Tailoring the Properties of Supramolecular Gels

Buerkle, Lauren Elizabeth

30 January 2012

No description available.

Biomedical Engineering

Materials Science

Nanoscience

Organic Chemistry

Polymer Chemistry

Polymers

Supramolecular hydrogels

guanosine

gluconamides

tissue engineering scaffolds

Magnetic Functionalization of Poly(N-isopropylacrylamide) Hydrogels for Sensor Applications

Keßler, Christian, Gerlach, Gerald

31 May 2024

To develop a hydrogel sensor system using the Hall effect to detect the degree of swelling, gels containing high concentrations of magnetic particles are necessary to induce a strong magnetic field. For this purpose, hydrogels based on poly(N-isopropylacrylamide) cross-linked with Laponite XLS are modified with various magnetic nanoparticles. The focus of this work is to introduce high particle densities with a homogeneous distribution into the gel. Particles are coated with 3-(trimethoxysilyl)propyl methacrylate to bind them into the network structure. The swelling behavior and temperature response of gels containing pure and modified particles are compared to the unmodified clay gel. Ferrogels are further synthesized in a magnetic field to permanently align magnetic nanoparticles in the network. This results in permanently embedded rod-like structures spanning the entire length of the gel. The influence of this anisotropic distribution on the mechanical properties of the hydrogel is investigated through compression measurements.

info:eu-repo/classification/ddc/530

ddc:530

Engineered microsystems and their application in the culture and characterization of three-dimensional (3D) breast tumor models

Menon, Nidhi

26 May 2021

Microsystems are a broad category of engineered technologies in the micro and nano scale that have a diverse range of applications. They are emerging as a powerful tool in the field of biomedical research, drug discovery, as well as clinical diagnostics and prognostics, especially with regards to cancer. One of the major challenges in precision and personalized medicine in cancer lies in the technical difficulties of ex-vivo cell culture and propagation of the limited number of primary cells derived from patients. Therefore, our aims are to 1. Develop a biologically relevant platform for culturing cancer cells and characterize how it influences the cell growth and phenotype compared to conventional 2-dimensional(2D) cell culturing techniques, 2. Isolate secondary metabolites from endophytic fungi and screen them on the platform for potential anticancer properties in a preliminary drug discovery pipeline, 3. Design and develop biosensors for quantifying cell responses in real-time within these systems. Several biomaterial scaffolds with microscale architectures have been utilized for engineering the tumor extracellular matrix, but very few studies have thoroughly characterized the phenotypic changes in their cell models, which is critical for translational applications of biomaterial systems. The overall objective of these studies is to engineer a biomimetic platform for the culture of breast cancer cells in vitro and to quantify and profile their phenotypic changes. In order to do this, we first evaluated a blank-slate matrix consisting of thiolated collagen, hyaluronic acid and heparin, cross-linked chemically via Michael addition reaction using diacrylate functionalized poly (ethylene glycol). The hydrogel network was used with triple-negative breast cancer cells and showed significant changes in characteristics, with cells self-assembling to form a 3D spheroid morphology, with higher viability, and exhibiting significantly lower cell death upon chemotherapy treatment, as well as had a decrease in proliferation. Furthemore, the transcriptomic changes quantified using RNA-Seq and Next-Gen Sequencing showed the dramatic changes in some of the commonly targeted pathways in cancer therapy. Furthermore, we were able to show the importance of our biomimetic platform in the process of drug discovery using fungal endophytes and their secondary metabolites as the source for potential anticancer molecules. Additionally, we developed gold nanoparticle and antibody-based (ICAM1 and CD11b) sensors to quantify cell responses spatiotemporally on our platform. We were able to show quenching of the green fluorescent fluorophores due to the Förster Resonance Energy Transfer mechanism between the fluorophore and the gold nanometal surface. We also observed antigen-dependent recovery of fluorescence and inhibition of energy transfer upon the antibody binding to the cell-surface receptors. Future efforts are directed towards incorporating the hydrogel system with antigen-dependent sensors in a conceptually-designed microfluidic platform to spatiotemporally quantify the expression of surface proteins in various cells of the tumor stroma. This includes the migration,infiltration, and polarization of specific immune cells. This approach will provide further insight into the heterogeneity of cells at the single-cell resolution in defined spaces within the 3D microfluidic platform. / Doctor of Philosophy / Microsystems are a broad category of engineered technologies in the micro and nano scale that have a diverse range of applications. They are emerging as a powerful tool in the field of biomedical research, drug discovery, as well as clinical diagnostics and prognostics, especially with regards to cancer. However, a major challenge in being able to offer personalized medicine to cancer patients comes from the difficulty of growing cells from the patient's tumor biopsy in a laboratory for further screening and analysis. There are also limited resources available for real-time expression of proteins on cell-surfaces, that could be potential biomarkers and targets for treatment. Various natural and synthetic polymers are biocompatible and have been used widely in engineering the tumor extracellular matrix. However, the effect of hydrogels derived from these polymers on the specific tumor cells are not always well characterized. Our studies explore the influence of a biohybrid hydrogel on breast cancer cells and our results show that the microscale architecture of the hydrogel platform works as a suitable scaffold for recapitulating the 3-dimensional(3D) breast tumor microenvironment, and can also be employed in the drug discovery process. Additionally, we developed a nano-scale biosensor to enable the quantification of specific cell-surface proteins in real-time. Ongoing and future efforts are focused on designing and fabricating a microfluidic device with precise control over the design of space and special chambers for cell culture. These will be used for studying interactions of various cells in the tumor microenvironment that influence cancer progression. Integrating these micro-scale systems, including sensors will allow researchers to quantify cell behavior in response to the variable factors they are exposed to, as well as provide insight to answer fundamental questions about cancer biology that are limited by the conventional 2D cell culture systems.

