@phdthesis{Berberich2024, author = {Berberich, Oliver}, title = {Lateral Cartilage Tissue Integration - Evaluation of Bonding Strength and Tissue Integration \(in\) \(vitro\) Utilizing Biomaterials and Adhesives}, doi = {10.25972/OPUS-34602}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-346028}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2024}, abstract = {Articular cartilage defects represent one of the most challenging clinical problem for orthopedic surgeons and cartilage damage after trauma can result in debilitating joint pain, functional impairment and in the long-term development of osteoarthritis. The lateral cartilage-cartilage integration is crucial for the long-term success and to prevent further tissue degeneration. Tissue adhesives and sealants are becoming increasingly more popular and can be a beneficial approach in fostering tissue integration, particularly in tissues like cartilage where alternative techniques, such as suturing, would instead introduce further damage. However, adhesive materials still require optimization regarding the maximization of adhesion strength on the one hand and long-term tissue integration on the other hand. In vitro models can be a valuable support in the investigation of potential candidates and their functional mechanisms. For the conducted experiments within this work, an in vitro disc/ring model obtained from porcine articular cartilage tissue was established. In addition to qualitative evaluation of regeneration, this model facilitates the implementation of biomechanical tests to quantify cartilage integration strength. Construct harvesting for histology and other evaluation methods could be standardized and is ethically less questionable compared to in vivo testing. The opportunity of cell culture technique application for the in vitro model allowed a better understanding of cartilage integration processes. Tissue bonding requires chemical or physical interaction of the adhesive material and the substrate. Adhesive hydrogels can bind to the defect interface and simultaneously fill the gap of irregularly shaped defect voids. Fibrin gels are derived from the physiological blood-clot formation and are clinically applied for wound closure. Within this work, comparisons of different fibrin glue formulations with the commercial BioGlue® were assessed, which highlighted the need for good biocompatibility when applied on cartilage tissue in order to achieve satisfying long-term integration. Fibrin gel formulations can be adapted with regard to their long-term stability and when applied on cartilage disc/ring constructs improved integrative repair is observable. The kinetic of repairing processes was investigated in fibrin-treated cartilage composites as part of this work. After three days in vitro cultivation, deposited extracellular matrix (ECM) was obvious at the glued interface that increased further over time. Interfacial cell invasion from the surrounding native cartilage was detected from day ten of tissue culture. The ECM formation relies on molecular factors, e.g., as was shown representatively for ascorbic acid, and contributes to increasing integration strengths over time. The experiments performed with fibrin revealed that the treatment with a biocompatible adhesive that allows cartilage neosynthesis favors lateral cartilage integration in the long term. However, fibrin has limited immediate bonding strength, which is disadvantageous for use on articular cartilage that is subject to high mechanical stress. The continuing aim of this thesis was to further develop adhesive mechanisms and new adhesive hydrogels that retain the positive properties of fibrin but have an increased immediate bonding strength. Two different photochemical approaches with the advantage of on-demand bonding were tested. Such treatment potentially eases the application for the professional user. First, an UV light induced crosslinking mechanism was transferred to fibrin glue to provide additional bonding strength. For this, the cartilage surface was functionalized with highly reactive light-sensitive diazirine groups, which allowed additional covalent bonds to the fibrin matrix and thus increased the adhesive strength. However, the disadvantages of this approach were the multi-step bonding reactions, the need for enzymatic pretreatment of the cartilage, expensive reagents, potential UV-light damage, and potential toxicity hazards. Due to the mentioned disadvantages, no further experiments, including long-term culture, were carried out. A second photosensitive approach focused on blue light induced crosslinking of fibrinogen (RuFib) via a photoinitiator molecule instead of using thrombin as a crosslinking mediator like in normal fibrin glue. The used ruthenium complex allowed inter- and