Hidrogéis de PVP e blendas de PVP/polianidridos como potenciais curativos para feridas crônicas / PVP hydrogels and PVP/Polyanhydride blends as potential materials for chronic wounds dressings

Bonacin, Renata Fogaça

07 October 2011

Hidrogéis compreendem uma importante classe de materiais poliméricos adequados à aplicação como curativos de feridas e queimaduras. A estrutura tridimensional hidrofílica dos hidrogéis permite que estes mantenham a umidade ideal no leito das feridas, absorvam o exsudato e não causem danos ao novo tecido durante as trocas dos curativos. No caso dos hidrogéis, essas trocas podem ser menos frequentes. Além disso, curativos que auxiliem na remoção de tecidos necrosados e ainda sejam capazes de oferecer tratamentos extras que acelerem o processo de cicatrização são desejáveis. Este trabalho apresenta a produção de materiais à base de hidrogel capazes de auxiliar neste processo de diferentes maneiras. Primeiramente, são apresentados hidrogéis formados a partir de nanofibras de poli(N-vinil-2-pirrolidona) (PVP) produzidas por eletrofiação, seguido da reticulação através da utilização de radiação UV-C ou reação de Fenton. A utilização da eletrofiação como técnica auxiliar na formação dos hidrogéis permitiu o controle da porosidade através da formação de fibras de diferentes diâmetros. A evidência de tal propriedade foi constatada através da produção de materiais que apresentam diferentes perfis de liberação da proteína modelo albumina de soro bovino (BSA). O hidrogel de PVP nanoestruturado foi capaz de liberar e manter a atividade da colagenase, uma importante enzima aplicada no tratamento de feridas via desbridamento enzimático, durante as 48 horas em que foi avaliado. Além disso, hidrogéis bactericidas nanoestruturados foram produzidos a partir de nanocompósitos de PVP e nanopartículas de prata (AgNP) produzidos por eletrofiação. Esses hidrogéis apresentaram propriedades térmicas semelhantes aos hidrogéis sem AgNP, diminuindo, contudo, a sua capacidade de intumescimento. Esses hidrogéis mostraram-se ativos contra bactérias gram-positivas e gram-negativas a partir de 100 ppm de AgNPs. Adicionalmente, foi estudada a formação de um hidrogel modelo composto PVP/AgNP/Imidazol, almejando-se a produção de um material bactericida-fungicida a base de hidrogel. Este hidrogel apresentou atividade conta três espécies de Candida a partir de 500 ppm de imidazol no material. Embora exista a formação de um complexo estável entre AgNP e Imidazol, cálculos teóricos e a constatação da atividade fungicida corroboram com o fato de que derivados imidazólicos podem ser liberados a partir deste hidrogel híbrido. A produção de hidrogéis físicos compostos por blendas de PVP/Polianidridos sintetizados a partir de derivados de hidroxicinamatos e ácido salicílico, capazes de liberar moléculas de interesse biológico quando parcialmente degradados hidroliticamente, também é descrita neste trabalho. Os resultados indicam que interações hidrofóbicas entre a PVP e os polianidridos sintetizados podem ser responsáveis pela formação dos hidrogéis físicos e pela miscibilidade das blendas produzidas. Os hidrogéis físicos de PVP/Polianidridos foram obtidos na forma de filmes por evaporação do solvente. Micro- e nanofibras também foram obtidas por eletrofiação. Desta maneira, o presente trabalho contribui com o desenvolvimento de uma geração de curativos multifuncionais aplicados no tratamento de feridas crônicas e queimaduras. / Hydrogels comprise an important class of polymeric materials that finds application as wound and burn dressings. The hydrophilic three-dimensional structure of hydrogels helps to provide the ideal humidity at the wound bed, to remove exsudates and to prevent damages to the new tissue during dressing substitution. Furthermore, these wound dressings are able to remove necrotic tissues and, therefore, capable to offer extra treatments that would benefit the healing processes. This work describes the production of hydrogel based materials that are able to act in wound healing by different ways. First, it is presented hydrogels composed of poly(N-vinyl-2-pyrrolidone) (PVP) nanofibers produced by electrospinning, followed by its crosslinking using UV-C radiation or Fenton reaction. The use of electrospinning in the hydrogel formation allowed porosity control by obtaining fibers of different diameters. This was evidenced by achieving materials that present different release profiles of the model protein bovine serum albumin (BSA). The nanostructured PVP hydrogel was capable of releasing and maintaining collagenase activity during 48 hour of evaluation. This is an important enzyme that find application in wound healing based on enzymatic debridement. Moreover, nanostructured bactericidal hydrogels were produced from PVP and silver nanoparticles (AgNP) composite through electrospinning, resulting in hydrogels with thermal properties similar to those hydrogels without AgNP, decreasing its swelling ability. These hydrogels were active against gram-positives and gram-negatives bacteria starting from 100 ppm of AgNP. In addition, the production of a model hydrogel composed by PVP/AgNP/Imidazole was investigated, aiming at a bactericidal-fungicidal hydrogel based material. This hydrogel was active against three Candida having 500 ppm of imidazole into the structure. In spite of the formation of a stable complex between AgNP and imidazole, theoretic calculations and the observed fungicidal activity corroborate with the fact that imidazoles derivatives can be released from this hybrid hydrogel. Physical hydrogels composed of PVP/Polyanhydrides blends were synthesized from hydroxycinammates derivatives and salicylic acid. These materials which were capable of releasing molecules with biological potential upon hydrolysis, are also described in this work. The results indicate that hydrophobic interactions between PVP and the synthesized polyanhydrides could be responsible for the hydrogel formation and blend miscibility as well. PVP/Polyanhydride physical hydrogels were obtained from cast films. Micro- and nanofibers were also obtained by electrospinning. Thus, the present work contributes with the development of the new generation of smart dressings for wound and burn healing.