Breast cancer

Tumor microenvironment

Tumor Extracellular Matrix (ECM)

3D-tumor models

Biomaterials

Hydrogels

Fungal Endophytes

Drug Discovery

Biosensors

FRET

Characterization of the Interfacial Fracture of Solvated Semi-Interpenetrating Polymer Network (S-IPN) Silicone Hydrogels with a Cyclo-Olefin Polymer (COP)

Murray, Katie Virginia

25 May 2011

As hydrogel products are manufactured and used for applications ranging from biomedical to agricultural, it is useful to characterize their behavior and interaction with other materials. This thesis investigates the adhesion between two different solvated semi-interpenetrating polymer network (S-IPN) silicone hydrogels and a cyclo-olefin (COP) polymer through experimental, analytical, and numerical methods. Interfacial fracture data was collected through the application of the wedge test, a relatively simple test allowing for the measurement of fracture properties over time in environments of interest. In this case, the test was performed at discrete temperatures within range of 4Ë C to 80Ë C. Two COP adherends were bonded together by a layer of one of the S-IPN silicone hydrogels. Upon the insertion of a wedge between the two adherends, debonding at one of the two interfaces would initiate and propagate at a decreasing rate. Measurements were taken of the debond length over time and applied to develop crack propagation rate versus strain energy release rate (SERR) curves. The SERR values were determined through the application of an analytical model derived for the wedge test geometry and to take into account the effects of the hydrogel interlayer. The time-temperature superposition principle (TTSP) was applied to the crack propagation rate versus SERR curves by shifting the crack propagation rates with the Williams-Landel-Ferry (WLF) equation-based shift factors developed for the bulk behavior of each hydrogel. The application of TTSP broadened the SERR and crack propagation rate ranges and presented a large dependency of the adhesion of the system on the viscoelastic nature of the hydrogels. Power-law fits were applied to the master curves in order to determine parameters that could describe the adhesion of the system and be applied in the development of a finite element model representing the interfacial fracture that occurs for each system. The finite element models were used to validate the analytical model and represent the adhesion of the system such that it could be applied to future geometries of interest in which the S-IPN silicone hydrogels are adhered to the COP substrate. <i>[Files modified per J. Austin, July 9, 2013 Gmc]</i> / Master of Science

