity. Placentas are organs of great interest in tissue engineering due to the fact that they are discarded after birth and present large amount of ECM. Decellularization methods can be classified into chemical, physical and enzymatic. All of them are known to cause changes on ECM; thus their association has been commonly used. This study compared different protocols and established a more favorable method for decellularization of canine placentas, aiming at the production of a biomaterial for clinical applications. Initially both placental portions maternal and fetal were subjected to ten different protocols that evaluated variables such as concentration and time of incubation in detergents, different temperatures and the influence of perfusion versus immersion of solutions in the remaining ECM were analysed. The analysis of tissue transparence and absence of cellular nuclei in histological slices stained with HE, led to selection of two protocols (I and II). Besides the before mentioned criteria, both protocols were compared according to the amount of DNA that remained in the ECM decelullarized and the distribution of some ECM proteins. SDS was the most effective detergent for cell removal although it was not enough to complete decellularization. The freezing of placentas led to larger periods of samples incubation in different detergents. Both perfusion and immersion methods were capable of removing cells, although large concentration of cytoskeletal proteins remained entrapped in the matrix. Samples subjected to protocol I (1% SDS, 5 mM EDTA + 50 mM TRIS + 0,5% antibiotic, and 1% Triton X-100) better preserved the structural organization of ECM when compared to those subjected to protocol II (wich differed from the first by the use of 0,05% trypsin instead of 50mM TRIS). However, protocol II optimized cell removal as observed in histological slices and decreased the DNA concentration. Both maternal and fetal portions, subjected to both protocols, retained the laminin, fibronectin and collagen type I proteins. Collagen type III was identified only in fetal portion. In conclusion, protocol II was more effective in the decellularization of canine placentas than protocol I; it removed cellular content and decrease the concentration of remaining DNA in remaining ECM. The ability of ECM decellularized by such method to be applied in tissue engineering strategies still need to be evaluated in vitro and in vivo Biomaterial Biomaterial Decellularization Decelularização Engenharia de tecidos Placenta Placenta Tissue engineering
336	Produção e caracterização de scaffolds de diferentes espessuras obtidos por eletrofiação de nanofibra polimérica e proteína. / Production and characterization of electrospun polymeric-protein nanofiber scaffolds with different thicknesses. Kimura, Vanessa Tiemi 26 September 2017 (has links) A engenharia tecidual visa repor, reparar ou ajudar a regenerar tecidos e órgãos danificados por meio da combinação de biomateriais, biomoléculas e células. Scaffolds de nanofibras biodegradáveis mimetizam a matriz extracelular natural fornecendo uma estrutura ideal para o crescimento celular. Blendas de policaprolactona (PCL) e gelatina são biodegradáveis e proporcionam uma combinação de boas propriedades mecânicas, do PCL, com a hidrofilicidade e caráter que promove a adesão celular, da gelatina. Neste contexto, o objetivo deste trabalho é avaliar a importância das diferentes espessuras de scaffolds eletrofiados em relação às suas propriedades principais. Quatro conjuntos de scaffolds de PCL/gelatina com diferentes espessuras foram produzidos sob as mesmas condições apenas aumentando o tempo de duração do processo de eletrofiação. Os resultados indicam que as espessuras aumentaram proporcionalmente ao tempo de eletrofiação, variando de 100 nm a 300 nm nos períodos de 1 a 3 horas, enquanto a densidade aparente e a porosidade mantiveram-se constantes. As micrografias das membranas revelaram fibras lisas com diâmetros maiores para os scaffolds de menor espessura, e fibras irregulares com diâmetros menores e regiões fundidas ou ligadas para os scaffolds de maior espessura. Além disso, o aumento da espessura melhorou a resistência mecânica e a molhabilidade dos scaffolds. A esterilização por peróxido de hidrogênio não modificou quimicamente a composição das membranas de PCL/gelatina, embora algumas amostras tenham se deformado. As membranas também apresentaram bons resultados de citotoxicidade, melhorando a viabilidade celular, apesar desses valores diminuírem minimamente para os scaffolds de maior espessura, provavelmente devido à maior quantidade de PCL. O teste de adesão não foi conclusivo e deverá ser repetido. / Tissue engineering aims to replace, repair, or helping regenerate damaged tissues and organs through the combination of biomaterials, biomolecules and cells. Biodegradable nanofibrous scaffolds mimic the natural extracellular matrix providing an ideal structure to cellular growth. Blends of polycaprolactone (PCL) and gelatin are biodegradable and provide a combination of good mechanical properties, from PCL, with the hydrophilicity and cell adhesion promoter character, from gelatin. The aim of this work was to evaluate the importance of the thickness of electrospun scaffolds on their key properties. Four sets of PCL/gelatin scaffolds with different thicknesses were produced under the same conditions by simply increasing the time length of electrospinning process. Results indicate that the thickness increases proportionally to the electrospinning time, varying from 100 nm to 300 nm in periods of 1 to 3 hours, while the apparent density and porosity remained constant. Micrographs from the nonwoven mats revealed smooth fibers with larger diameters in the thinner scaffold, and irregular fibers with smaller diameters and molten or bonded regions as the thickness increased. Furthermore, the increase of thickness improved mechanical resistance and wettability of the scaffolds. Plasma sterilization did not modify chemical composition of PCL/gelatin membranes, although some samples have been deformed. Membranes also presented good results for cytotoxicity, improving cell viability, despite these values decreased minimally to the thicker scaffolds, probably due to the higher amount of PCL. Adhesion test was not conclusive and might be repeat. Biomaterials Electrospinning Engenharia tecidual Materiais nanoestruturados Nanofibers Scaffold Tissue engineering
