Biomimetic Poly(ethylene glycol)-based Hydrogels as a 3D Tumor Model for Evaluation of Tumor Stromal Cell and Matrix Influences on Tissue Vascularization

Ali, Saniya

January 2015

<p>To this day, cancer remains the leading cause of mortality worldwide1. A major contributor to cancer progression and metastasis is tumor angiogenesis. The formation of blood vessels around a tumor is facilitated by the complex interplay between cells in the tumor stroma and the surrounding microenvironment. Understanding this interplay and its dynamic interactions is crucial to identify promising targets for cancer therapy. Current methods in cancer research involve the use of two-dimensional (2D) monolayer cell culture. However, cell-cell and cell-ECM interactions that are important in vascularization and the three-dimensional (3D) tumor microenvironment cannot accurately be recapitulated in 2D. To obtain more biologically relevant information, it is essential to mimic the tumor microenvironment in a 3D culture system. To this end, we demonstrate the utility of poly(ethylene glycol) diacrylate (PEGDA) hydrogels modified for cell-mediated degradability and cell-adhesion to explore, in 3D, the effect of various tumor microenvironmental features such as cell-cell and cell-ECM interactions, and dimensionality on tumor vascularization and cancer cell phenotype. </p><p>In aim 1, PEG hydrogels were utilized to evaluate the effect of cells in the tumor stroma, specifically cancer associated fibroblasts (CAFs), on endothelial cells (ECs) and tumor vascularization. CAFs comprise a majority of the cells in the tumor stroma and secrete factors that may influence other cells in the vicinity such as ECs to promote the organization and formation of blood vessels. To investigate this theory, CAFs were isolated from tumors and co-cultured with HUVECs in PEG hydrogels. CAFs co-cultured with ECs organized into vessel-like structures as early as 7 days and were different in vessel morphology and density from co-cultures with normal lung fibroblasts. In contrast to normal lung fibroblasts (LF), CAFs and ECs organized into vessel-like networks that were structurally similar to vessels found in tumors. This work provides insight on the complex crosstalk between cells in the tumor stroma and their effect on tumor angiogenesis. Controlling this complex crosstalk can provide means for developing new therapies to treat cancer.</p><p>In aim 2, degradable PEG hydrogels were utilized to explore how extracellular matrix derived peptides modulate vessel formation and angiogenesis. Specifically, integrin-binding motifs derived from laminin such as IKVAV, a peptide derived from the α-chain of laminin and YIGSR, a peptide found in a cysteine-rich site of the laminin β chain, were examined along with RGDS. These peptides were conjugated to heterobifunctional PEG chains and covalently incorporated in hydrogels. The EC tubule formation in vitro and angiogenesis in vivo in response to the laminin-derived motifs were evaluated. </p><p>Based on these previous aims, in aim 3, PEG hydrogels were optimized to function as a 3D lung adenocarcinoma in vitro model with metastasis-prone lung tumor derived CAFs, HUVECs, and human lung adenocarcinoma derived A549 tumor cells. Similar to the complex tumor microenvironment consisting of interacting malignant and non-malignant cells, the PEG-based 3D lung adenocarcinoma model consists of both tumor and stromal cells that interact together to support vessel formation and tumor cell proliferation thereby more closely mimicking the functional properties of the tumor microenvironment. The utility of the PEG-based 3D lung adenocarcinoma model as a cancer drug screening platform is demonstrated with investigating the effects of doxorubicin, semaxanib, and cilengitide on cell apoptosis and proliferation. The results from drug screening studies using the PEG-based 3D in vitro lung adenocarcinoma model correlate with results reported from drug screening studies conducted in vivo. Thus, the PEG-based 3D in vitro lung adenocarcinoma model may serve as a better tool for identifying promising drug candidates than the conventional 2D monolayer culture method.</p> / Dissertation

Biomedical engineering

3D Scaffold

Cancer Associated Fibroblasts

ECM

Tissue Engineering

Tumor Angiogenesis

Tumor Microenvironment

Compliant 3D Hydrogel Bead Scaffolds to Study Cell Migration and Mechanosensitivity in vitro