S-IPN hydrogels

confinement

Finite element method

debonding

strain energy release rate

bridging

cyclo-olefin polymers

interfacial fracture

Development and Characterization of Gel-Like Structures from Aquatic Biomass for Food Applications / Obtención y caracterización de estructuras tipo gel a partir de biomasa acuática para aplicaciones alimentarias

Fontes Candia, Cynthia

28 July 2022

Tesis por compendio / [ES] El objetivo de esta tesis doctoral ha sido el diseño y caracterización estructural de estructuras tipo gel basadas de polisacáridos extraídos de biomasa acuática con interés para aplicaciones relacionadas con la alimentación. Las propiedades de los polisacáridos extraídos de algas y plantas acuáticas son adecuadas para producir diferentes estructuras tipo gel basadas en la formación de redes reticuladas, como hidrogeles, aerogeles y emulsion-gels. En la primera parte de esta tesis se investigaron los diferentes mecanismos de gelificación de polisacáridos sulfatados, así como los parámetros que afectan a la estructura y las propiedades funcionales de los hidrogeles obtenidos. En base a los resultados, se evaluó la potencial aplicación de los hidrogeles y aerogeles de agar y k-carragenato para encapsular una proteína alimentaria modelo como la caseína, explorando así el efecto protector contra la hidrólisis enzimática tras digestiones gastrointestinales simuladas. En la segunda parte de esta tesis, se desarrollaron estructuras de aerogeles mediante la valorización de una fuente de biomasa residual infrautilizada, como es el Arundo donax. Con esta biomasa se generaron fracciones celulósicas con diferentes grados de purificación y extractos bioactivos solubles en agua, que posteriormente se utilizaron para producir aerogeles bioactivos híbridos. La estructura altamente porosa y la elevada capacidad de sorción de los aerogeles los convierten en excelentes candidatos para la sustitución de las almohadillas absorbentes para mantener la calidad de los productos cárnicos envasados. Los emulsion-gels son reconocidos por su gran potencial como ingredientes funcionales en la industria alimentaria como modificadores de textura y como sustitutos de grasas sólidas. Además, pueden utilizarse como vehículo para la liberación controlada de compuestos bioactivos liposolubles. Así, en la última parte de esta tesis, se investigó la naturaleza de las interacciones entre los componentes en las formulaciones de emulsion-gels basadas en polisacáridos y se relacionó con su estructura y comportamiento mecánico y reológico. Después de estudiar el mecanismo de gelificación de los emulsion-gels de carragenato, estos sistemas se adaptaron y utilizaron para dos diferentes aplicaciones relevantes para los sectores de alimentación y biomedicina. En primer lugar, se produjeron y evaluaron estructuras gelificadas a partir de emulsion-gels de agar y k-carragenato y aerogeles cargados de aceite como encapsulantes de un bioactivo lipofílico como la curcumina. Los resultados mostraron que el tipo de polisacárido y el estado físico de las redes del gel tenían un impacto en la estructura de los productos de la digestión. Por otro lado, se evaluó el potencial de los emulsion-gels basados en polisacáridos sulfatados (k-carragenato y agar) para la producción de un material capaz de simular tejido graso. Los resultados evidencian que los emulsions-gels de agar son adecuadas para producir materiales que simulan las propiedades dieléctricas para imitar tejidos de bajo y alto contenido en agua. / [CA] L'objectiu d'aquesta tesi doctoral ha sigut, el disseny i caracterització estructural d'estructures tipus gel, basades en polisacàrids extrets de biomassa aquàtica amb interès per a aplicacions relacionades amb l'alimentació. Les propietats dels polisacàrids extrets d'algues i plantes aquàtiques, són adequades per a produir diferents estructures tipus gel basades en la formació de xarxes reticulades, com a hidrogels, aerogels i emulsió-gels. En la primera part d'aquesta tesi es van investigar els diferents mecanismes de gelificació de polisacàrids sulfatats, així com els paràmetres que afecten l'estructura i les propietats funcionals dels hidrogels obtinguts. Sobre la base dels resultats, es va avaluar la potencial aplicació dels hidrogels i aerogels d'agar i k-carraguenina per a encapsular una proteïna alimentària model com la caseïna, explorant així l'efecte protector contra la hidròlisi enzimàtica després de digestions gastrointestinals simulades. A la segona part d'aquesta tesi, es van desenvolupar estructures d' aerogels mitjançant la valorització d'una font de biomassa residual infrautilitzada, com és el Arundo donax. Amb aquesta biomassa es van generar fraccions cel·lulòsiques amb diferents graus de purificació i extractes bioactius solubles en aigua, que posteriorment es van utilitzar per a produir aerogels bioactius híbrids. L'estructura altament porosa i l'elevada capacitat de sorció dels aerogels els converteixen en excel·lents candidats per a la substitució dels coixinets absorbents per a mantenir la qualitat dels productes carnis envasats. Els emulsió-gels són reconeguts pel seu gran potencial com a ingredients funcionals en la indústria alimentària com a modificadors de textura i com a substituts de