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2D and 3D applications of polymeric biomaterialsVenturato, Andrea January 2018 (has links)
The field of biomaterials has seen huge development over the past decade with enormous efforts invested in discovering materials with improved biocompatibility, application and versatility. Polymers can display many properties that make them ideal biomaterials, such as their potential flexibility, low weight, low cost and biodegradability. Moreover, they can be prepared in a wide variety of compositions and forms and be readily fabricated into various shapes and structures. Polymer microarrays represent an efficient high-throughput platform for the screening and discovery of new materials compared to conventional assays with advantages such as high-density screening, internal consistency of assays and the requirement for only small quantities of material. The first part of this thesis describes work in the area of diabetes research with a focus on how dysfunctional β-cells could be replaced by the transplantation of β-cells obtained from pluripotent stem cells. To achieve this aim, high numbers of β-cells are required. A polymer microarray screening approach was used to identify a number of polymers that promoted the attachment of pancreatic progenitor cells and enhanced cell proliferation. Multiple scale-up fabrication techniques were assessed to establish the most suitable approach and surface for long term cell culture leading to the obtainment of reproducible in situ polymerised polymer layers with enhanced binding properties toward pancreatic progenitor cells. These surfaces have the potential to support cell adhesion and proliferation and could find potential use in the industrial sector to increase the production of pancreatic progenitor cells in vitro. In the second part, efforts were made to gain a better understanding of the maturation of β-cells and their behaviour, with the development of 3D hydrogels based on the previously identified polymers. In this scenario, parameters such as stiffness and porosity were evaluated to identify the best environmental conditions to support 3D cell culturing of pancreatic progenitor cells. Several approaches were tested to generate scaffolds with suitable stiffness and porosity leading to the obtainment of scaffolds based on the previously identified polymer composition and with controlled porosity and stiffness. These scaffolds could represent a suitable environment to allow a better understanding of cell organisation and regulation. In a third avenue of work, arrays of 3D biocompatible materials, which were tailored for varying elasticity, hardness, and porosity (to provide the necessary physical cues to control cellular functions) were fabricated. In this chapter, details of the development of an array of eighty 3D double-network hydrogel features are reported. The array features can be produced as single or double networks and modulated in terms of stiffness, viscoelasticity and porosity to assess cell response to materials with a wide range of properties. The final part of the thesis describes the development and screening of polymeric materials to allow a better understanding of cell–surface interactions with various cell types. To investigate the correlation between cell attachment and the nature of the polymer, a series of random and block copolymers were synthesised and examined for their abilities to attach and support the growth of human cervical cancer cells (HeLa) and human embryonic kidney cells (HEK293T), with attachment modelled on monomer ratios, arrangement, and polymer chain length. The results of this screening showed differences between block copolymers and random copolymers in cell adhesion and provide interesting insight into the improvement of polymer coatings for cell culture.
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Dynamic Mechanical Regulation of Cells in 3D MicrotissuesWalker, Matthew 27 May 2020 (has links)
It has been well established that the fundamental behaviors of mammalian cells are influenced by the physical cues that they experience from their surrounding environment. With respect to cells in our bodies, mechanically-driven morphological and phenotypic changes to our cells have been linked to responses critical to both normal development and disease progression, including lung, heart, muscle and bone disorders, and cancer. Although significant advancements to our understanding of cell behavior have been made using 2D cell culture methods, questions regarding how physical stretch guides cell behavior in more complex 3D biological systems remain unanswered. To address these questions, we used microfabrication techniques to develop vacuum-actuated stretchers for high throughput stretching and dynamic mechanical screening of 3D microtissue cultures. This thesis contains five research chapters that have utilized these devices to advance our understanding of how cells feel stretch and how it influences their behavior in a 3D matrix. In the first research chapter (chapter 2), we characterized how stretch is transferred from the tissue-level to the single-cell level and we investigated the cytoskeletal reinforcement response to long-term mechanical conditioning. In the second research chapter (chapter 3), we examined the effects of an acute dynamic stretch and found that 3D cultures soften through actin depolymerization to homeostatically maintain a mean tension. This softening response to stretch may lengthen tissues in our body, and thus may be an important mechanism by which airway resistance and arterial blood pressure are controlled. In the third and forth research chapters (chapter 4-5), we investigated the time dependencies of microtissues cultures and we found that their behavior differed from our knowledge of the rheological behavior of cells in 2D culture. Microtissues instead followed a stretched exponential model that seemed to be set by a dynamic equilibrium between cytoskeletal assembly and disassembly rates. The difference in the behavior from cells in 2D may reflect the profound changes to the structure and distribution of the cytoskeleton that occur when cells are grown on flat surfaces vs. within a 3D environment. In the fifth and final research chapter (chapter 6), we examined how mechanical forces may contribute to the progression of tissue fibrosis through activating latent TGF-β1. Our results suggest that mechanical stretch contributes to a feed forward loop that preserves a myofibroblastic phenotype. Together these investigations further our understanding of how cells respond to mechanical stimuli within 3D environments, and thus, mark a significant contribution to the fields of mechanobiology and cell mechanics.