Wagner, Katrin

19 January 2019

Gewebe sind nicht nur durch ihre biochemische Zusammensetzung definiert, sondern auch durch ihre individuellen mechanischen Eigenschaften. Inzwischen ist es weithin akzeptiert, dass Zellen ihre mechanische Umgebung spüren und darauf reagieren. Zum Beispiel werden Zellmigration und die Differenzierung von Stammzellen durch die Umgebungssteifigkeit beeinflusst. Um diese Effekte in vitro zu untersuchen, wurden viele Zellkulturstudien auf 2D Hydrogelsubstraten durchgeführt. Zusätzlich dazu steigt die Anzahl von Studien an, die hydrogelbasierte 3D-Scaffolds nutzen, um 2D Studien zu validieren und die experimentellen Bedingungen der Situation in vivo anzunähern. Jedoch erweist es sich weiterhin als schwierig den Effekt von Mechanik in 3D in vitro zu untersuchen, da in den gemeinhin genutzten 3D Hydrogelsystemen immer eine Kopplung zwischen Gelporosität und Steifigkeit besteht. Zusätzlich hängt die Konzentration der biologisch aktiven Bindungsstellen für Zellen oft ebenfalls von der Steifigkeit ab. Diese Arbeit präsentiert die Entwicklung und Optimierung neuer 3D Hydrogelkugel-Scaffolds, in denen die Steifigkeit von der Porosität schließlich entkoppelt wird. Mit Hydrogelkugeln als Scaffold-Bausteine ist es nun möglich 3D Scaffolds mit definierten mechanischen Eigenschaften und konstanter Porengröße zu generieren. Während der Methodenentwicklung wurden verschiedene Prinzipien und Kultivierungskammern konstruiert und überarbeitet, gefolgt von der theoretischen Betrachtung der Sauerstoffdiffusion, um die Eignung der gewählten Kammer hinsichtlich Zellvitalität und Zellwachstum zu überprüfen. Eine Kombination aus mehreren getesteten Filtern wurde ausgewählt um HydrogelkugelScaffolds erfolgreich in der ausgewählten Kammer zu generieren. Im Weiteren wurden verschiedene Hydrogelmaterialien untersucht hinsichtlich der erfolgreichen Produktion monodisperser Hydrogelkugeln und der Erzeugung stabiler Scaffolds. Hydrogelkugeln aus Polyacrylamid (PAAm) wurden als Scaffold-Bausteine ausgewählt um damit die Eignung des entwickelten Systems zu demonstrieren lebende Zellen zu mikroskopieren. Außerdem wurde das Überleben von Fibroblasten über vier Tage in unterschiedlich steifen HydrogelkugelScaffolds erfolgreich gezeigt. Weiterhin war es möglich erste Zellmigrationsexperimente durchzuführen. Dafür wurden sowohl einfache PAAm-Hydrogelkugeln als auch mit Adhäsionsmolekülen funktionalisierte Hydrogelkugeln genutzt, um unterschiedlich steife Schichten in einem Scaffold zu erzeugen. Dadurch war es möglich nicht nur Zellmigration anhand von Zelladhäsion in 3D Scaffolds mit Steifigkeitsgradienten zu beobachten, sondern auch Zellmigration ohne Zelladhäsion.:1 Introduction 1.1 Mechanics play a role in biology 1.2 3D cultures and scaffolds 1.3 3D hydrogel systems to study effects of mechanics 1.4 Decoupling stiffness and porosity in 3D scaffolds 2 Materials 3 Methods 3.1 Laser scanning microscopy and microscopy data processing 3.2 Atomic force microscopy (AFM) 3.3 Refractive index matching of PMMA beads 3.4 Regular PMMA bead scaffolds for developing analysis algorithm 3.5 Cell culture standards 3.6 Fluorescent labelling of ULGP agarose 3.7 Production of polydisperse ULGP agarose beads 3.8 Hydrogel bead production via microfluidics 3.9 PAAm bead functionalization 3.10 Real-time fluorescence and deformability cytometry (RT-fDC) 3.11 3D scaffolds made from hydrogel beads 3.12 Statistics 4 Results 4.1 Design of a suitable scaffold device 4.2 Theoretical oxygen supply in 3D culture system is sufficient for cell survival and proliferation 4.3 Further optimization of 3D scaffold device 4.3.1 PMMA beads can be arranged in stable scaffolds 4.3.2 Regular PMMA bead scaffolds can be achieved and analysed 4.3.3 PMMA bead scaffolds and agarose bead scaffolds act as combined filter to stack up hydrogel beads 4.4 PAAm hydrogel beads produced by microfluidics are suitable to create compliant 3D scaffolds 4.5 Reproducible, regular and stable 3D scaffolds made of hydrogel beads 4.6 NIH-3T3/GFP cell migration within 3D hydrogel bead scaffolds 5 Discussion and