greixos sòlids. A més, poden utilitzar-se com a vehicle per a l'alliberament controlat de compostos bioactius liposolubles. Així, a l'última part d'aquesta tesi, es va investigar la naturalesa de les interaccions entre els components dins les formulacions d' emulsió-gels basades en polisacàrids i es va relacionar amb la seua estructura i comportament mecànic i reològic. Després d'estudiar el mecanisme de gelificació dels emulsió-gels de carraguenina, aquests sistemes es van adaptar i es van utilitzar per a dues aplicacions diferents, rellevants per als sectors de l' alimentació i la biomedicina. En primer lloc, es van produir i van avaluar estructures gelificades a partir de emulsió-gels d'agar i k-carraguenina i aerogels carregats d'oli com a encapsulants d'un bioactiu lipofílic com la curcumina. Els resultats van mostrar que el tipus de polisacàrid i l'estat físic de les xarxes del gel tenien un impacte en l'estructura dels productes de la digestió. D'altra banda, es va avaluar el potencial dels emulsió-gels basats en polisacàrids sulfatats (k-carraguenina i agar) per a la producció d'un material capaç de simular teixit gras. Els resultats evidencien que els emulsió-gels d'agar són adequats per a produir materials que simulen les propietats dielèctriques podentimitar teixits de baix i alt contingut en aigua. / [EN] The aim of this doctoral thesis was to design and characterize the structure of gel-like structures based on polysaccharides extracted from aquatic biomass, with interest for food-related applications. The properties of polysaccharides extracted from seaweeds and aquatic plants make them suitable to produce a range of gel-like structures based on the formation of interconnected networks, such as hydrogels, aerogels and emulsion-gels. In the first part of this thesis, the different gelation mechanism of sulphated polysaccharides and the parameters affecting the structure and functional properties of the obtained hydrogels were investigated. Based on the results, the potential application of agar and k-carrageenan hydrogels and aerogels to encapsulate a model food protein such as casein was evaluated, thus exploring the protective effect against the enzymatic hydrolysis upon simulated gastrointestinal digestions. In the second part of this thesis, aerogel structures were developed by valorising an underutilized waste biomass source such as Arundo donax. This biomass was used to generate cellulosic fractions with different purification degrees and water-soluble bioactive extracts, which were subsequently used to produce hybrid bioactive aerogels. The highly porous structure and high sorption capacity of aerogels make them excellent candidates for the replacement of absorbent pads to maintain the quality of packaged meat products. Emulsion-gels are recognized for their great potential as functional ingredients in the food industry to modify texture and for solid fat replacement. Moreover, they can be used as a delivery vehicle for the controlled release of fat-soluble bioactive compounds. Thus, in the last part, the nature of interactions between the components in polysaccharide-based emulsion-gel formulations was investigated and related to their structure and mechanical and rheological behavior. After studying the gelation mechanism of carrageenan emulsion-gels, these systems were adapted and used for two different applications relevant to the food and biomedicine sectors. Firstly, oil-filled gel-like structures from agar and k-carrageenan emulsion-gels and oil-filled aerogels were produced and evaluated as carriers of a lipophilic bioactive such as curcumin. The results showed that the polysaccharide type and the physical state of the gel network had an impact on the structure of the digestion products. On the other hand, the potential of emulsion-gels based on sulphated polysaccharides (k-carrageenan and agar) for the production of tissue mimicking phantoms was evaluated. The results evidence that the agar emulsion-gels are suitable to produce materials simulating the dielectric properties to mimic low- and high-water content tissues. / Synchrotron experiments were performed at NCD beamline at ALBA Synchrotron with the collaboration of ALBA staff (2018022638 project). This work was financially supported by the grant RTI2018-094268-B-C22 (MCIU/AEI/FEDER, UE). Part of this work was supported by the COST Action ES1408 European network for algal-bioproducts (EUALGAE). Cynthia Fontes-Candia is recipient of a pre-doctoral grant from CONACYT (MEX/Ref. 306680). The projects RTI2018-094268-B-C22 and RTI2018-094408-J-I00 were funded by MCIN/AEI/10.13039/501100011033 and by “ERDF A way of making Europe”. This work has also received financial support from project PID2019-107663RB-I00 from the Spanish Ministry of Science and Innovation (MICINN). Cynthia Fontes-Candia is recipient of a pre-doctoral grant from CONACYT (MEX/Ref. 306680). Marta Martinez-Sanz is recipient of a Juan de la Cierva (IJCI-2015-23389) contract from the Spanish Ministry of Economy, Industry and Competitiveness. / Fontes Candia, C. (2022). Development and Characterization of Gel-Like Structures from Aquatic Biomass for Food Applications [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/181564 / Compendio

