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Institute
- Graduate School of Life Sciences (32) (remove)
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.
Lungenkrebs ist weltweit für die meisten krebsassoziierten Tode verantwortlich. Ursache dafür ist unter anderem, dass viele Medikamente in der klinischen Anwendung, aufgrund nicht übertragbarer Ergebnisse aus der Präklinik, scheitern. Zur Entwicklung neuer Therapiestrategien werden deshalb Modelle benötigt, welche die in vivo Situation besser widerspiegeln. Besonders wichtig ist es dabei, zu zeigen, für welche Fragestellungen ein neues Testsystem valide Ergebnisse liefert.
In dieser Arbeit ist es mit Hilfe des Tissue Engineering gelungen, ein humanes 3D in vitro Lungentumor-Testsystem weiter zu entwickeln und für verschiedene Fragestellungen zu validieren. Zudem konnten sowohl für die Herstellung als auch für die Behandlung der Tumormodelle SOPs etabliert werden. Hier wurde zunächst beobachtet, dass die Auswerteparameter für die Beurteilung von Behandlungseffekten eine geringe Varianz aufweisen und das 3D Modell deshalb als Testsystem geeignet ist.
Ein Vergleich der Morphologie, des EMT-Status und der Differenzierung der Tumorzelllinien im 3D Modell mit Tumorbiopsaten von Adenokarzinompatienten verdeutlichte, dass die 3D Modelle tumorrelevante Merkmale besitzen. So sind die Zelllinien auf der biologischen Matrix, verglichen mit der jeweiligen 2D Kultur, durch eine reduzierte Proliferationsrate gekennzeichnet, welche eher der in vivo Situation entspricht. Für die Etablierung und Validierung des 3D Modells als Testsystem war es notwendig, klinisch relevante Therapien in dem Modell anzuwenden und die Ergebnisse der Behandlung in vitro mit denen im Patienten zu vergleichen. Dabei konnte zunächst bestätigt werden, dass eine zielgerichtete Therapie gegen den EGFR in dem 3D System zu einer verstärkten Induktion der Apoptose im Vergleich zu 2D führt. Dies entspricht klinischen Beobachtungen, bei denen EGFR-mutierte Patienten gut auf eine Therapie mit Tyrosin-Kinase-Inhibitoren (TKI) ansprechen. Anschließend wurde in dieser Arbeit erstmals in vitro gezeigt, dass die Behandlung mit einem HSP90-Inhibitor bei KRAS-Mutation wie in behandelten Patienten keine eindeutigen Vorteile bringt, diese jedoch in Experimenten der 2D Zellkultur mit den entsprechenden Zelllinien vorhergesagt werden. Die Ergebnisse aus dem in vitro Modell spiegeln damit verschiedene klinische Studien wider und unterstreichen das Potenzial des 3D Lungentumor-Testsystems die Wirkung zielgerichteter Therapien vorherzusagen. Durch die Messung von Signalwegsaktivierungen über Phospho-Arrays und Western Blot konnten in dieser Arbeit Unterschiede zwischen 2D und 3D nach Behandlung gezeigt werden. Diese lieferten die Grundlage für bioinformatische Vorhersagen für Medikamente.
Mit fortschreitender Erkrankung und dem Entstehen invasiver Tumore, die möglicherweise Metastasen bilden, verschlechtert sich die Prognose von Krebspatienten. Zudem entwickeln Patienten, die zunächst auf eine Therapie mit TKI ansprechen, bereits nach kurzer Zeit Resistenzen, die ebenfalls zur Progression des Tumorwachstums führen. Zur Wirkungsuntersuchung von Substanzen in solchen fortgeschrittenen Erkrankungsstadien wurde das bestehende Testsystem erweitert. Zum einen wurde mit Hilfe des Wachstumsfaktors TGF-β1 eine EMT ausgelöst. Hier konnte beobachtet werden, dass sich die Expression verschiedener EMT- und invasionsassoziierter Gene und Proteine veränderte und die Zellen vor allem in dynamischer Kultur verstärkt die Basalmembran der Matrix überquerten. Zum anderen wurde die Ausbildung von Resistenzen gegenüber TKI durch die Generierung von resistenten Subpopulationen aus einer ursprünglich sensitiven Zelllinie und anschließender Kultivierung auf der Matrix abgebildet. Dabei zeigte sich keine der klinisch bekannten Mutationen als ursächlich für die Resistenz, sodass weitere Mechanismen untersucht wurden. Hier konnten Veränderungen in der Signaltransduktion sowie der Expression EMT-assoziierter Proteine festgestellt werden.