Concluding Remarks 6 Bibliography List of Figures List of Tables Eigenständigkeitserklärung Appendix A Appendix B FIJI macro for FFT analysis maxima Python script to determine regularity of PMMA bead scaffolds Excel macro to determine number of peaks for regularity analysis / Tissues are defined not only by their biochemical composition, but also by their distinct mechanical properties. It is now widely accepted that cells sense their mechanical environment and respond to it. For example, cell migration and stem cell differentiation is affected by stiffness. To study these effects in vitro, many cell culture studies have been performed on 2D hydrogel substrates. Additionally, the amount of 3D studies based on hydrogels as 3D scaffold is increasing to validate 2D in vitro studies and adjust experimental conditions closer to the situation in vivo. However, studying the effects of mechanics in vitro in 3D is still challenging as commonly used 3D hydrogel assays always link gel porosity with stiffness. Additionally, the concentration of biologically active adhesion sides often also depends on the stiffness. This work presents the development and optimization of novel 3D hydrogel bead scaffolds where the stiffness is finally decoupled from porosity. With hydrogel beads as scaffold building blocks it was possible to generate 3D scaffolds with defined mechanical properties and a constant pore size. During the method development, different culture devices were constructed and revised, followed by oxygen diffusion simulations to proof the suitability of the chosen device for cell survival and growth. A combination of different filter approaches was selected to generate hydrogel bead scaffolds in the culture device. Furthermore, different hydrogel materials were investigated regarding successful production of monodisperse beads and stable scaffold generation. Polyacrylamide (PAAm) hydrogel beads were chosen as scaffold building blocks to demonstrate live-cell imaging and successful cell survival over four days in differently compliant hydrogel bead scaffolds. Moreover, first cell migration experiments were performed by using plain PAAm hydrogel beads as well as PAAm hydrogel beads functionalized with adhesion molecules with differently stiff layers in one scaffold. Thereby fibroblast migration was observed not only in adhesion-dependent migration manner, but also in an adhesion-independent mode .:1 Introduction 1.1 Mechanics play a role in biology 1.2 3D cultures and scaffolds 1.3 3D hydrogel systems to study effects of mechanics 1.4 Decoupling stiffness and porosity in 3D scaffolds 2 Materials 3 Methods 3.1 Laser scanning microscopy and microscopy data processing 3.2 Atomic force microscopy (AFM) 3.3 Refractive index matching of PMMA beads 3.4 Regular PMMA bead scaffolds for developing analysis algorithm 3.5 Cell culture standards 3.6 Fluorescent labelling of ULGP agarose 3.7 Production of polydisperse ULGP agarose beads 3.8 Hydrogel bead production via microfluidics 3.9 PAAm bead functionalization 3.10 Real-time fluorescence and deformability cytometry (RT-fDC) 3.11 3D scaffolds made from hydrogel beads 3.12 Statistics 4 Results 4.1 Design of a suitable scaffold device 4.2 Theoretical oxygen supply in 3D culture system is sufficient for cell survival and proliferation 4.3 Further optimization of 3D scaffold device 4.3.1 PMMA beads can be arranged in stable scaffolds 4.3.2 Regular PMMA bead scaffolds can be achieved and analysed 4.3.3 PMMA bead scaffolds and agarose bead scaffolds act as combined filter to stack up hydrogel beads 4.4 PAAm hydrogel beads produced by microfluidics are suitable to create compliant 3D scaffolds 4.5 Reproducible, regular and stable 3D scaffolds made of hydrogel beads 4.6 NIH-3T3/GFP cell migration within 3D hydrogel bead scaffolds 5 Discussion and Concluding Remarks 6 Bibliography List of Figures List of Tables Eigenständigkeitserklärung Appendix A Appendix B FIJI macro for FFT analysis maxima Python script to determine regularity of PMMA bead scaffolds Excel macro to determine number of peaks for regularity analysis