Hidrogeles

Aerogeles

Geles en emulsión

Biomasa acuática

Gelificación

Polisacáridos de algas

Aerogels

Hydrogels

Emulsion gels

Aquatic biomass

Gelation

Seaweed polysaccharides

Generation and Use of Functional Hydrogels That Can Rapidly Sample Infected Surfaces

Swift, Thomas, Pinnock, A., Shivshetty, N., Pownall, David, MacNeil, S., Douglas, I., Garg, P., Rimmer, Stephen

09 August 2022

Yes / This paper outlined our method for developing polymer-linked contact lens type materials for rapid detection and differentiation of Gram-positive, Gram-negative bacteria and fungi in infected corneas. It can be applied to both model synthetic or ex-vivo corneal models and has been successfully trialed in an initial efficacy tested animal study. First a hydrogel substrate for the swab material is selected, we have demonstrated selective swabs using a glycerol monomethacrylate hydrogel. Alternatively any commercial material with carboxylic acid functional groups is suitable but risks nonspecific adhesion. This is then functionalised via use of N-hydroxysuccinimide reaction with amine groups on the specified highly branched polymer ligand (either individually gram negative, gram positive or fungal binding polymers or a combination of all three can be employed for desired sensing application). The hydrogel is then cut into swabs suitable for sampling, used, and then the presence of gram positive, game negative and fungi are disclosed by the sequential addition of dyes (fluorescent vancomycin, fluorescein isothiocyanate and calcofluor white). In summary this method presents: Method to produce glycerol monomethacrylate hydrogels to minimize nonspecific binding Methods of attaching pathogen binding highly branched polymers to produce selective hydrogel swabs Method for disclosing bound pathogens to this swab using sequential dye addition