Im letzten Teil der Arbeit wurde eine neuartige Behandlung im Bereich der Immuntherapie erfolgreich in dem 3D Modell angewendet. Dafür wurden T-Zellen, die einen chimären Antigen-Rezeptor (CAR) gegen ROR1 tragen, in statischer und dynamischer Kultur zu den Tumorzellen gegeben und der Therapieeffekt mittels histologischer Färbung und der Bestimmung der Apoptose evaluiert. Zusätzlich konnten Eigenschaften der T-Zellen, wie deren Proliferation sowie Zytokinausschüttung quantifiziert und damit eine spezifische Wirkung der CAR transduzierten T-Zellen gegenüber Kontroll-T-Zellen nachgewiesen werden.
Zusammenfassend ist es in dieser Arbeit gelungen, ein humanes 3D Lungentumor-Testsystem für die Anwendung in der präklinischen Entwicklung von Krebsmedikamenten sowie der Grundlagenforschung im Bereich der Tumorbiologie zu etablieren. Dieses Testsystem ist in der Lage relevante Daten zu Biomarker-geleiteten Therapien, zur Behandlung fortgeschrittener Tumorstadien und zur Verbesserung neuartiger Therapiestrategien zu liefern.
Kardiovaskuläre Erkrankungen, wie beispielsweise der Herzinfarkt, sind die häufigste Todesursache weltweit. Bei einem Herzinfarkt sterben Areale des Herzens aufgrund einer Unterversorgung mit Blut ab. Da das Herzmuskelgewebe ein sogenanntes terminal differenziertes Gewebe ist, kommt es zu keiner Regeneration des Gewebes, mit der Folge einer Herzinsuffizienz beziehungsweise dem Tod des Patienten. Eine alternative Behandlungsmöglichkeit zu einer Herztransplantation stellt das Tissue Engineering dar. Mit Hilfe des Tissue Engineerings können dreidimensionale Gewebe aufgebaut und kultiviert werden, um auf diese Weise ein funktionelles Gewebe zu erhalten, durch welches das abgestorbene Gewebeareal des Herzens zukünftig auch ersetzt werden könnte.
In der vorliegenden Arbeit wurden notwendige Technologien für den Aufbau von Geweben entwickelt sowie erste Versuche für die Erzeugung eines funktionellen Herzmuskelgewebes durchgeführt. Beim Aufbau von dreidimensionalen Geweben finden Trägerstrukturen Anwendung, die mit Zellen besiedelt werden. Solche Trägerstrukturen können aus biologischen oder synthetischen Polymeren hergestellt sein oder aus der extrazellulären Matrix eines dezellularisierten Gewebes bestehen. Für eine standardisierte Dezellularisierung von Geweben wurde eine computergesteuerte Pumpeneinheit, für die Herstellung von Nanofaserscaffolds eine Elektrospinninganlage entwickelt. Mit Hilfe der Dezellularisierungseinheit können komplexe Organe, wie ein Herz im Ganzen, reproduzierbar dezellularisiert werden. Untersuchungen der mittels Elektrospinning hergestellten Nanofaserscaffolds, welche als Alternative zu der dezellularisierten, natürlichen Matrix eingesetzt werden können, zeigten bei allen hergestellten Zusammensetzungen eine Orientierung der Zellen entlang der Fasern.
Die Kultivierung von Zellmatrixkonstrukten erfolgt im Tissue Engineering häufig unter dynamischen Bedingungen. Hierfür wurde ein mobiler Stand Alone Inkubator mit der erforderlichen Peripherie für eine Kultur unter Perfusion des Gewebes entwickelt. Als Weiterentwicklung des Stand Alone Inkubators ist eine modulare Bioreaktorplattform, bestehend aus Wärmetauscher, Beutelpumpe und Gasaustauscher, aufgebaut worden. In dieses System kann über Standard Anschlüsse jegliche Art von Bioreaktor in das System eingebunden werden. Durch die Kompaktheit des Systems ist es möglich mehrere Ansätze parallel auf engem Raum durchzuführen. Die Funktion der Plattform, wurde in der vorliegenden Arbeit durch die Gewebekultur einer nativen porzinen Karotis nachgewiesen.