intramolecular dityrosine binding of fibrinogen molecules. The advantage of this method is a one-step curing of fibrinogen via visible light that further achieved higher adhesive strengths than fibrin. In contrast to diazirine functionalization of cartilage, the ruthenium complex is of less toxicological concern. However, after in vitro cultivation of the disc/ring constructs, there was a decrease in integration strength. Compared to fibrin, a reduced cartilage synthesis was observed at the defect. It is also disadvantageous that a direct adjustment of the adhesive can only be made via protein concentration, since fibrinogen is a natural protein that has a fixed number of tyrosine binding sites without chemical modification. An additional cartilage adhesive was developed that is based on a mussel-inspired adhesive mechanism in which reactivity to a variety of substrates is enabled via free DOPA amino acids. DOPA-based adhesion is known to function in moist environments, a major advantage for application on water-rich cartilage tissue surrounded by synovial liquid. Reactive DOPA groups were synthetically attached to a polymer, here POx, to allow easy chemical modifiability, e.g. insertion of hydrolyzable ester motifs for tunable degradation. The possibility of preparing an adhesive hybrid hydrogel of POx in combination with fibrinogen led to good cell compatibility as was similarly observed with fibrin, but with increased immediate adhesive strength. Degradation could be adjusted by the amount of ester linkages on the POx and a direct influence of degradation rates on the development of integration in the in vitro model could be shown. Hydrogels are well suited to fill defect gaps and immediate integration can be achieved via adhesive properties. The results obtained show that for the success of long-term integration, a good ability of the adhesive to take up synthesized ECM components and cells to enable regeneration is required. The degradation kinetics of the adhesive must match the remodeling process to avoid intermediate loss of integration power and to allow long-term firm adhesion to the native tissue. Hydrogels are not only important as adhesives for smaller lesions, but also for filling large defect volumes and populating them with cells to produce tissue engineered cartilage. Many different hydrogel types suitable for cartilage synthesis are reported in the literature. A long-term stable fibrin formulation was tested in this work not only as an adhesive but also as a bulk hydrogel construct. Agarose is also a material widely used in cartilage tissue engineering that has shown good cartilage neosynthesis and was included in integration assessment. In addition, a synthetic hyaluronic acid-based hydrogel (HA SH/P(AGE/G)) was used. The disc/ring construct was adapted for such experiments and the inner lumen of the cartilage ring was filled with the respective hydrogel. In contrast to agarose, fibrin and HA-SH/P(AGE/G) gels have a crosslink mechanism that led to immediate bonding upon contact with cartilage during curing. The enhanced cartilage neosynthesis in agarose compared to the other hydrogel types resulted in improved integration during in vitro culture. This shows that for the long-term success of a treatment, remodeling of the hydrogel into functional cartilage tissue is a very high priority. In order to successfully treat larger cartilage defects with hydrogels, new materials with these properties in combination with chemical modifiability and a direct adhesion mechanism are one of the most promising approaches.}, subject = {Knorpel}, language = {en} } @phdthesis{Schmidt2021, author = {Schmidt, Stefanie}, title = {Cartilage Tissue Engineering - Comparison of Articular Cartilage Progenitor Cells and Mesenchymal Stromal Cells in Agarose and Hyaluronic Acid-Based Hydrogels}, doi = {10.25972/OPUS-25171}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-251719}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {Articular cartilage damage caused by sports accidents, trauma or gradual wear and tear can lead to degeneration and the development of osteoarthritis because cartilage tissue has only limited capacity for intrinsic healing. Osteoarthritis causes reduction of mobility and chronic pain and is one of the leading causes of disability in the elderly population. Current clinical treatment options can reduce pain and restore mobility for some time, but the formed repair tissue has mostly inferior functionality compared to healthy articular cartilage and does not last long-term. Articular cartilage tissue engineering is a promising approach for the improvement of the quality of cartilage repair tissue and regeneration. In this thesis, a promising new cell type for articular cartilage tissue engineering, the so-called articular