Curativos

Electrospinning

Eletrofiação

Hidrogéis

Hydrogels

Nanopartículas de prata

Nanotechnology

Nanotecnologia

Polianidridos

Polyanhydrides

PVP

PVP

Silver nanoparticles

Wound dressings

Desenvolvimento de uma membrana nanoestruturada à base de poliacrilamida para veiculação de proteínas / Radio-synthesized polyacrylamide nanostructured hydrogels for proteins release

Ferraz, Caroline Cristina

14 June 2013

Hidrogéis são membranas formadas pela reticulação de cadeias poliméricas, empregados na área farmacêutica como produtos biomédicos. Dentre os principais polímeros selecionados para a síntese de hidrogéis, destaca-se a poliacrilamida (PAAM) devido às suas propriedades como hidrofilicidade e alto grau de intumescimento. Proteínas terapêuticas e enzimas são veiculadas em hidrogéis como carreadores de fármaco ou como dispositivos para tratamento de feridas e escaras na pele. Este trabalho teve como objetivo a síntese de uma membrana à base de PAAM favorável para veiculação de proteínas. As proteínas empregadas foram papaína e albumina de soro bovino (BSA) e as etapas do processo englobaram síntese da membrana, adição das proteínas no sistema, irradiação em condições específicas e caracterização da membrana. Ao utilizar temperaturas criogênicas na síntese e na irradiação das amostras, houve predomínio de reticulação da cadeia polimérica, fato que não ocorria em temperatura ambiente. As membranas foram obtidas com incorporação dos ativos na concentração de 0,2 a 1% (p/p), obtendo-se concentração de PAAM entre 4% a 10% (p/p), as quais receberam irradiação com raios gama provenientes de uma fonte 60Co, na dose de 25 kGy. Nas condições realizadas, as membranas não apresentaram citotoxicidade nem adesão celular, o perfil de liberação das proteínas foi adequado, a papaína manteve sua bioatividade preservada apesar do decaimento biológico e, segundo estudos de carga das moléculas, a membrana possui maior afinidade com a papaína, liberando-a mais lentamente. Desta forma, o método proposto e as membranas obtidas foram apropriados para a obtenção de um biomaterial. / The use of hydrogels for biomedical purposes has been extensively investigated. Polyacrylamide (PAAM) is widely used due to properties such as hydrophilicity and swelling degree. Pharmaceutical proteins correspond to highly active substances which may be applied for distinct purposes. This work concerns the development of radio-synthesized hydrogel for protein release using papain and bovine serum albumin (BSA) as model proteins. The polymer was solubilized (1% w/v) in water and lyophilized. The proteins were incorporated into the lyophilized polymer and the hydrogels were produced by simultaneous crosslinking and sterilization using gamma radiation at 25 kGy under frozen conditions. The produced systems were characterized in terms of swelling degree, gel fraction, crosslinking density, fluid handling capacity, determination pH at point of polymer zero charge and evaluated according to protein release, bioactivity, cytotoxicity and cell adhesion. The hydrogels developed presented different properties as a function of polymer concentration and the optimized results were found for the samples containing 4-10% polyacrylamide. Protein release was controlled by the electrostatic affinity of acrylic moieties of polymer and proteins. This selection was based on the release of the proteins during the experiment period (up to 50 hours), maintenance of enzyme activity and the nanostructure developed. The system was suitable for protein loading and release and according to the cytotoxic assay and cell adhesion it was also adequate for biomedical purposes and this method was able to generate a matrix to protein release.

adesão celular

BSA

BSA

cell adhesion

citotoxicidade

cytotoxicity

hidrogel

hydrogels

ionizing radiation

Papain

Papaína

poliacrilamida

polyacrylamide

radiação ionizante

Preparação e caracterização de nanosuspensões e hidrogéis de N,O-metoxipoli(etilenoglicol)-g-quitosana para aplicação em sistemas de liberação de fármacos antitumorais / Preparation and characterization of nanosuspensions and hydrogels of N,O-metoxy(polyethylenoglycol)-g-chitosan for applying in antitumoral drugs delivery systems