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Influence of 3D tumor cell/fibroblast co-culture on monocyte differentiation and tumor progression in pancreatic cancer / Einfluss von 3D Tumorzell/Fibroblasten Ko-kulturen auf die Monozyten Differenzierung und das Tumorwachstum bei BauchspeicheldrüsenkrebsKuen, Janina January 2017 (has links) (PDF)
Pancreatic cancer (PC) remains one of the most challenging solid tumors to treat with a high unmet medical need as patients poorly respond to standard-of-care-therapies. Prominent desmoplastic reaction involving cancer-associated fibroblasts (CAFs) and the immune cells in the tumor microenvironment (TME) and their cross-talk play a significant role in tumor immune escape and progression. To identify the key cellular mechanisms induce an immunosuppressive tumor microenvironment, we established 3D co-culture model with pancreatic cancer cells, CAFs, monocyte as well as T cells.
Using this model, we analysed the influence of tumor cells and fibroblasts on monocytes and their immune suppressive phenotype. Phenotypic characterization of the monocytes after 3D co-culture with tumor/fibroblast spheroids was performed by analysing the expression of defined cell surface markers and soluble factors. Functionality of these monocytes and their ability to influence T cell phenotype and proliferation was investigated.
3D co-culture of monocytes with pancreatic cancer cells and fibroblasts induced the production of immunosuppressive cytokines which are known to promote polarization of M2 like macrophages and myeloid derived suppressive cells (MDSCs). These co-culture spheroid polarized monocyte derived macrophages (MDMs) were poorly differentiated and had an M2 phenotype. The immunosuppressive function of these co-culture spheroids polarized MDMs was demonstrated by their ability to inhibit autologous CD4+ and CD8+ T cell activation and proliferation in vitro, which we could partially reverse by 3D co-culture spheroid treatment with therapeutic molecules that are able to re-activate spheroid polarized MDMs or block immune suppressive factors such as Arginase-I.
In conclusion, we generated a physiologically relevant 3D co-culture model, which can be used as a promising tool to study complex cell-cell interactions between different cell types within the tumor microenvironment and to support drug screening and development. In future, research focused on better understanding of resistance mechanisms to existing cancer immunotherapies will help to develop new therapeutic strategies in order to combat cancer. / Bei Bauchspeicheldrüsenkrebs handelt es sich um eine maligne Tumorerkrankung, deren Behandlung Ärzte noch immer vor große Herausforderungen stellen und die zur dritthäufigsten krebsbedingten Todesursache der westlichen Welt zählt. Desmoplastische Reaktionen im Tumorgewebe sind hierbei ein besonderes Merkmal dieser Erkrankung. Dabei spielen tumor-assoziierte Fibroblasten sowie unterschiedliche Zellen des Immunsystems und deren Interaktionen eine essentielle Rolle hinsichtlich Tumorwachstum und der Herunterregulation des Immunsystems. Um zelluläre Mechanismen, die ein immunsuppressives Tumormilieu induzieren, zu identifizieren, entwickelten wir ein 3D Ko-Kultur Modell mit Bauchspeicheldrüsenkrebszellen, tumor-assoziierten Fibroblasten sowie Monozyten und T-Zellen.
Mit Hilfe dieses Modells konnten wir den Einfluss von Tumorzellen und Fibroblasten auf den Phänotyp und das Verhalten von Monozyten untersuchen. Dazu wurden Monozyten in einer 3D Tumorzell/Fibroblasten Ko-Kultur kultiviert und differenziert, um anschließend die Expression definierter Zelloberflächenmarker und löslicher Faktoren zu analysieren. Des Weiteren wurde das Verhalten dieser 3D Ko-Kultur differenzierten myeloiden Zellpopulation sowie ihre Fähigkeit den Phänotyp von T Zellen und deren Proliferation zu beeinflussen untersucht.