Für den Aufbau des kardialen Gewebes dient die small intestinal submucosa ohne Serosa (SISser) als Trägerstruktur. Der Aufbau des Gewebekonstrukts erfolgte in verschiedenen Ansätzen unter Einsatz verschiedener Zellarten. Native, aus Herzbiopsien generierte Cardiosphere derived cells (CDCs) verteilten sich gleichmäßige über die Oberfläche der Matrix, jedoch konnten immunhistologisch keine spezifischen kardialen Marker bei den artifiziellen Geweben nachgewiesen werden. Zellmatrixkonstrukte aus einer Mono Kultur von Kardiomyozyten, differenziert aus induzierten pluripotenten Stammzellen (iPS Zellen) sowie einer Co Kultur dieser Kardiomyozyten mit mesenchymalen Stammzellen und Zellen aus einer Herzbiopsie zeigten nach wenigen Tagen in Kultur ein kontraktiles Verhalten. Immunhistologische Färbungen der beiden Gewebe bestätigten die Expression der spezifischen kardialen Marker, wie beispielsweise kardiales Troponin T, kardiales Troponin C und alpha Actinin. Die Kardiomyozyten der Mono Kultur sind jedoch nicht über die gesamte Matrixoberfläche verteilt, sondern bilden Aggregate. Bei der Co Kultur kann eine gleichmäßige Verteilung der Zellen auf der Matrix beobachtet werden. Der vielversprechendste Ansatz für den Aufbau eines Herzmuskelgewebes, welches als Implantat oder Testsystem eingesetzt werden kann, bildet nach den in dieser Arbeit erzielten Ergebnissen, ein Konstrukt aus der SISser und der Co Kultur der Zellen. Allerdings muss die Zusammensetzung der Co Kultur sowie das Verhältnis der Zellzahlen optimiert werden.
The main function of the small intestine is the absorption of essential nutrients, water and vitamins. Moreover, it constitutes a barrier protecting us from toxic xenobiotics and pathogens. For a better understanding of these processes, the development of intestinal in vitro models is of great interest to the study of pharmacological and pathological issues such as transport mechanisms and barrier function. Depending on the scientific questions, models of different complexity can be applied.
In vitro Transwell® systems based on a porous PET-membrane enable the standardized study of transport mechanisms across the intestinal barrier as well as the investigation of the influence of target substances on barrier integrity. However, this artificial setup reflects only limited aspects of the physiology of the native small intestine and can pose an additional physical barrier. Hence, the applications of this model for tissue engineering are limited.
Previously, tissue models based on a biological decellularized scaffold derived from porcine gut tissue were demonstrated to be a good alternative to the commonly used Transwell® system. This study showed that preserved biological extracellular matrix components like collagen and elastin provide a natural environment for the epithelial cells, promoting cell adhesion and growth. Intestinal epithelial cells such as Caco-2 cultured on such a scaffold showed a confluent, tight monolayer on the apical surface. Additionally, myofibroblasts were able to migrate into the scaffold supporting intestinal barrier formation.
In this thesis, dendritic cells were additionally introduced to this model mimicking an important component of the immune system. This co-culture model was then successfully proven to be suitable for the screening of particle formulations developed as delivery system for cancer antigens in peroral vaccination studies. In particular, nanoparticles based on PLGA, PEG-PAGE-PLGA, Mannose-PEG-PAGE-PLGA and Chitosan were tested. Uptake studies revealed only slight differences in the transcellular transport rate among the different particles. Dendritic cells were shown to phagocytose the particles after they have passed the intestinal barrier. The particles demonstrated to be an effective carrier system to transport peptides across the intestinal barrier and therefore present a useful tool for the development of novel drugs.
Furthermore, to mimic the complex structure and physiology of the gut including the presence of multiple different cell types, the Caco-2 cell line was replaced by primary intestinal cells to set up a de novo tissue model. To that end, intestinal crypts including undifferentiated stem cells and progenitor cells were isolated from human small intestinal tissue samples (jejunum) and expanded in vitro in organoid cultures. Cells were cultured on the decellularized porcine gut matrix in co-culture with intestinal myofibroblasts. These novel tissue models were maintained under either static or dynamic conditions.
Primary intestinal epithelial cells formed a confluent monolayer including the major differentiated cell types positive for mucin (goblet cells), villin (enterocytes), chromogranin A (enteroendocrine cells) and lysozyme (paneth cells). Electron microscopy images depicted essential functional units of an intact epithelium, such as microvilli and tight junctions. FITC-dextran permeability and TEER measurements were used to assess tightness of the cell layer. Models showed characteristic transport activity for several reference substances. Mechanical stimulation of the cells by a dynamic culture system had a great impact on barrier integrity and transporter activity resulting in a tighter barrier and a higher efflux transporter activity.