Facchinatto, William Marcondes

19 February 2016

Dados do Instituto Nacional do Câncer revelam 14,1 milhões de casos novos de câncer em 2012 em todo o mundo, e a estimativa para 2014/2015 no Brasil aponta para mais 500 mil novos casos. Assim, pesquisas voltadas à produção de nanopartículas e hidrogéis, constituídos de polímeros naturais ou sintéticos, são importantes para o desenvolvimento de sistemas destinados à liberação controlada de fármacos antitumorais. Nesse sentido, este estudo visou produzir derivados hidrofílicos de quitosanas, N,O-metoxi(polietilenoglicol)-g-quitosana, destinados ao encapsulamento e à liberação de fármacos antitumorais. As características estruturais e físico-químicas dos polímeros foram avaliadas por FTIR, RMN 1H, solubilidade em função do pH, viscosimetria, DRX e TGA. As quitosanas de partida, com diferentes graus médios de desacetilação e massas molares médias viscosimétricas, QD1x ( = 64,0 ± 1,1 % e = 495,6 ± 6,3.103 g mol-1), QD2x ( = 75,8 ± 0,8 % e = 346,8 ± 5,8.103 g mol-1) e QD3x ( = 92,3 ± 0,9 % e = 501,9 ± 5,9.103 g mol-1), produzidas pela aplicação do processo DAIUS à β-quitina, e quitosana comercial, Q ( = 94,7 ± 0,7 % e = 82,9 ± 2,0.103 g mol-1), foram avaliadas quanto aos teores de metais pesados por ICP OES e os resultados comparados aos limites permitidos pela ANVISA e Farmacopeia norte-americana. Teores significativos de metais foram detectados nas quitosanas QD1x, QD2x e QD3x (Ti e Al) e na quitosana comercial (Ni). O emprego de α-metoxipoli(etilenoglicol)-ω-carboxi possibilitou a síntese dos derivados PgQD1x, PgQD2x, PgQD3x e PgQ, que apresentaram graus médios de substituição semelhantes ( ≈ 40%). Os derivados foram hidrossolúveis em amplo intervalo de pH (1 – 11) e apresentaram viscosidades intrínsecas significativamente inferiores quando comparados às quitosanas. Foi observado que a estabilidade térmica e a cristalinidade das quitosanas são inferiores às de beta-quitina, enquanto os derivados exibiram maior cristalinidade e são termicamente mais estáveis quando comparados às quitosanas. Em geral, o aumento da razão molar –NH3+/TPP empregada na preparação das nano e microsuspensões de polímero/TPP pelo método de gelificação iônica resultou no aumento da densidade de cargas positivas nas superfícies das partículas. Entretanto, a ocorrência de numerosas cadeias de mPEG nos polímeros N,O-mPEG-g-quitosana levou à predominância das cadeias laterais hidrofílicas nas superfícies das partículas, blindando as cargas positivas, favorecendo a hidratação das partículas e o aumento dos diâmetros hidrodinâmicos médios. A influência das viscosidades intrínsecas dos polímeros e das concentrações poliméricas foi avaliada através do parâmetro de recobrimento (c[η]). Essa avaliação revelou que os diâmetros hidrodinâmicos médios das partículas são diretamente afetados por c[η] nos casos dos sistemas quitosana/TPP, enquanto as viscosidades intrínsecas dos derivados N,O-mPEG-g-quitosana são determinantes nos sistemas N,O-mPEG-g-quitosana/TPP. O estudo do comportamento reológico dos hidrogéis de N,O-mPEG-g-quitosana revelou que G’ > G’’ nos casos de PgQD3x, PgQD1x e PgQ, o que é característico de gel rígido, enquanto que no caso de PgQD2x foi observado G’’ > G’, indicando a predominância do comportamento viscoso sobre o elástico. O ponto de crossover foi observado acima de 38,2 ºC, indicando a formação de hidrogel estruturado termosensível. Assim, pesquisas futuras poderão investigar a influência das características estruturais e físico-químicas destes carreadores poliméricos, visando melhor eficiência de incorporação e liberação in vitro de fármacos antitumorais. / Data from National Institute of Cancer show an increase of 14.1 million new cases of cancer over the world in 2012, and the estimate for 2014/2015 in Brazil points to over 500,00 new cases. Thus, research focused on the production of nanoparticles and hydrogels, consisting by natural or synthetic polymers, are important for the development of systems for controlled release of antitumoral drugs. Therefore, this study aimed to produce systems based on hydrophilic derivative of chitosan, N,O-methoxy(polyethyleneglycol)-g-chitosan, for the encapsulation and release of antitumor drugs. The structural and physicochemical characteristics of the chitosan and the polymers were analyzed by FTIR, 1H NMR, solubility as function of pH, viscosimetry, XRD and TGA. The parent chitosan with different average degrees of deacetylation and viscosimetric average molecular weight, QD1x ( = 64,0 ± 1,1 % e = 495,6 ± 6,3.103 g mol-1), QD2x ( = 75,8 ± 0,8 % e = 346,8 ± 5,8.103 g mol-1) e QD3x ( = 92,3 ± 0,9 % e = 501,9 ± 5,9.103 g mol-1), produced applying the USAD to β-chitin, and the comercial chitosan, Q ( = 94,7 ± 0,7 % e = 82,9 ± 2,0.103 g mol-1) were analyzed for heavy metal content by ICP OES and the results compared to the limits allowed by ANVISA and US Pharmacopoeial. Significant levels of metals were detected in chitosan QD1x, QD2x and QD3x (Ti and Al) and commercial chitosan (Ni). The use of α-methoxypoly(ethyleneglycol)-ω-carboxy enabled the synthesis of derivatives PgQD1x, PgQD2x, PgQD3x and PgQ, which had similar average degree of substitution ( ≈ 40%). The derivatives were soluble in a broad pH range (1-11) and presented significantly lower intrinsic viscosities as compared to chitosan. It was observed that the thermal stability and crystallinity of chitosan are inferior to β-chitin, while the derivatives exhibit higher crystallinity and are more thermally stable as compared to chitosan. In general, increasing molar ratio of –NH3+/TPP in the preparation of nano- and microsuspensions of polymer/TPP by ionic gelation method, resulted in an increased positive charge density on the surfaces of the particles. However, the occurrence of a great number of chains of mPEG along the N,O-mPEG-g-chitosan chains led to the predominance of hydrophilic side chains on the surfaces of the particles, shielding the positive charges, favoring the hydration of the particles and the increasing the average hydrodynamic diameter. The influence of the intrinsic viscosities of the polymers and polymer concentrations were evaluated by the overlapping parameter (c[η]). This assessment revealed that the average hydrodynamic diameter of the particles are directly affected by c[η] in the case of chitosan/TPP systems, while the intrinsic viscosities of the derivates N,O-mPEG-g-chitosan are essential for N,O-mPEG-g-chitosan/TPP systems. The study of the rheological behavior of the hydrogels of N,O-mPEG-g-chitosan revealed that G’ > G’’ in the case of PgQD3x, PgQD1x and PGQ which is characteristic of structured gel, whereas in the case of PgQD2x it was observed G’’ > G’ indicating the predominance of the viscous behavior over the elastic. The crossover point was observed above 38.2 °C, indicating the formation of structured thermosensitive hydrogel. Thus, future research will investigate the influence of structural and physicochemical characteristics of polymeric carriers, aiming a better incorporation and release in vitro efficiency of antitumor drugs.