Die 3D Ko-Kultur der Monozyten zusammen mit den Tumorzellen und den Fibroblasten führten zur Produktion immunsuppressiver Zytokine und Chemokine, wodurch die Differenzierung der Monozyten in M2-ähnliche Makrophagen induziert wurde. Diese durch die 3D Tumorzell/Fibroblasten Sphäroide polarisierten aus Monozyten herangereiften M2-ähnlichen Makrophagen besaßen außerdem immunsuppressive funktionelle Eigenschaften, indem sie in der Lage waren, die Aktivierung und Proliferation von autologen CD4+ und CD8+ T Zellen in vitro zu inhibieren. Die Suppression sowohl der CD4+ als auch der CD8+ T Zellen konnte durch die Behandlung therapeutischer Moleküle, die die Re-Aktivierung der immunsuppressiven 3D Sphäroid polarisierten Makrophagen stimulierten oder suppressive Faktoren wie Arginase-I blockierten, wieder aufgehoben und die T Zell Proliferation teilweise wiederhergestellt werden.
Unser etabliertes 3D Ko-Kultur System repräsentiert ein vielversprechendes physiologisch relevantes Modell, welches genutzt werden kann, um Zell-Zell Interaktion und Kommunikation im Tumormilieu zu untersuchen und dadurch die Wirkung von Medikamenten zu verbessern. Ein gezieltes besseres Verständnis von Tumorresistenz Mechanismen gegen bereits bestehende Immun Therapien fördert die Entwicklung neuer therapeutischer Ansätze zur Bekämpfung von Krebs.
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Hyaluronic Acid Hydrogel as a Scaffold for Cells’ EncapsulationWärmegård, Susanna January 2022 (has links)
Hydrogels are high water-content polymers that mimic the extracellular matrix of cells. The polymers can have many sources and be of natural origin from the extracellular matrix (ECM) of cells or be synthetically derived. Two such polymers are hyaluronic acid and gelatin, which can with the help of the release of free radicals from photoinitiators, initiated by UV light, polymerise, and form a hydrogel. In these hydrogels, cells can be encapsulated. The hydrogels can in turn be used to maintain cells as they are in the natural environment. For example, hydrogels can provide an in-vivo-like ECM for stem cells and endothelial cells by supporting “stemness” and cell-to-cell contact; respectively. We aim to establish a protocol for culturing cells in the hydrogelas a first milestone in a project focused on profiling the metabolome of cells grown in hydrogels. To accomplish this, four types of cells, namely mouse brain microvascular endothelial cells (bEnd.3), human umbilical vein endothelial cells (HUVECs), adult human lung fibroblast (hLFs) and mesenchymal stem cells (MSCs), were evaluated for growth in hyaluronic acid methacrylate (HA-ma), hyaluronic acid acrylamide (HA-am) as well as a QuattroGel composed by gelatin methacryloyl (GelMA), HA-ma, fibrinogen and thrombin. It was found that HA-masupported viability and the stemness of mesenchymal stem cells, of which the metabolome can be further studied in order to evaluate the difference between regular 2D maintenance and maintenance in 3D. No sprouting was observed for the other cells encapsulated in the hydrogel, and further experiments are needed to find the source of error.
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Generation of Hybrid Peptide-Silver Nanoparticles for Antibacterial and Antifouling ApplicationsSeferji, Kholoud 05 1900 (has links)
An alarming increase of antibiotic-resistant bacterial strains has made the demand for novel antibacterial agents, for example, more effective antibiotics, highly crucial. One of the oldest antimicrobial agents is elementary silver which has been used for thousands of years. Even in our days, elementary silver is used for medical purposes, such as for burns, wounds, and microbial infections. We have taken the effectiveness of elementary silver into consideration to generate novel antibacterial and antifouling agents. Our innovative antibacterial agents are hybrid peptide silver nanoparticles (CH-01-AgNPs) that are created de novo and in situ from a silver nitrate solution (AgNO3) in the presence of ultrashort self-assembling peptides compounds. The nucleation of CH-01-AgNPs is initiated by irradiating the peptide solution mixed with the AgNO3 solution using ultraviolet (UV) light at a wavelength of 254 nm, in the absence of any reducing or capping agents. Obviously, the peptide itself serves as the reducing agent. The ultrashort peptides are four amino acids in length with an innate ability to self-assemble into nanofibrous scaffolds. Using these ultrashort peptides CH-01 we were able to create hybrid peptide silver nanoparticles CH-01-AgNPs with a diameter of 4-6 nm. The synthesized CH-01-AgNPs were further characterized using ultraviolet-visible spectroscopy, transmission electron microscopy, dynamic light scattering, and X-ray photoelectron spectroscopy. The antibacterial and antifouling activity of CH-01-AgNPs were then investigated using either gram-negative bacteria, such as antibiotic-resistant Top10 Escherichia coli and Pseudomonas aeruginosa PDO300, or gram-positive bacteria, such as Staphylococcus aureus CECT 976. The hybrid nanoparticles demonstrated very promising antibacterial and antifouling activity with higher antibacterial and antifouling activity as commercial silver nanoparticles. Quantitative Polymerase Chain Reaction (qPCR) results showed upregulation of stress-related genes, e.g. osmB and bdm. Biocompatibility studies of CH-01-AgNPs, using concentrations of 0.06 mM and 0.125 mM, testing for the viability of human dermal fibroblast neonatal (HDFn) cells, showed no significant influence on cell viability. In summary, we consider hybrid peptide silver nanoparticles CH-01-AgNPs as promising biomaterials that can be utilized in various biomedical applications, in particular for wound healing and biofilm inhibition, but also for other applications, such as tissue engineering, drug delivery, regenerative medicine, and biosensing.