337	Interaction between vascular endothelial cells and surface textured biomaterials Qui, Lin January 2014 (has links) A promising approach to overcome thrombus and neointima formation on vascular grafts is to create a functional, quiescent monolayer of endothelial cells on the surface of implants. Surface topography of these implants is proven to enhance cell attachment and to reduce the inflammation associated with a smooth surface. Photoembossing is a relatively new, simple, environment-friendly and cost-effective technique to create surface topographies, since there is no etching step or mould needed. In this study, photopolymer films are photoembossed through contact mask photoembossing, while fibres are photoembossed through holographic lithography. Surface relief textures of ridges and grooves with various pitch sizes and heights are successfully obtained through both methods. Furthermore, we introduce this technique to fabricate, for the first time, reproducible surface textures on electrospun fibres. Human umbilical vein endothelial cells (HUVECs) are used in the study. Three different systems are investigated: non-degradable PMMA-TPETA, semi-degradable PLGA-TPETA and fully degradable PLGA-PEGDA-DTT, for different applications and therapeutic requirements. Both non-degradable PMMA-TPETA photopolymer and semi-degradable PLGA-TPETA photopolymer are shown to improve biocompatibility compared to PMMA and PLGA, respectively. Photoembossed films made from these two photopolymers show significantly improved cell attachment and proliferation, IV with a water contact angle around 70º. It is shown that the pitch size of surface topographies affects cell adhesion and migration in the wound healing assay study. Interaction between HUVECs and fibres shows that cells grow from their initial locations at fibre crossings. Focal adhesions are seen to be more aggregated on the surface textured fibres, while those on the glass cover slips are more dispersed near the edge of the cell membrane. The appearance of F-actin in the cytoplasm is also seen to be influenced by the surface topography, where changes in the diameter of the fibre and its surface texture result in F-actin rearrangement. Our study shows that a surface textured, fully degradable, gel-like photopolymer PLGA-PEGDA-DTT has great potential to be further developed for tissue engineering applications. 610.28
338	Electrically Conducting Biofibers: Approaches to Overcome the Major Challenges in the Clinical Translation of a Tissue Engineered Cardiac Patch Gershlak, Joshua R 19 June 2018 (has links) Cardiovascular disease is the leading cause of death in the United States, accounting for approximately 25% of total deaths. Myocardial infarction (MI) is an extreme case of cardiovascular disease where ischemia leads to irreversible tissue necrosis. As the heart lacks the capacity to endogenously regenerate, the infarcted region is negatively remodeled, reducing cardiac function. Current therapies are not able to regenerate cardiac function post-MI, requiring novel approaches such as tissue engineering. However, there are three major pitfalls that are currently limiting the clinical translation of a tissue engineered cardiac patch: lack of proper vascularization within the tissues; biocompatible material; and lack of electrical integration between engineered tissue and host. The research within this dissertation aimed to engineer solutions to overcome these three pitfalls. Plants and animals exploit fundamentally different approaches to transporting fluids, yet there are surprising structural similarities. To take advantage of these similarities, we looked across different kingdoms and investigated whether plants and their innate vasculature could serve as perfusable scaffolds for tissue engineering. Standard perfusion decellularization techniques were adapted and applied to spinach leaves, which were found to be fully devoid of DNA following processing. Leaf vasculature remained patent post-decellularization and supported transport of various sized microparticles. Human cells successfully seeded onto and inside the plant scaffolds. Decellularized leaves were found to be nearly void of any cytotoxic affects. Leaf biocompatibility was then investigated in vivo through subcutaneous implantation in a rat model. Leaf scaffolds were found to be biocompatible after 4 weeks of implantation. Furthermore, leaves that were pre-functionalized with an RGD-dopamine peptide were fully integrated into the host tissue within one week. This shows the leaf scaffold’s potential to be an immuno-modulatory material, depending upon the intended application. Electrically conducting biofibers were engineered through the combination of fibrin microthreads and engineered conductive HEK293 cells. Biofibers could act as a modular platform to allow for electrical integration between the host tissue and any engineered cardiac patch. Biofibers directionally carried electrical current and were found capable of bridging electrical signal between two separate clusters of cardiomyocytes. In vivo investigation bridging a biofiber from the left atria to the left ventricle was accomplished in a rat model. Electrical maps demonstrated a visible accessory pathway that created a feedback electrical signal from the ventricle to the atria through the implanted biofiber. These results demonstrate electrical integration in vivo between host myocardium and the engineered biofiber.