antitumoral drugs

fármacos antitumorais

hidrogéis

hydrogels

nanosuspensions

nanosuspensões

Hydrogels de polygalacturonate réticulés par les ions Fe2+ : impact du mode d'association local sur les mécanismes de gélification, contrôle de la structure multi-échelle et des propriétés mécaniques. / Polygalacturonate hydrogels using Fe2+ as cross-linkers : impact of the local association mode on gelation mechanisms, control of the multiscale structure and the mechanical properties.

Maire du Poset, Aline

24 September 2018

Ce travail de thèse décrit la formulation d'hydrogels de polygalacturonate (polyGal) réticulés par les cations Fe2+, ainsi que leur caractérisation expérimentale depuis les échelles moléculaires jusqu'aux échelles macroscopiques, en utilisant notamment la spectroscopie d'absorption X (EXAFS), la diffusion de neutrons aux petits angles (DNPA) ainsi que des mesures de rhéologie. Nous avons élaboré un protocole de gélification robuste permettant d'obtenir des gels cylindriques reproductibles qui présentent des gradients de concentrations contrôlés depuis leur partie basale jusqu'à leur partie apicale. Le rapport R = [Fe]/[Gal] a une valeur constante de 0,25 tout au long du gel, ce qui prouve que les cations Fe2+ s'associent avec 4 unités galacturonate. La confrontation des résultats d’EXAFS et de dynamique moléculaire a démontré que ces associations se font via le modèle ''egg-box''. Les mécanismes de réticulation qui contrôlent la structure du réseau formée par les chaînes aux échelles locales sont donc les mêmes dans l'ensemble du gel, ce qui est confirmé par les mesures de DNPA. La formation des gradients de concentration macroscopiques provient des mécanismes de diffusion des cations à travers le gel lors de sa formation. Ces gradients de concentration contrôlent les propriétés mécaniques des gels. En outre, nous avons prouvé que le mode d'association "egg-box" permettait la protection des ions Fe2+ contre l'oxydation, ce qui confère à ces hydrogels un potentiel applicatif pour soigner l'anémie car ils pourraient permettre la vectorisation du fer sous cette forme réduite biodisponible jusqu’à l’intestin.Nous avons étendu notre étude à la formulation d'hydrogels avec d'autres cations (Ca2+ et Zn2+). Ces hydrogels présentent des propriétés macroscopiques proches de celles des hydrogels Fe2+-polyGal car les mécanismes de diffusion des cations régissant la formation des gradients macroscopiques lors de la formation des gels sont similaires. Les hydrogels présentent cependant des structures locales différentes car les modes d'associations locaux varient d"un cation à l’autre. L’ensemble de ces résultats nous a permis de proposer un mécanisme généralisé permettant de décrire les mécanismes de formation d"hydrogels de polygalacturonate pour les cations divalents, et ainsi de moduler finement leur structure sur plusieurs échelles. Ces hydrogels pourraient donc être des outils de choix pour la vectorisation de molécules actives et le contrôle de leur relargage. / This pHD thesis describes the design of polygalacturonate hydrogels (polyGal) cross-linked by the Fe2+ cations, and their experimental characterization from the molecular scales up to the macroscopic scales, by combining EXAFS spectroscopy, Small Angle Neutron Scattering (SANS) and rheological measurements. We designed a robust gelling protocol that allowed to obtain reproducible cylindrical gels with controlled concentration gradients from the lower side to the upper side of the gel. The ratio [Fe]/[Gal] has a constant value all along the gel, which demonstrate that the Fe2+ cations are associated with 4 galacturonate units. The comparison of EXAFS measurements and molecular dynamics simulation has shown that these associations followed the "egg-box" model. The crosslinking mechanisms that control the structure of the network made by the chains at local scale is therefore the same throughout the whole gel, which is confirmed by SANS measurements. The formation of the macroscopic concentration gradients comes from the mechanisms that drive the cations diffusion through the gel during the gelation process. These gradients control the gels mechanical properties. Besides, we proved that the “egg-box" association enables to protect Fe2+ against oxidation, which gives to these hydrogels an applicative potential to cure anemia as they could allow to target iron under its bioavailable form up to the gut.We have extended the study to the design of hydrogels with other cations (Ca2+ et Zn2+). The macroscopic properties of these hydrogels are very close to that of the Fe2+-polyGal hydrogels because the cation diffusion that govern the formation of macroscopic gradients during the gelationg process are similar. The hydrogels have however different local structures because the cation- polyGal local association varies from one cation to another. All these results allowed us to propose a generalized mechanism that describes the polygalacturonate hydrogels formation for divalent cations, and thus to tune their structure over several scales. These hydrogels could therefore be some promising tools for the vectorization of active molecules and the control of their release.