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Hydrogels with Dynamic Biochemical Environment for 3D Cell CultureNijsure, Devang January 2018 (has links)
The in vivo 3D extracellular matrix provides a temporal regulatory environment
of chemical cues. Understanding this dynamic environment will be crucial for efficient
drug screening, diseases mechanism elucidation, and tissue engineering. Therefore, in
vitro 3D cell culture systems with reversible chemical environments are required. To this
end, we developed a non-cytotoxic agarose-desthiobiotin hydrogel to sequester
streptavidin biomolecule conjugates (KD 10-11 M), which can then be displaced by the
addition of biotin (KD 10-15 M). Streptavidin biomolecule conjugates were simultaneously
and sequentially immobilized by changing media components. The time required for
biochemical environment exchange was minimized by increasing the surface area to
volume ratios and pore size of the hydrogels. We temporally controlled the cell adhesive
properties of hydrogels with RGD modified streptavidin to influence endothelial cell tube
formation. / Thesis / Master of Science (MSc)
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Comparison of biophysical properties characterized for microtissues cultured using microencapsulation and liquid crystal based 3D cell culture techniquesSoon, C.F., Tee, K.S., Wong, S.C., Nayan, N., Sundra, S., Ahmad, M.K., Sefat, Farshid, Sultana, N., Youseffi, Mansour 30 November 2017 (has links)
No / Growing three dimensional (3D) cells is an emerging research in tissue engineering. Biophysical properties of the 3D cells regulate the cells growth, drug diffusion dynamics and gene expressions. Scaffold based or scaffoldless techniques for 3D cell cultures are rarely being compared in terms of the physical features of the microtissues produced. The biophysical properties of the microtissues cultured using scaffold based microencapsulation by flicking and scaffoldless liquid crystal (LC) based techniques were characterized. Flicking technique produced high yield and highly reproducible microtissues of keratinocyte cell lines in alginate microcapsules at approximately 350 ± 12 pieces per culture. However, microtissues grown on the LC substrates yielded at lower quantity of 58 ± 21 pieces per culture. The sizes of the microtissues produced using alginate microcapsules and LC substrates were 250 ± 25 μm and 141 ± 70 μm, respectively. In both techniques, cells remodeled into microtissues via different growth phases and showed good integrity of cells in field-emission scanning microscopy (FE-SEM). Microencapsulation packed the cells in alginate scaffolds of polysaccharides with limited spaces for motility. Whereas, LC substrates allowed the cells to migrate and self-stacking into multilayered structures as revealed by the nuclei stainings. The cells cultured using both techniques were found viable based on the live and dead cell stainings. Stained histological sections showed that both techniques produced cell models that closely replicate the intrinsic physiological conditions. Alginate microcapsulation and LC based techniques produced microtissues containing similar bio-macromolecules but they did not alter the main absorption bands of microtissues as revealed by the Fourier transform infrared spectroscopy. Cell growth, structural organization, morphology and surface structures for 3D microtissues cultured using both techniques appeared to be different and might be suitable for different applications. / (Science Fund Vot No.: 0201-01-13-SF0104 or S024) awarded by Malaysia Ministry of Science and Technology (MOSTI) and IGSP Grant Vot No. U679 awarded by Universiti Tun Hussein Onn Malaysia.