339	Centritubing: Using Centrifugal Force to Create Self-Assembled Tubular Tissue Constructs Jones, Craig 09 January 2013 (has links) With 500,000 coronary artery bypass procedures performed each year in the United States, and only one-third of patients possessing suitable autologous grafts, there is a clinical need for tissue engineered blood vessels (TEBVs). The overall goal of this project was to develop a one- step approach to rapidly produce entirely cell- derived tubular tissue constructs without scaffold materials. To achieve this goal, we developed "centritubing"-- a system based on applying centrifugal force to suspended cells to create a tube-shaped cellular aggregate. Briefly, rat aortic smooth muscle cells were injected into cylindrical polycarbonate spinning chambers and then spun to apply centrifugal force, which pelletted the cells on the inner wall of the chamber. After three days in culture with growth medium, the cells remodeled to form tissue tubes. In previous work we have shown, in principle, that centritubing produces tubular constructs, however tissue tube production was not consistently achieved. The first objective of this study was to develop modifications to the centritubing device that would lead to consistent lumen diameter, rapid cellular aggregation into a tube construct, and an improved success rate of tube formation. The second objective was to investigate cellular parameters that contribute to tubular tissue construct formation using centritubing. Prior to changes in manufacturing of the centritubing device and culture system, the success rate of centritubing was inconsistent. After these changes, the success rate of tubular construct formation improved to 85% (11/13). Noteworthy modifications to the centritubing device included the addition of a central mandrel as a substrate for tissue contraction, development of a smoother seeding surface, and manufacture of a reusable culture chamber. The results of this study support the proof of concept for centritubing as a device for rapid production of tubular tissue constructs and provide insight for future progress using the centritubing methodology. centrifugal force tubular construct TEBV tissue engineering self-assembly
340	Assessment of Ascorbic Acid Effects on the Properties of Cell-Derived Tissue Rings Hu, Jason Z 24 June 2010 (has links) "We have developed a system to rapidly create three-dimensional tissue rings from aggregated cells. The ability to use cell-derived tissues to screen the effects of culture conditions on tissue mechanical function has not previously been reported. The first goal of this study was to evaluate the mechanical properties of cell-derived tissue rings in response to ascorbic acid, which has been shown to increase collagen content, resulting in increased mechanical strength. The second goal was to develop quantitative methods to evaluate the structure and composition of cell-derived tissue rings. Rat aortic smooth muscle cells (1.33x10^6 cells/ring) were seeded in agarose wells with 4 mm post diameters in DMEM supplemented with 10% FBS and ascorbic acid (0, 50, 150 ug/ml). After 7 days, the average thickness of the constructs reached 0.72 +/- 0.03 mm with no statistical differences between groups. Ultimate tensile strength values were higher in the ascorbic acid-treated groups compared to untreated controls. However, there was no significant difference between tissue rings treated with 50 and 150 ug/ml ascorbic acid. Biochemical analysis showed that ascorbic acid did not significantly affect total protein, collagen content or cell number. Image analysis of polarized light micrographs suggested that collagen fibril coverage increased in response to ascorbic acid treatment, although the differences between groups were insignificant. In addition to ascorbic acid treatment, we also subjected tissue rings to DTPA treatment to prolong ascorbic acid availability in culture medium, which resulted in weak and necrotic tissue rings. Reduced serum was also investigated in order to decrease cell proliferation, which resulted in decreased tissue thickness and increased mechanical strength. Overall, we successfully demonstrated that the mechanical properties of the tissue rings could be altered by ascorbic acid treatment, and developed a series of quantitative methods to measure tissue mechanics, composition and organization. The results of this study further support the potential to use the tissue ring system as a high throughput screening method for studying the functional properties of three-dimensional engineered tissues." CDM ascorbic acid tissue engineering collagen RASMCs TEBVs

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