Browsing by Subject "hydrogel"

In the past few years, there has been an increased consideration on the stem cell niche as a key factor to regulate stem cell maintenance and differentiation. Research on characterization of the stem cell microenvironment boosted after the determination of long-term three-dimensional (3D) tissue cultures, or so-called organoids. Organoids are derived from stem cells which self-organize in 3D multicellular structures upon embedding in an extracellular matrix mimic, such as Matrigel®. Their main advantage is these structures resemble the architectural distribution of the tissue of origin in vivo. Likewise, the cellular components of organoids vary depending on multiple variables as the tissue of origin and the growth factors they have access to. As a result of advances in this technique, some stem cell niches have been well characterized, as in the case of intestinal stem cells (ISCs), while others remain elusive as in case of the human gastric stem cells (hGSCs). Along with the remarkable development of 3D cultures, the interest of ECM proteins in stem cell regulation increased. Matrigel® is a rich matrix composed of several adhesive proteins such as laminins and collagens. Aside from providing structural support, the extracellular matrix (ECM) proteins forming this matrix contribute to cell adhesion and signalling. However, Matrigel® composition cannot be modified or even well-characterized due to its origin from Engelbreth-Holm-Swarm (EHS) mouse sarcoma cells. Additionally, it has been demonstrated that contains a high batch-to-batch variability. Other techniques to study the effects of individual ECM proteins have been used such as coating of tissue culture plates with ECM proteins. However, the biomechanical properties in this model are far from being physiological. Therefore, although preliminary results can be obtained using this technique, results extrapolation to an in vivo model can be questioned. To date, there is a lack of a reproducible, high-throughput and reliable technique to test the effect of ECM proteins on human gastric stem cells behavior. This Master’s thesis presents a novel transwell device containing a polyethylene glycol (PEG)-based hydrogel enriched with human ECM proteins to test their effect on human gastric stem cell regulation. Preliminary results showed that gastric organoid-derived epithelial cells (GODE) grown on hydrogels with ECM proteins that are localized at base of the gastric glands, such as Laminin-211, had a higher stem cell marker expression than the control grown on ECM proteins that are uniformly localized in vivo. Additionally, when GODE were grown on hydrogels containing ECM proteins that are localized at the surface of the native gastric epithelium, expression of surface gastric mucins markers was enhanced. These preliminary results highlight the utility of the optimized transwell device to further shed light on how the human gastric stem cells are regulated and what is the effect of the ECM proteins surrounding them.

Despite the advances in the management of breast cancer, discovery of novel and targeted drugs remains a challenge. It has been suggested that drug failure rates in clinical trials might be diminished by improving the predictive potential of preclinical cancer models. Three-dimensional (3D) scaffold-based cell culture has emerged as an attractive platform for mimicking tissue-like microenvironment, since it is well-known that cells respond to the cues in the extracellular matrix (ECM). The aim of this thesis was to develop fibrin-based hydrogels and evaluate their performance in 3D cell culture of breast cancer cells. The fibrin gel formulation was first optimized by testing the effect of different buffers on gel properties. Structural properties were examined with scanning electron microscopy and mechanical properties measured with oscillatory rheometry. Three different fibrin concentrations of the optimized formulation were then used as scaffolds for DU4475 breast cancer cells. After seven days of culture, the morphology, phenotype and proliferation of the resulting cell structures were assessed by using techniques such as light microscopy, immunofluorescent confocal microscopy and Western blot analysis. The desired properties for 3D cell culture were obtained by preparing fibrin gels at high pH in the absence of calcium. The main finding of the thesis was that fibrin concentration strongly affected the phenotype of DU4475 cells, with cells cultured in the softest gel retaining their original characteristics to the greatest extent. In the future, the developed scaffold could possibly be used in drug discovery and personalized medicine by culturing tumor explants from patients. However, the methods used in the study must be further optimized and the results validated with other breast cancer cell lines and with primary tissues.