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High-Frequency Irreversible Electroporation (H-FIRE) optimization for the treatment of highly invasive cells beyond the tumor marginLatouche, Eduardo L. 19 June 2016 (has links)
Irreversible electroporation (IRE) is a non-thermal ablation technique that allows for eradication of unresectable tumors in a minimally invasive procedure. While IRE will preferentially kill larger cells over smaller ones, it does not discriminate between cells with larger and small nuclei. Given that one of the hallmarks of cancer cell morphology is larger, more abundant nuclei, our team set out to explore the possibility of preferentially targeting this physical and geometrical characteristic. / Master of Science
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Collective Migration Models: Dynamic Monitoring of Leader Cells in Migratory/Invasive Disease ProcessesDean, Zachary S. January 2015 (has links)
Leader cells are a fundamental biological process that have only been investigated since the early 2000s. These cells have often been observed emerging at the edge of an artificial wound in 2D epithelial cell collective invasion, created with either a mechanical scrape from a pipette tip or from the removal of a plastic, physical blocker. During migration, the moving cells maintain cell-cell contacts, an important quality of collective migration; the leader cells originate from either the first or the second row, they increase in size compared to other cells, and they establish ruffled lamellipodia. Recent studies in 3D have also shown that cells emerging from an invading collective group that also exhibit leader-like properties. Exactly how leader cells influence and interact with follower cells as well as other cells types during collective migration, however, is another matter, and is a subject of intense investigation between many different labs and researchers. The majority of leader cell research to date has involved epithelial cells, but as collective migration is implicated in many different pathogenic diseases, such as cancer and wound healing, a better understanding of leader cells in many cell types and environments will allow significant improvement to therapies and treatments for a wide variety of disease processes. In fact, more recent studies on collective migration and invasion have broadened the field to include other cell types, including mesenchymal cancer cells and fibroblasts. However, the proper technology for picking out dynamic, single cells within a moving and changing cell population over time has severely limited previous investigation into leader cell formation and influence over other cells. In line with these previous studies, we not only bring new technology capable of dynamically monitoring leader cell formation, but we propose that leader cell behavior is more than just an epithelial process, and that it is a critical physiological process in multiple cell types and diseases.
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SELF-ASSEMBLY OF SILK-ELASTINLIKE PROTEIN POLYMERS INTO THREE-DIMENSIONAL SCAFFOLDS FOR BIOMEDICAL APPLICATIONSZeng, Like January 2014 (has links)
Production of brand new protein-based materials with precise control over the amino acid sequences at single residue level has been made possible by genetic engineering, through which artificial genes can be developed that encode protein-based materials with desired features. As an example, silk-elastinlike protein polymers (SELPs), composed of tandem repeats of amino acid sequence motifs from Bombyx mori (silkworm) silk and mammalian elastin, have been produced in this approach. SELPs have been studied extensively in the past two decades, however, the fundamental mechanism governing the self-assembly process to date still remains largely unresolved. Further, regardless of the unprecedented success when exploited in areas including drug delivery, gene therapy, and tissue augmentation, SELPs scaffolds as a three-dimensional cell culture model system are complicated by the inability of SELPs to provide the embedded tissue cells with appropriate biochemical stimuli essential for cell survival and function. In this dissertation, it is reported that the self-assembly of silk-elastinlike protein polymers (SELPs) into nanofibers in aqueous solutions can be modulated by tuning the curing temperature, the size of the silk blocks, and the charge of the elastin blocks. A core-sheath model was proposed for nanofiber formation, with the silk blocks in the cores and the hydrated elastin blocks in the sheaths. The folding of the silk blocks into stable cores - affected by the size of the silk blocks and the charge of the elastin blocks - plays a critical role in the assembly of silk-elastin nanofibers. The assembled nanofibers further form nanofiber clusters on the microscale, and the nanofiber clusters then coalesce into nanofiber micro-assemblies, interconnection of which eventually leads to the formation of three-dimensional scaffolds with distinct nanoscale and microscale features. SELP-Collagen hybrid scaffolds were also fabricated to enable independent control over the scaffolds' biochemical input and matrix stiffness. It is reported herein that in the hybrid scaffolds, collagen provides essential biochemical cues needed to promote cell attachment and function while SELP imparts matrix stiffness tunability. To obtain tissue-specificity in matrix stiffness that spans over several orders of magnitude covering from soft brain to stiff cartilage, the hybrid SELP-Collagen scaffolds were crosslinked by transglutaminase at physiological conditions compatible for simultaneous cell encapsulation. The effect of the increase in matrix stiffness induced by such enzymatic crosslinking on cellular viability and proliferation was also evaluated using in vitro cell assays.
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