Polygalacturonate

Fer(II)

Hydogels

Propriétés mécaniques

Mécanisme de gélification

Polysaccharide

Iron(II)

Hydrogels

Mechanical properties

Gelation mechanism

Eggbox model

660.6

Adhésion stimulable d'hydrogels

Sudre, Guillaume

18 January 2011

L'adhésion stimulable d'un hydrogel sur une surface a été étudiée de façon systématique par le jeu d'interactions spécifiques réversibles entre polymères. A cette fin, des surfaces modèles de brosses de poly(acide acrylique) (PAA) ont été obtenues par " grafting to " et leur structure, sensible au pH, a été caractérisée par réflectivité de neutrons. Parallèlement, des hydrogels neutres de poly(N,N-diméthylacrylamide) (PDMA) et de poly(acrylamide) (PAM) ont été synthétisés par polymérisation radicalaire conventionnelle ; leurs propriétés mécaniques, leur structure et leur gonflement ont été étudiés et variés au moyen de deux paramètres : le gonflement initial et le taux de réticulant. En solution aqueuse, les couples de polymères PAA et PDMA ou PAA et PAM forment des complexes inter polymères dont l'apparition dépend du pH et de la température. Les associations se produisent à pH faible dans les deux cas ; et quoique relativement similaire d'un point de vue chimique, ces couples de polymères s'associent par une séparation de phase de type UCST lorsque l'accepteur de proton est le PAM, mais par une transition de type LCST avec le PDMA. La formation de ces complexes en solution a aussi été étudiée aux interfaces entre la brosse de PAA et les hydrogels de PDMA et PAM. Une étude à l'échelle de la brosse a été menée par réflectivité de neutrons : en présence de gel, un gonflement additionnel de la brosse est observé en présence des interactions à faible pH alors que sa structure n'est pas perturbée à pH élevé. L'étude macroscopique de ces interactions aux interfaces correspond aux tests d'adhésion : un montage expérimental et des protocoles adaptés à la mesure quantitative de l'énergie d'adhésion entre matériaux immergés. Au moyen d'un contact plan-plan entre les brosses de PAA et les gels de PDMA et PAM attachés de façon covalente sur des substrats, une adhésion immergée stimulable par le pH de l'ordre de grandeur des adhésions thermodynamiques a été mise en évidence, de même que les cinétiques relativement lentes impliquées dans la formation et la rupture des complexes aux interfaces.

adhésion réversible

brosses de polymère

hydrogels neutres

complexes inter polymères

interactions faibles

réflectivité de neutrons

Synthesis, characterization, and biological evaluation of gelatin-based scaffolds