info:eu-repo/classification/ddc/620

ddc:620

3d Patterned Cardiac Tissue Construct Formation Using Biodegradable Materials

Kenar, Halime

01 December 2008

The heart does not regenerate new functional tissue when myocardium dies following coronary artery occlusion, or is defective. Ventricular restoration involves excising the infarct and replacing it with a cardiac patch to restore the heart to a more efficient condition. The goal of this study was to design and develop a myocardial patch to replace myocardial infarctions. A basic design was developed that is composed of 3D microfibrous mats that house mesenchymal stem cells (MSCs) from umbilical cord matrix (Wharton&rsquo / s Jelly) aligned parallel to each other, and biodegradable macroporous tubings to supply growth media into the structure. Poly(glycerol sebacate) (PGS) prepolimer was synthesized and blended with P(L-D,L)LA and/or PHBV, to produce aligned microfiber (dia 1.16 - 1.37 &amp / #956 / m) mats and macroporous tubings. Hydrophilicity and softness of the polymer blends were found to be improved as a result of PGS introduction. The Wharton&rsquo / s Jelly (WJ) MSCs were characterized by determination of their cell surface antigens with flow cytometry and by differentiating them into cells of mesodermal lineage (osteoblasts, adipocytes, chondrocytes). Cardiomyogenic differentiation potential of WJ MSCs in presence of differentiation factors was studied with RT-PCR and immunocytochemistry. WJ MSCs expressed cardiomyogenic transcription factors even in their undifferentiated state. Expression of a ventricular sarcomeric protein was observed upon differentiation. The electrospun, aligned microfibrous mats of PHBV-P(L-D,L)LA-PGS blends allowed penetration of WJ MSCs and improved cell proliferation. To obtain the 3D myocardial graft, the WJ MSCs were seeded on the mats, which were then wrapped around macroporous tubings. The 3D construct (4 mm x 3.5 cm x 2 mm) was incubated in a bioreactor and maintained the uniform distribution of aligned cells for 2 weeks. The positive effect of nutrient flow within the 3D structure was significant. This study represents an important step towards obtaining a thick, autologous myocardial patch, with structure similar to native tissue and capability to grow, for ventricular restoration.

QH Life 501-531

Modification of polymeric particles via surface grafting for 3D scaffold design

Nugroho, Robertus Wahyu Nayan

January 2015

Surface modification techniques have played important roles in various aspects of modern technology. They have been employed to improve substrates by altering surface physicochemical properties. An ideal surface modifying technique would be a method that is applicable to any kind of materials prepared from a wide range of polymers and that can occur under mild reaction conditions. The work in this thesis has utilized four main concepts: I) the development of a ‘grafting-from’ technique by covalently growing polymer grafts from particle surfaces, II) the presence of steric and electrosteric forces due to long-range repulsive interactions between particles, III) a combined surface grafting and layer-by-layer approach to create polyelectrolyte multilayers (PEMs) on particle surfaces to fabricate strong and functional materials, and IV) the roles of hydrophilic polymer grafts and substrate geometry on surface degradation. A non-destructive surface grafting technique was developed and applied to polylactide (PLA) particle surfaces. Their successful modification was verified by observed changes to the surface chemistry, morphology and topography of the particles. To quantify the aggregation behavior of grafted and non-grafted particles, force interaction measurements were performed using colloidal probe atomic force microscopy (AFM). Long-range repulsive interactions were observed when symmetric systems, i.e., hydrophilic polymer grafts on two interacting surfaces, and asymmetric system were applied. Electrosteric forces were observed when the symmetric substrates interacted at pH 7.4. When PEMs were alternately assembled on the surface of poly(L-lactide) (PLLA) particles, the grafted surfaces played a dominated role in altering the surface chemistry and morphology of the particles. Three-dimensional scaffolds of surface grafted particle coated with PEMs demonstrated high mechanical performance that agreed well with the mechanical performance of cancellous bone. Nanomaterials were used to functionalize the scaffolds and further influence their physicochemical properties. For example, when magnetic nanoparticles were used to functionalize the scaffolds, a high electrical conductivity was imparted, which is important for bone tissue regeneration. Furthermore, the stability of the surface grafted particles was evaluated in phosphate buffered saline (PBS) solution. The nature of the hydrophilic polymer grafts and the geometry of the PLLA substrates played central roles in altering the surface properties of films and particles. After 10 days of PBS immersion, larger alterations in the surface morphology were observed on the film compared with microparticles grafted with poly(acrylic acid) (PAA). In contrast to the PAA-grafted substrates, the morphology of poly(acrylamide) (PAAm)-grafted substrates was not affected by PBS immersion. Additionally, PAAm-grafted microparticulate substrates encountered surface degradation more rapidly than PAAm-grafted film substrates. / <p>QC 20151002</p>

surface grafting

PLA

PLLA

hydrophilic polymers

particles

geometry

steric stabilization

atomic force microscopy (AFM)

polyelectrolyte multilayers

3D scaffold

bone tissue engineering

surface degradation

Synthèse et caractérisation d’hydrogels de fibrine et de polyéthylène glycol pour l’ingénierie tissulaire cutanée / Synthesis and characterization of fibrin/polyethylene glycol based for skin tissue engineering