Contact lens

Pathogen diagnosis

Medical device

Specificity

Amphotericin elisa

Polymyxin elisa

Highly branched polymers

Microbe detection

Functional hydrogels

Cornea - infections

Étude des dérivés de la chitosane et leur intérêt en technologie pharmaceutique

Gueddi, Mohammed

12 1900

Mémoire numérisé par la Direction des bibliothèques de l'Université de Montréal. / Le présent travail s'inscrit dans le domaine de la libération contrôlée des médicaments. Un polymère naturel, la chitosane modifiée par acylation, fait l'objet de l'étude en tant que nouvel excipient pour la fabrication des comprimés à libération prolongée de principe actif. La chitosane est un polysaccharide préparé chimiquement à partir de la chitine par un traitement alcalin à haute température (Muzzareli, 1977). Elle ne possède pas la propriété de former un gel dans un milieu aqueux, cependant, lorsque les molécules de ce polymère sont substituées par des chaînes carbonées, cela génère des dérivés de chitosane capables de gonfler dans l'eau ou dans un tampon phosphate. Le mécanisme de gonflement du polymère substitué est dû à l'éloignement des macromolécules les unes des autres entraînant ainsi un espace diffusionnel. Une telle structure est appelée hydrogel. Les propriétés gélifiantes de ces dérivés de chitosane ont été mises à profit pour l'étude de la cinétique de libération des médicaments. La première section de ce mémoire est une revue des différentes formes à libération contrôlée. La deuxième section est divisée en deux parties : la première décrit la synthèse de trois dérivés de chitosane. Ces derniers sont caractérisés par leur capacité à former un gel en milieu aqueux. Dans la deuxième partie, les systèmes réservoir et matriciel ont été choisis comme modèle pour analyser l'influence du poids moléculaire du médicament ainsi que de la géométrie du comprimé sur la cinétique de libération. Pour déterminer le mécanisme de libération, on a utilisé l'équation de PEPPAS (Peppas, 1987) comme modèle mathématique afin d'interpréter les résultats expérimentaux.

Libération contrôlée

Chitosane modifiée

Polymère naturel

Acylation

Hydrogels

Cinétique de libération

Systèmes réservoir et matriciel

Équation de PEPPAS

Bile Acid Based Supramolecular Gels, Semiconductor Nanocrystals And Soft Hybrid Materials