cartilage progenitor cell (ACPC), was investigated for the first time in the two different hydrogels agarose and HA-SH/P(AGE-co-G) in comparison to mesenchymal stromal cells (MSCs). In agarose, ACPCs´ and MSCs´ chondrogenic capacity was investigated under normoxic (21 \% oxygen) and hypoxic (2 \% oxygen) conditions in monoculture constructs and in zonally layered co-culture constructs with ACPCs in the upper layer and MSCs in the lower layer. In the newly developed hyaluronic acid (HA)-based hydrogel HA-SH/P(AGE-co-G), chondrogenesis of ACPCs and MSCs was also evaluated in monoculture constructs and in zonally layered co-culture constructs like in agarose hydrogel. Additionally, the contribution of the bioactive molecule hyaluronic acid to chondrogenic gene expression of MSCs was investigated in 2D monolayer, 3D pellet and HA-SH hydrogel culture. It was shown that both ACPCs and MSCs could chondrogenically differentiate in agarose and HA-SH/P(AGE-co-G) hydrogels. In agarose hydrogel, ACPCs produced a more articular cartilage-like tissue than MSCs that contained more glycosaminoglycan (GAG), less type I collagen and only little alkaline phosphatase (ALP) activity. Hypoxic conditions did not increase extracellular matrix (ECM) production of ACPCs and MSCs significantly but improved the quality of the neo-cartilage tissue produced by MSCs. The creation of zonal agarose constructs with ACPCs in the upper layer and MSCs in the lower layer led to an ECM production in zonal hydrogels that lay in general in between the ECM production of non-zonal ACPC and MSC hydrogels. Even though zonal co-culture of ACPCs and MSCs did not increase ECM production, the two cell types influenced each other and, for example, modulated the staining intensities of type II and type I collagen in comparison to non-zonal constructs under normoxic and hypoxic conditions. In HA-SH/P(AGE-co-G) hydrogel, MSCs produced more ECM than ACPCs, but the ECM was limited to the pericellular region for both cell types. Zonal HASH/P(AGE-co-G) hydrogels resulted in a native-like zonal distribution of ECM as MSCs in the lower zone produced more ECM than ACPCs in the upper zone. It appeared that chondrogenesis of ACPCs was supported by hydrogels without biological attachment sites such as agarose, and that chondrogenesis of MSCs benefited from hydrogels with biological cues like HA. As HA is an attractive material for cartilage tissue engineering, and the HA-based hydrogel HA-SH/P(AGE-co-G) appeared to be beneficial for MSC chondrogenic differentiation, the contribution of HA to chondrogenic gene expression of MSCs was investigated. An upregulation of chondrogenic gene expression was found in 2D monolayer and 3D pellet culture of MSCs in response to HA supplementation, while gene expression of osteogenic and adipogenic transcription factors was not upregulated. MSCs, encapsulated in a HA-based hydrogel, showed upregulation of gene expression for chondrogenic, osteogenic and adipogenic differentiation markers as well as for stemness markers. In a 3D bioprinting process, using the HA-based hydrogel, gene expression levels of MSCs mostly did not change. Nevertheless, expression of three tested genes (COL2A1, SOX2, CD168) was downregulated in printed in comparison to cast constructs, underscoring the importance of closely monitoring cellular behaviour during and after the printing process. In summary, it was confirmed that ACPCs are a promising cell source for articular cartilage engineering with advantages over MSCs when they were cultured in a suitable hydrogel like agarose. The performance of the cells was strongly dependent on the hydrogel environment they were cultured in. The different chondrogenic performance of ACPCs and MSCs in agarose and HA-SH/P(AGE-co-G) hydrogels highlighted the importance of choosing suitable hydrogels for the different cell types used in articular cartilage tissue engineering. Hydrogels with high polymer content, such as the investigated HA-SH/P(AGE-co-G) hydrogels, can limit ECM distribution to the pericellular area and should be developed further towards less polymer content, leading to more homogenous ECM distribution of the cultured cells. The influence of HA on chondrogenic gene expression and on the balance between differentiation and maintenance of stemness in MSCs was demonstrated. More studies should be performed in the future to further elucidate the signalling functions of HA and the effects of 3D bioprinting in HA-based hydrogels. Taken together, the results of this thesis expand the knowledge in the area of articular cartilage engineering with regard to the rational combination of cell types and hydrogel materials and open up new possible approaches to the regeneration of articular cartilage tissue.