Tronci, Giuseppe

January 2010

This work presents the development of entropy-elastic gelatin based networks in the form of films or scaffolds. The materials have good prospects for biomedical applications, especially in the context of bone regeneration. Entropy-elastic gelatin based hydrogel films with varying crosslinking densities were prepared with tailored mechanical properties. Gelatin was covalently crosslinked above its sol gel transition, which suppressed the gelatin chain helicity. Hexamethylene diisocyanate (HDI) or ethyl ester lysine diisocyanate (LDI) were applied as chemical crosslinkers, and the reaction was conducted either in dimethyl sulfoxide (DMSO) or water. Amorphous films were prepared as measured by Wide Angle X-ray Scattering (WAXS), with tailorable degrees of swelling (Q: 300-800 vol. %) and wet state Young’s modulus (E: 70 740 kPa). Model reactions showed that the crosslinking reaction resulted in a combination of direct crosslinks (3-13 mol.-%), grafting (5-40 mol.-%), and blending of oligoureas (16-67 mol.-%). The knowledge gained with this bulk material was transferred to the integrated process of foaming and crosslinking to obtain porous 3-D gelatin-based scaffolds. For this purpose, a gelatin solution was foamed in the presence of a surfactant, Saponin, and the resulting foam was fixed by chemical crosslinking with a diisocyanate. The amorphous crosslinked scaffolds were synthesized with varied gelatin and HDI concentrations, and analyzed in the dry state by micro computed tomography (µCT, porosity: 65±11–73±14 vol.-%), and scanning electron microscopy (SEM, pore size: 117±28–166±32 µm). Subsequently, the work focused on the characterization of the gelatin scaffolds in conditions relevant to biomedical applications. Scaffolds showed high water uptake (H: 630-1680 wt.-%) with minimal changes in outer dimension. Since a decreased scaffold pore size (115±47–130±49 µm) was revealed using confocal laser scanning microscopy (CLSM) upon wetting, the form stability could be explained. Shape recoverability was observed after removal of stress when compressing wet scaffolds, while dry scaffolds maintained the compressed shape. This was explained by a reduction of the glass transition temperature upon equilibration with water (dynamic mechanical analysis at varied temperature (DMTA)). The composition dependent compression moduli (Ec: 10 50 kPa) were comparable to the bulk micromechanical Young’s moduli, which were measured by atomic force microscopy (AFM). The hydrolytic degradation profile could be adjusted, and a controlled decrease of mechanical properties was observed. Partially-degraded scaffolds displayed an increase of pore size. This was likely due to the pore wall disintegration during degradation, which caused the pores to merge. The scaffold cytotoxicity and immunologic responses were analyzed. The porous scaffolds enabled proliferation of human dermal fibroblasts within the implants (up to 90 µm depth). Furthermore, indirect eluate tests were carried out with L929 cells to quantify the material cytotoxic response. Here, the effect of the sterilization method (Ethylene oxide sterilization), crosslinker, and surfactant were analyzed. Fully cytocompatible scaffolds were obtained by using LDI as crosslinker and PEO40 PPO20-PEO40 as surfactant. These investigations were accompanied by a study of the endotoxin material contamination. The formation of medical-grade materials was successfully obtained (<0.5 EU/mL) by using low-endotoxin gelatin and performing all synthetic steps in a laminar flow hood. / Diese Arbeit beschreibt die Entwicklung Entropie-elastischer Gelatine-basierter Netzwerke als Filme und Scaffolds. Mögliche Anwendungen für die entwickelten Materialien liegen im biomedizinischen Bereich, insbesondere der Knochenregeneration. Im ersten Schritt der Arbeit wurden Entropie-elastische, Gelatine-basierte Hydrogel-Filme entwickelt, deren mechanische Eigenschaften durch die Veränderung der Quervernetzungsdichte eingestellt werden konnten. Dazu wurde Gelatine in Lösung oberhalb der Gel-Sol-Übergangstemperatur kovalent quervernetzt, wodurch die Ausbildung helikaler Konformationen unterdrückt wurde. Als Quervernetzer wurden Hexamethylendiisocyanat (HDI) oder Lysindiisocyanat ethylester (LDI) verwendet, und die Reaktionen wurden in Dimethylsulfoxid (DMSO) oder Wasser durchgeführt. Weitwinkel Röntgenstreuungs Spektroskopie (WAXS) zeigte, dass die Netzwerke amorph waren. Der Quellungsgrad (Q: 300-800 vol. %) und der Elastizitätsmodul (E: 70 740 kPa) konnten dabei durch die systematische Veränderung der Quervernetzungsdichte eingestellt werden. Die Analyse der Quervernetzungsreaktion durch Modellreaktionen zeigte, dass die Stabilisierung der Hydrogele sowohl auf kovalente Quervernetzungen (3-13 mol.-%) als auch auf Grafting von (5-40 mol.-%) und Verblendung mit Oligoharnstoffen (16-67 mol.-%) zurückgeführt werden kann. Die Erkenntnisse aus dem Umgang mit dem Bulk-Material wurden dann auf einen integrierten Prozess der Verschäumung und chemischen Quervernetzung transferiert, so dass poröse, dreidimensionale Scaffolds erhalten wurden. Dafür wurde eine wässrige Gelatinelösung in Gegenwart eines Tensids, Saponin, verschäumt, und durch chemische Quervernetzung mit einem Diisocyanat zu einem Scaffold fixiert. Die Scaffolds hergestellt mit unterschiedlichen Mengen HDI und Gelatine, wurden im trockenen Zustand mittels Mikro Computertomographie (µCT, Porosität: 65±11–73±14 vol.-%) und Rasterelektronenmikroskopie (SEM, Porengröße: 117±28–166±32) charakterisiert. Anschließend wurden die Scaffolds unter Bedingungen charakterisiert, die für biomedizinische Anwendungen relevant sind. Die Scaffolds nahmen große Mengen Wasser auf (H: 630 1680 wt.-%) bei nur minimalen Änderungen der äußeren Dimensionen. Konfokale Laser Scanning Mikroskopie zeigte, dass die Wasseraufnahme zu einer verminderten Porengröße führte (115±47–130±49 µm), wodurch die Formstabilität erklärbar ist. Eine Formrückstellung der Scaffolds wurde beobachtet, wenn Scaffolds im nassen Zustand komprimiert wurden und dann entlastet wurden, während trockene Proben in der komprimierten Formen blieben (kalte Deformation). Dieses Entropie-elastische Verhalten der nassen Scaffolds konnte durch die Verminderung der Glasübergangstemperatur des Netzwerks nach Wasseraufnahme erklärt werden (DMTA). Die zusammensetzungsabhängigen Kompressionsmoduli (Ec: 10 50 kPa) waren mit den mikromechanischen Young’s moduli vergleichbar, die mittels Rasterkraftmikroskopie (AFM) gemessen wurden. Das hydrolytische Degradationsprofil konnte variiert werden, und während des Abbaus kam es nur zu kontrolliert-graduellen Änderungen der mechanischen Eigenschaften. Während der Degradation konnte ein Anstieg der mittleren Porengröße beobachtet werden, was durch das Verschmelzen von Poren durch den Abbau der Wände erklärt werden kann. Die Endotoxinbelastung und die Zytotoxizität der Scaffolds wurden untersucht. Humane Haut-Fibroblasten wuchsen auf und innerhalb der Scaffolds (bis zu einer Tiefe von 90 µm). Indirekte Eluat-Tests mit L929 Mausfibroblasten wurden genutzt, um die Zytotoxizität der Materialien, insbesondere den Einfluss des Quervernetzertyps und des Tensids, zu bestimmen. Vollständig biokompatible Materialien wurden erzielt, wenn LDI als Quervernetzer und PEO40 PPO20-PEO40 als Tensid verwendet wurden. Durch den Einsatz von Gelatine mit geringem Endotoxin-Gehalt, und die Synthese in einer Sterilarbeitsblank konnten Materialien für medizinische Anwendungen (Endotoxin-Gehalt < 0.5 EU/mL) hergestellt werden.