Gsib, Olfat

20 March 2018

Depuis plus d’une cinquantaine d’années, de formidables avancées ont été initiées dans le domaine de l’ingénierie tissulaire cutanée menant à la reconstruction in vitro de substituts de peau. La plupart sont des substituts dermiques destinés à être utilisés comme aide à la cicatrisation des plaies aigües et chroniques en complément des traitements de greffes conventionnels ainsi que pour l’augmentation des tissus mous. Bien qu’un nombre croissant de patients aient pu bénéficier de ces matrices dermiques, leur application clinique reste encore restreinte, en raison de leur coût élevé mais également à cause de résultats cicatriciels parfois peu satisfaisants. Par conséquent, il reste un défi de taille, celui de développer des substituts dermiques stimulant activement la cicatrisation, présentant un faible coût de production, sans propriétés antigéniques et possédant des propriétés mécaniques adaptées. Dans ce cadre, les hydrogels à base de fibrine constituent des candidats prometteurs, en particulier en raison du rôle central de cette protéine dans la cicatrisation. Le principal inconvénient est qu’à concentration physiologique, ces hydrogels sont faibles mécaniquement, ce qui les rend difficilement manipulables. L’objectif de cette thèse a été la mise au point ainsi que la caractérisation de différents hydrogels destinés à être utilisés comme substituts dermiques. Ces derniers présentent l’avantage d’associer les propriétés biologiques de la fibrine avec les propriétés mécaniques d’un polymère synthétique, le polyéthylène glycol dans une architecture de réseaux interpénétrés de polymères (RIP). Les résultats obtenus ont permis : - de confirmer les propriétés physico-chimiques des RIP développés initialement par nos collaborateurs de l’université de Cergy-Pontoise, - de valider en trois étapes (in vitro, ex vivo puis in vivo) la biocompatibilité de ces nouvelles matrices, destinées à être utilisées comme supports de culture 2D et pour l’augmentation des tissus mous, - d’élaborer et de caractériser des matrices macroporeuses, optimisées pour la culture 3D de fibroblastes de dermes humains. / Over the past five decades, we assisted in extraordinary advances in the field of skin tissue engineering which led to the in vitro reconstruction of a wide range of skin substitutes. Most of them are dermal substitutes: Their clinical application ranges from treating acute and chronic wounds to soft tissue augmentation. Although increasing numbers of patients have been treated with dermal substitutes, their clinical application has been limited by their substantial cost and some poor healing outcomes. Hence, there is still a challenge to produce a dermal substitute which enhance sufficiently wound healing. To this end, the substitute should exhibit suitable properties for enabling the repair process. Other requirements such as excellent biocompatibility, minimal antigenicity, ease to handle and cost-effective production are also essential. In this context, fibrin hydrogels constitute promising candidates for skin tissue engineering since fibrin fibers form a physiological and provisional backbone during wound healing. However, the poor mechanical properties of fibrin-based hydrogels at physiological concentration are an obstacle to their use. In this study, our aim was to design and characterize mechanically reinforced fibrin-based hydrogels by combining the intrinsic properties of a fibrin network with the mechanical features of a polyethylene glycol network using an interpenetrating polymer network (IPN) architecture. They are intended to be used as dermal scaffolds. The results obtained in this thesis: - Confirmed the suitable physico-chemical properties of IPN, first developed by our partner of the University of Cergy-Pontoise. - Validated their biocompatibility using a three-step approach (in vitro, ex vivo and in vivo assays). - Led to the synthesis and characterization of a new type of fibrin-based macroporous matrices, optimized for 3D dermal fibroblast culture.

Macroporosité

Fibroblastes de derme humain

Substitut dermique

Interpenetrating polymer networks (IPN)

Fibrin

Polyethylene glycol

Hydrogel

Skin tissue engineering

Biocompatibility

Biomaterial

Dermal substitute

Dermal human fibroblasts

Macroporosity

3D scaffold