}, subject = {Hyaliner Knorpel}, language = {en} } @phdthesis{Schwab2017, author = {Schwab, Andrea}, title = {Development of an osteochondral cartilage defect model}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-155617}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2017}, abstract = {The limited intrinsic self-healing capability of articular cartilage requires treatment of cartilage defects. Material assisted and cell based therapies are in clinical practice but tend to result in formation of mechanical inferior fibro-cartilage in long term follow up. If a lesion has not been properly restored degenerative diseases are diagnosed as late sequela causing pain and loss in morbidity. Complex three dimensional tissue models mimicking physiological situation allow investigation of cartilage metabolism and mechanisms involved in repair. A standardized and reproducible model cultured under controllable conditions ex vivo to maintain tissue properties is of relevance for comparable studies. Topic of this thesis was the establishment of an cartilage defect model that allows for testing novel biomaterials and investigate the effect of defined defect depths on formation of repair tissue. In part I an ex vivo osteochondral defect model was established based on isolation of porcine osteochondral explants (OCE) from medial condyles, 8 mm in diameter and 5 mm in height. Full thickness cartilage defects with 1 mm to 4 mm in diameter were created to define ex vivo cartilage critical size after 28 days culture with custom developed static culture device. In part II of this thesis hydrogel materials, namely collagen I isolated from rat tail, commercially available fibrin glue, matrix-metalloproteinase clevable poly(ethylene glycol) polymerized with heparin (starPEGh), methacrylated poly(N-(2-hydroxypropyl) methacrylamide mono-dilactate-poly(ethylene glycol) triblock copolymer/methacrylated hyaluronic acid (MP/HA), thiol functionalized HA/allyl functionalized poly(glycidol) (P(AGE/G)-HA-SH), were tested cell free and chondrocyte loaded (20 mio/ml) as implant in 4 mm cartilage defects to investigate cartilage regeneration. Reproducible chondral defects, 8 mm in diameter and 1 mm in height, were generated with an artificial tissue cutter (ARTcut®) to investigate effect of defect depth on defect regeneration in part III. In all approaches OCE were analyzed by Safranin-O staining to visualize proteoglycans in cartilage and/or hydrogels. Immuno-histological and -fluorescent stainings (aggrecan, collagen II, VI and X, proCollagen I, SOX9, RUNX2), gene expression analysis (aggrecan, collagen II and X, SOX9, RUNX2) of chondrocyte loaded hydrogels (part II) and proteoglycan and DNA content (Part I \& II) were performed for detailed analysis of cartilage regeneration. Part I: The development of custom made static culture device, consisting of inserts in which OCE is fixed and deep well plate, allowed tissue specific media supply without supplementation of TGF � . Critical size diameter was defined to be 4 mm. Part II: Biomaterials revealed differences in cartilage regeneration. Collagen I and fibrin glue showed presence of cells migrated from OCE into cell free hydrogels with indication of fibrous tissue formation by presence of proCollagen I. In chondrocyte loaded study cartilage matrix proteins aggrecan, collagen II and VI and transcription factor SOX9 were detected after ex vivo culture throughout the two natural hydrogels collagen I and fibrin glue whereas markers were localized in pericellular matrix in starPEGh. Weak stainings resulted for MP/HA and P(AGE/G)-HA-SH in some cell clusters. Gene expression data and proteoglycan quantification supported histological findings with tendency of hypertrophy indicated by upregulation of collagen X and RunX2 in MP/HA and P(AGE/G)-HA-SH. Part III: In life-dead stainings recruitment of cells from OCE into empty or cell free collagen I treated chondral defects was seen. Separated and tissue specific media supply is critical to maintain ECM composition in cartilage. Presence of OCE stimulates cartilage matrix synthesis in chondrocyte loaded collagen I hydrogel and reduces hypertrophy compared to free swelling conditions and pellet cultures. Differences in cartilage repair tissue formation resulted in preference of natural derived polymers compared to synthetic based materials. The ex vivo cartilage defect model represents a platform for testing novel hydrogels as cartilage materials, but also to investigate the effect of cell seeding densities, cell gradients, cell co-cultures on defect regeneration dependent on defect depth. The separated media compartments allow for systematic analysis of pharmaceutics, media components or inflammatory cytokines on bone and cartilage metabolism and matrix stability.}, subject = {Hyaliner Knorpel}, language = {en} }