Chakrabarty, Arkajyoti

10 1900

Chapter 1. General Introduction This chapter gives an introduction to supramolecular organo/hydrogels and the related bile acid chemistry touching upon the gelation properties of the bile acid derivatives. Diverse applications of the supramolecular gels are illustrated with several examples. In the concluding section of this chapter, a brief introduction on the semiconductor nanocrystals is provided. Finally, the content of the thesis is outlined. Chapter 2. Bile Acid Derived Novel Organo/hydrogelators Part 1. Bile Acid Derived Organo/hydrogelators With a Basic Side Chain Cationic analogues of bile acids which showed remarkable gelation properties in water were reported from our laboratory. This led us to investigate the aggregation behaviour of some of the lithocholic and deoxycholic acid derivatives having a basic side-chain. Figure 1. Bile acid based organo/hydrogelators containing a basic side-chain. In this part, an organogelator 1 and a hydrogelator 2 derived from parent bile acids have been described with respect to their gelation properties, morphology, thermal and mechanical stability of the gels. The organo/hydrogels were shown to be responsive to acid-base stimuli as the organogel formed only in the protonated state and the hydrogel formed in the neutral form of the tertiary amines. The xerogel fibres obtained from the organogel were found to be solid-like and stable up to 200 oC as confirmed by variable temperature polarizing optical microscopy. The non-fluorescent organogel was doped with a fluorescent dye (coumarin 153) to design a novel dye-organogel composite material which was investigated with laser scanning confocal fluorescence microscopy showing the dye molecules were uniformly deposited on the organogel fibres. Part 2. Serendipitous Organogelation by Dimeric Bile Acid Esters This section highlights our work on the organogelators based on a number of dimeric esters consisting of different bile acid units. Figure 2. The three different dimeric bile acid esters as organogelators. In this part, three bile acid derived dimeric esters (1, 2 and 3) were shown to possess organogelation properties in aromatic and halogenated aromatic solvents. We studied the morphological features and rheological properties of these organogels. Next, the organogel matrix was exploited to generate and stabilize gold nanoparticles and prepare AuNP/gel hybrid material. Chapter 3. Cholate Hydrogels and Soft Gel-nanoparticle Hybrid Materials Sodium cholate does not form gel in water under any condition as compared to other sodium salts of other bile acids such as sodium deoxycholate and lithocholate which show pH-dependent gelation behaviour. Figure 3. Metal cholate hydrogels derived from sodium cholate and a variety of metal ions. In this chapter, super hydrogelation of sodium cholate induced by a variety of metal ions (Ca2+, Cu2+, Co2+, Zn2+, Cd2+, Hg2+ and Ag+) is highlighted with respect to their morphology and mechanical strength/stability. The calcium cholate supramolecular system showed the presence of helically twisted nanofibres which were utilised in the synthesis of soft hybrid materials containing metal (Au and Ag) and metal sulphide (CdS, ZnS, HgS, etc.) nanoparticles. Chapter 4. Cadmium Deoxycholate and Highly Luminescent CdSe Nanocrystals Bile acid derivatives have very high chemical and thermal stability owing to the presence of a rigid steroidal nucleus. We explored the possibility of utilizing the bile salt derived from Cd as a metal complexes as precursor to high quality nanocrystals (NCs) which can only be accessed at high temperatures (>200 oC). Figure 4. Synthesis of high quality CdSe NCs from cadmium deoxycholate. In this chapter, the synthesis of high quality CdSe nanocrystals is discussed using a novel bile acid based precursor: cadmium salt of 7-deoxycholic acid, which has high thermal stability and can be conveniently used at very high temperatures (>300 oC) required for the synthesis of high quality nanocrystals. Syntheses were done both by ‘injection’ and ‘non-injection’ modes. The as-prepared nanocrystals have high photoluminescence quantum yield, multiple excitons, narrow size-distributions and zinc blende/wurtzite crystalline cores. Appendix. Steroidal Thiols in Design of Novel Quantum dot (QD)/Gel Hybrid Materials Bile acid derived steroidal thiols were reported to be efficient capping agents for silver and gold nanoparticles from our laboratory. So, we wanted to check whether they could stabilize the semiconductor nanocrystals as well. Figure 5. Steroidal thiols as stabilizers of semiconductor quantum dots. In this short report, we describe the efficient capping by bile acid derived thiols of group II-VI semiconductor nanocrystals/quantum dots (QDs) (CdS, CdSe). After synthesizing the thiol capped QDs, we tried to disperse the capped nanoparticles into the gel fibres. The hybrid gels showed the presence of nanoparticles inside the fibres as observed by transmission electron microscopy, although the photoluminescence of the QDs was very low in the gel matrix, which might be due to the inefficient surface passivation of the nanoparticles in the gel.