Hydrogele

Polymer-Netzwerke

Gelatine

poröse Gerüste

Abbau

regenerative Medizin

hydrogels

polymer networks

gelatin

porous scaffolds

degradation

regenerative medicine

Life sciences

Multi-Hierarchical Self-Assembly of Collagen Mimetic Peptides into AAB Type Heterotrimers, Nanofibers and Hydrogels Driven by Charged Pair Interactions

January 2012

Replicating the multi-hierarchical self-assembly of collagen (peptide chain to triple helix to nanofiber and, finally, to a hydrogel) has long attracted scientists, both from the fundamental science perspective of supramolecular chemistry and for the potential biomedical applications perceived in tissue engineering. In terms of triple helical formation, collagen is the most abundant protein in the human body with at least 28 types, yet research involving collagen mimetic systems has only recently began to consider the innate ability of collagen to control helix composition and register. Collagen triple helices can be homotrimeric or heterotrimeric and while some types of natural collagen form only one specific composition of helix, others can form multiple. It is critical to fully understand and, if possible, reproduce the control that native collagen has on helix composition and register. In terms of nanofiber formation, many approaches to drive the self-assembly of synthetic systems through the same steps as natural collagen have been partially successful, but none have simultaneously demonstrated all levels of structural assembly. In this work, advancements in the ability to control helix composition and replicate the multi-hierarchical assembly of collagen are described. Both positive and negative design for the assembly of AAB type collagen heterotrimers were utilized by promoting heterotrimer formation though the use of charged amino acids to form intra-helix electrostatic interactions, while simultaneously discouraging homotrimers, resulting in the identification of multiple peptide systems with full control over the composition of the resulting triple helix. Similar salt-bridged hydrogen bonds between charged residues were incorporated into nanofiber forming peptides, one of which successfully assembled into sticky-ended triple helices, nanofibers with characteristic triple helical packing visible in the solution state, and strong hydrogels that are degraded by collagenase at a similar rate to natural collagen. Together, these results provide a better understanding of the self-assembly of collagenous sequences as well as a novel design scheme for synthetic extracellular matrix mimetics with potential applications in regenerative medicine and drug delivery.

Applied sciences

Pure sciences

Biological sciences

Self-assembly

Collagen

Nanofibers

Hydrogels

Charged pair interactions

Triple helix

Molecular biology

Biochemistry

Nanoscience

Bone tissue engineering utilizing adult stem cells in biologically functionalized hydrogels

Dosier, Christopher R.

09 April 2013

Repair of large bone defects remains a clinical challenge for orthopedic surgeons. Current treatment strategies such as autograft and allograft are limited by the amount of available tissue in the case of the former, and failure of revascularization effecting engraftment in the case of the latter. Tissue engineering offers an alternative approach to this challenging clinical problem. The general principle of tissue engineering for bone regeneration prescribes delivery of osteoinductive factors to induce an endogenous response within the host to repair a defect that will not normally heal. One such tissue engineering approach is cell based therapy and this is attractive in the cases of patients with a lack of endogenous osteoprogenitors cells due to volumetric loss of tissue/ageing. Stem cell therapy has emerged as a possible alternative to current treatment modalities, however many challenges to clinical translation remain. Central to these challenges for bone tissue engineering are lingering questions of which cells to use and how to effectively deliver those cells. The goal of this thesis was to elucidate more effective ways to enhance bone repair utilizing adult stem cells. First, we investigated adipose derived stem cells (ADSCs) as a viable cell source for bone tissue engineering. Upon isolation, adipose derived stem cells are a heterogeneous population of multipotent cells predisposed to adipogenic differentiation. We developed an enrichment protocol that demonstrated the osteogenic potential of ADSCs can be enhanced in a dose dependent manner with resveratrol, which had been demonstrated to up-regulate Runx-2 expression. This enrichment strategy produced an effective method to enhance the osteogenic potential of ADSCs while avoiding cell sorting and gene therapy techniques, thus bypassing the use of xenogenic factors to obtain an enriched source of osteoprogenitor cells. This protocol was also used to investigate differences between human and rat ADSCs and demonstrated that rat ADSCs have a higher osteogenic potential than human ADSCs in vitro. The second major thrust of this thesis was to develop an injectable hydrogel system to facilitate bone formation in vivo. Both a synthetic and a naturally based polymer system was investigated, the results of which demonstrated that the naturally based alginate hydrogel was a more effective vehicle for both cell viability in vitro and bone formation in vivo. Our results also demonstrated that despite the ability to increase the osteogenic potential of ADSCs in vitro with resveratrol treatment, this was insufficient to induce bone formation in vivo. However, the inclusion of bone marrow mesenchymal stem cells (BMMSCs) in BMP-2 functionalized alginate hydrogels resulted in significantly greater mineralization than acellular hydrogels. Finally, the effect of timing of delivery of therapeutics to a non-healing segmental bone defect in the femur was investigated. We hypothesized that delivery of biologics after the initial inflammation response caused by injury to the host tissue would result in greater regeneration of tissue in terms of newly formed bone. Contrary to our initial hypothesis, these experiments demonstrated that delayed implantation of therapeutics has a detrimental effect on the overall healing response. It was, however, demonstrated that the inclusion of BMMSCs results in greater bone volume regenerated in the defect site over acellular hydrogels. In conclusion, this work has rigorously investigated the use of adipose derived stem cells for bone tissue engineering, and further produced an injectable hydrogel system for stem cell based bone tissue engineering. This work also demonstrated that the inclusion of adult stem cells, specifically BMMSCs, can enhance the regeneration response in a non-healing bone defect model relative to acellular hydrogel.