Crohn's disease is a type of inflammatory bowel disease. There are no treatment procedures that can cure Crohn's disease, but it is usually controllable with medicinal options. However 70 - 80 % of patients will require surgery and most undergo several during their life, due to weak local potency of drugs and disrupted recovery from surgical treatment. A better method of combined treatment, such as a drug releasing surgical suture, could improve the disease recovery process. One approach would be to coat a surgical suture with nanofibrillar cellulose (NFC) hydrogel containing the active drug ingredient within. NFC is biocompatible, biostable and it can be easily chemically modified. It displays pseudoplastic and thixotropic gel-like behavior in aqueous suspension in addition to high shear thinning properties under low and high shear rates. The shear-thinning behavior is particularly useful in a range of different coating applications. Furthermore, recent studies have shown the potential of NFC in controlled drug release. The aim of this Master's thesis was to investigate the suitability of anionic NFC hydrogel for surgical suture coatings and controlled release applications. The structure of NFC hydrogel was modified with crosslinking cations (Fe3+, Al3+, Ca2+) and alginate. The diffusion studies were performed with two antibiotics, metronidazole and rifaximin together with FITC-dextrans (10 and 250 kDa). The surgical suture was coated with each type of hydrogels (n = 16). Furthermore, the suitability of suture drug formulation for controlled drug release was simulated with STELLA® modeling software. It was shown that the NFC hydrogel structure was stiffened with the use of crosslinking cations; however similar results were not observed with the addition of alginate. Release profiles of model compounds were similar before and after NFC hydrogel crosslinking. At 6 days, 50 - 60 % of 10 kDa dextran (6 µg) was released. For 250 kDa dextran (6 µg) the released amount was 25 - 35 %. During the first 3 days of the diffusion study, all of metronidazole (20 µg) was released. Rifaximin samples were not obtained due to high adsorption to the container surfaces. The release profiles of metronidazole and 10 kDa dextran had linear correlation with square-root diffusion process. 250 kDa dextran followed a near zero-order kinetics after a few hours from the start. The coating was performed successfully with NFC hydrogels except for hydrogels with dextrans or without crosslinking. Metronidazole was predicted to release from the surgical suture almost instantly with STELLA® modeling software. NFC hydrogel shows potential as a matrix for controlled drug release and the coating of surgical sutures. However, the manufacturing method of the NFC hydrogel could be improved with surface modifications of nanofibrils or with the choice of a drug or of its derivatives. With pharmacokinetic simulation models it is possible to predict and estimate different factors which affect drug release from the surgical suture. Furthermore, the simulation models can be used to estimate an effect in the treatment of Crohn's disease.

Aerogels are lightweight, porous and dry foams that are produced from gels by replacing the liquid phase by air. When produced from polysaccharide-based hydrogels, potential applications for aerogels could be found as bio-based packaging materials. The literature review focused on the production of polysaccharide-based hydrogels and their chemical crosslinking, as well as the production of aerogels and their properties. In the experimental study the possibilities for utilization of spruce galactoglucomannan (GGM), an abundant but largely unexploited raw material, as aerogel matrix was explored. Nanofibrillated cellulose (NFC) was used as reinforcement and the polysaccharides were crosslinked with ammonium zirconium carbonate (AZC). Hydrogels were prepared from GGM-NFC-suspensions and heat treatment was performed in order to induce crosslinking reaction. Prepared hydrogels were frozen in a bath of carbon dioxide ice and ethanol and subsequently freeze-dried into cubic aerogels. The aim was to investigate the effect of polysaccharide proportions and AZC content on the strength of hydrogels and on the mechanical properties and moisture sensitivity of aerogels. The formation of crosslinks was observed indirectly from the values of storage and loss moduli by dynamic rheological measurement. The strength of hydrogels was highly dependent on the AZC and NFC content. In contrast, the compressive modulus of aerogels instead was affected only by NFC content at relative humidity (RH) of 50% and 23 °C. Hydrogel strength could not be used for prediction of aerogel strength under these ambient conditions. AZC and NFC mainly decreased the sensitivity of aerogels towards moisture by decreasing the water absorption and its plasticizing effect on aerogels. The effect of crosslinking on mechanical and physical properties of aerogels appeared clearly at RH over 50%. GGM was shown to be a suitable aero-gel raw material when combined with NFC. The role of NFC in enhancing the aerogel’s me-chanical properties was significant. The mechanical properties of uncrosslinked aerogels, how-ever, weakened in a humid environment. In particular, AZC is needed to protect aerogels from the plastizicing effect of water. Properties of crosslinked aerogels in a humid environment would be an interesting subject of further studies.