Bile Acid Supramolecular Gels

Semiconductor Nanocrystals

Supramolecular Organogels

Bile Acid Chemistry

Organogelation

Dimeric Bile Acid Esters

Organogelators

Cholate Hydrogels

Soft Gel-Nanoparticle Hybrid Materials

Cadium Deoxycholate

Cadium Selenide Nanocrystals

Soft Hybrid Materials

Supramolecular Hydrogels

Hydrogelators

Hydrogels

Supramolecular Gels

CdSe Nanocrystals

Hydrogelation

Organic Chemistry

The prostatic tumour stroma

Bonda, Ulrich

12 August 2016

The majority of cancer research projects mainly focus on the epithelial cancer cell, while the role of the tumour stroma has been largely neglected. Conventional 2D techniques, such as well plates and other kinds of tissue culture plastic, and animal models are mainly used to broaden our understanding of how tumours arise, develop, and induce metastasis. However, there is accumulating evidence suggesting a tremendous impact of the non‐cancerous tumour stroma on carcinogenesis, while other publications illustrate the great importance of advanced 3D in vitro models for cancer research. The overall goal of this work was to investigate how cancer associated fibroblasts (CAFs; the most abundant component in the tumour stroma) and normal prostate fibroblasts (NPFs), isolated from patients diagnosed with aggressive forms of prostate cancer, contribute to angiogenesis, an important hallmark of cancer progression. For this purpose, a 3D in vitro angiogenesis co‐culture model was established. At first, two (semi‐) synthetic hydrogel platforms, gelatine methacrylate (GelMA) and star‐shaped (star)PEG‐heparin hydrogels were characterised and their physicochemical properties were compared with each other. Interestingly, GelMA gels shrank while starPEG‐heparin gels swelled in cell culture medium over the course of 24 hours. The cell concentration, in addition to the stiffness, was critical for the formation of endothelial networks, and the knowledge of swelling behaviour enabled the adjustment of initial cell density to ensure the density between both gel types was comparable. Moreover, preliminary tests with mesenchymal stem cells demonstrated that the hydrogel can be actively remodelled, as evaluated by stiffness parameters at day one and seven of incubation. Growth factors (GFs) affect cellular fate and behaviour, and storage, presentation and administration of such chemokines can be critical for certain cellular applications. Due to the high anionic charge density of heparin, starPEG‐heparin hydrogels are known to reversibly immobilise several GFs and thereby might mimic the GF reservoir of the extra cellular matrix. Thus, transport processes of GFs with low and high heparin affinity inside these hydrogels were analysed by fluorescence correlation spectroscopy and a bulk diffusion approach. Results indicated that diffusion constants were synergistically decreased with increasing size and heparin affinity of the diffusant. Next, the capability of endothelial cells (ECs) to self‐assemble and organise into 3D capillary networks was tested in GelMA, starPEG‐heparin and Matrigel hydrogels. Only starPEG‐heparin hydrogels allowed the formation of interconnected capillaries in macroscopic hydrogel samples. However, as it is widely used to test for pro‐ and anti‐angiogenic agents, the 2D Matrigel angiogenesis assay was included for subsequent co‐culture experiments of ECs and fibroblasts in order to investigate how the stromal cells influence the formation of endothelial networks. For a detailed characterisation of 3D structures, a conventionally applied 2D method (Maximum Intensity Projection for 3D reconstructed images, MIP) was compared to an optimised 3D analysing tool. As a result, it was discovered that MIP analysis did not allow for an accurate determination of 3D endothelial network parameters, and can result in misleading interpretations of the data set. Indirect co‐cultures of hydrogel‐embedded ECs with a 2D layer of fibroblasts showed that fibroblast‐derived soluble factors, including stromal cell‐derived factor 1 and interleukin 8, affected endothelial network properties. However, only co‐encapsulation of ECs and fibroblasts in starPEG‐heparin hydrogel discs revealed remarkable changes in endothelial network parameters between CAF and NPF samples. In detail, the total length and branching of the capillaries was increased. For two donor pairs, the diameter of capillaries was decreased in CAF samples compared to NPF samples, underlining the high physiological relevance of this model. In contrast, significant differences in 2D Matrigel assays were not detected between, CAF, NPF and control (ECs only) samples. In summary, a 3D angiogenesis co‐culture system was successfully developed and used to characterise stromal‐endothelial interactions in detail. The combination of advanced biomaterials (starPEG‐heparin) and 3D analysing techniques goes beyond conventional 2D in vitro cancer research, and opens new avenues for the development of more complex models to further improve the acquisition of more biologically relevant data.

Tumor-Stroma

Prostatakarzinom

3D Zellkultur

Angiogenese Assays

3D Analyse

Diffusion in Hydrogelen

Tumour Stroma

Prostate Cancer

3D Cell Culture

Angiogenesis Assays

3D Analysis

Diffusion in Hydrogels

ddc:570

rvk:XH 8000

Étude de la diffusion dans les hydrogels polymères par spectroscopie et imagerie RMN

Thérien-Aubin, Héloïse

January 2007

Thèse numérisée par la Division de la gestion de documents et des archives de l'Université de Montréal.

Diffusion

Auto-diffusion

Imagerie RMN

Hydrogels

Amidon

Relargage de principes actifs

Comprimés pharmaceutiques