Tissue Engineering

Bone

Hydrogels

Stem cells

Biomedical engineering

Regenerative medicine

Tissue culture

Bone regeneration

Stem cells Transplantation

Colloids

Design, Synthesis and Characterization of Multiresponsive Microgels

Nayak, Satish Prakash

26 January 2005

This thesis is geared towards using hydrogel nanoparticles in various biotechnological applications. The polymer that was used in making these nanoparticles was poly(N-isopropylacrylamide), which is a thermoresponsive polymer. These particles were used in making fast responsive polymer films, which can be used in optics. It was observed that the rate of deswelling increased as the concentration of the nanoparticles in the film was increased. These particles were also used in making photoresponsive materials. In this case a photoresponsive dye (malachite green) was conjugated to these nanoparticles and in presence of light of appropriate wavelength the particles undergo a phase transition. A core/shell construct was synthesized where the core was composed of degradable cross-links and the shell of composed of non-degradable cross-links. The degradable cross-linker had vicinal diols, which can be cleaved by sodium periodate. Hence after degrading the core, hollow particles were obtained. Zwitterionic particles were made by incorporating a cationic and anionic comonomer. These microgels go from a positively charged state to zwitterionic to negatively charged state on increasing the pH. One of the important potential applications for these microgels is drug delivery. Microgels were used for targeting cancer cells. Folic acid was used as the targeting ligand. The microgels were conjugated with folic acid and were able to target cells that overexpress folate receptors. In one other application core/shell microgels were made which exhibit pore-size dependent permeation of proteins.

pNIPAm

Core/Shell

Nanoparticles

Hydrogels

Polymers

Thin films

Colloids

Nanoparticles Synthesis

Polymers Optical properties

Polymers Thermal properties

Growth Plate Regeneration Using Polymer-Based Scaffolds Releasing Growth Factor

Clark, Amanda

01 January 2013

Currently growth plate fractures account for nearly 18.5% of fractures in children and can lead to stunted bone growth or angular deformation. If the body is unable to heal itself a bony bar forms, preventing normal bone growth. Clinical treatment involves removing the bony bar and replacing it with a filler substance, which causes poor results 60% of the time. Using primarily poly(lactic-co-glycolic acid) (PLGA) as the scaffold material, the goal was to develop an implant that would support to the implant site, allow for cell ingrowth, and degrade away over time. Porous scaffolds were fabricated from PLGA microspheres using the salt leaching method. The first part of this work investigated the effect of sintering the microspheres by studying the mechanical properties, degradation and morphology and their potential applications for hard and soft tissue implants. Growth factor or drugs can be encapsulated into PLGA microspheres, which was the second part of this work. Encapsulated insulin-like growth factor I (IGF-I) was able to withstand the scaffold fabrication process without compromising it’s bioactivity and promoted cell proliferation. The next part of this work experimented with the addition of a hydrogel porogen. Porogen particles were made using a quick degrading poly(beta-amino ester) (PBAE) hydrogel and loaded with ketoprofen. The addition of the porogen creates a dual drug-releasing scaffold with a localized delivery system. The final step of this work involved animal studies to determine the effectiveness of the scaffolds in growth plate regeneration and how they compare to the current clinical treatment option. Gross observation, microCT analysis, angular measurement of bone growth and histological methods were employed to evaluate the scaffolds. The goal was to develop a versatile scaffold that could be used for a wide range of tissue engineering applications. The mechanical properties, degradation profiles and drug delivery capabilities can be all tailored to meet the specific needs of an implant site. One specific application was regenerating the native growth plate that can also encourage the endogenous mesenchymal stem cells to follow the desire linage. By regenerating the native growth plate, angular deformation and stunted limb growth were greatly reduced.

Biodegradable polymers

biodegradable hydrogels

tissue engineering scaffolds

growth plate regeneration

controlled drug delivery

Biomaterials