In Summary, the use of primary human intestinal cells combined with a biological decellularized scaffold offers a new and promising way to setup more physiological intestinal in vitro models. Maintenance of primary intestinal stem cells with their proliferation and differentiation potential together with adjusted culture protocols might help further improve the models. In particular, dynamic culture systems and co culture models proofed to be a first crucial steps towards a more physiological model. Such tissue models might be useful to improve the predictive power of in vitro models and in vitro in vivo correlation (IVIVC) studies. Moreover, these tissue models will be useful tools in preclinical studies to test pharmaceutical substances, probiotic active organisms, human pathogenic germs and could even be used to build up patient-specific tissue model for personalized medicine.
Induced pluripotent stem cells (iPSCs) have been recognised as a virtually unlimited source of stem cells that can be generated in a patient-specific manner. Due to these cells’ potential to give rise to all differentiated cell types of the human body, they have been widely used to derive differentiated cells for drug screening and disease modelling purposes. iPSCs also garner much interest as they can potentially serve as a source for cell replacement therapy. Towards the realisation of these biomedical applications, this thesis aims to address challenges that are associated with scale-up, safety and biofabrication.
Firstly, the manufacture of a high number of human iPSCs (hiPSCs) will require standardised procedures for scale-up and the development of a flexible bioprocessing method, since standard adherent hiPSC culture exhibits limited scalability and is labour-intensive. While the quantity of cells that are required for cell therapy depends largely on the tissue and defect that these replacing cells are meant to correct, an estimate of 1 × 10^9 has been suggested to be sufficient for several indications, including myocardial infarction and islet replacement for diabetes. Here, the development of an integrated, microcarrier-free workflow to transition standard adherent hiPSC culture (6-well plates) to scalable stirred suspension culture in bioreactors (1 L working volume, 2.4 L maximum working volume) is presented. The two-phase bioprocess lasts 14 days and generates hiPSC aggregates measuring 198 ± 58 μm in diameter on the harvesting day, yielding close to 2 × 10^9 cells. hiPSCs can be maintained in stirred suspension for at least 7 weeks with weekly passaging, while exhibiting pluripotency-associated markers TRA-1-60, TRA-1-81, SSEA-4, OCT4, and SOX2. These cells retain their ability to differentiate into cells of all the three germ layers in vitro, exemplified by cells positive for AFP, SMA, or TUBB3. Additionally, they maintain a stable karyotype and continue to respond to specification cues, demonstrated by directed differentiation into beating cardiomyocyte-like cells. Therefore, the aim of manufacturing high hiPSC quantities was met using a state-of-the-art scalable suspension bioreactor platform.
Secondly, multipotent stem cells such as induced neural stem cells (iNSCs) may represent a safer source of renewable cells compared to pluripotent stem cells. However, pre-conditioning of stem cells prior to transplantation is a delicate issue to ensure not only proper function in the host but also safety. Here, iNSCs which are normally maintained in the presence of factors such as hLIF, CHIR99021, and SB431542 were cultured in basal medium for distinct periods of time. This wash-out procedure results in lower proliferation while maintaining key neural stem cell marker PAX6, suggesting a transient pre-differentiated state. Such pre-treatment may aid transplantation studies to suppress tumourigenesis through transplanted cells, an approach that is being evaluated using a mouse model of experimental focal demyelination and autoimmune encephalomyelitis.
Thirdly, biomedical applications of stem cells can benefit from recent advancements in biofabrication, where cells can be arranged in customisable topographical layouts. Employing a 3DDiscovery bioprinter, a bioink consisting of hiPSCs in gelatin-alginate was extruded into disc-shaped moulds or printed in a cross-hatch infill pattern and cross-linked with calcium ions. In both discs and printed patterns, hiPSCs recovered from these bioprints showed viability of around 70% even after 4 days of culture when loaded into gelatin-alginate solution in aggregate form. They maintained pluripotency-associated markers TRA-1-60 and SSEA-4 and continued to proliferate after re-plating. As further proof-of-principle, printed hiPSC 3D constructs were subjected to targeted neuronal differentiation, developing typical neurite outgrowth and resulting in a widespread network of cells throughout and within the topology of the printed matrix. Staining against TUBB3 confirmed neuronal identity of the differentiated cellular progeny. In conclusion, these data demonstrate that hiPSCs not only survive the 3D-printing process but were able to differentiate along the printed topology in cellular networks.
The knee joint is a complex composite joint containing the C-shaped wedge-like menisci composed of fibrocartilage. Due to their complex composition and structure, they provide mechanical resilience to the knee joint protecting the articular cartilage. Because of the limited repair potential, meniscal injuries do not only affect the meniscus itself but also lead to altered joint homeostasis and inevitably to secondary osteoarthritis.
The meniscus was characterized focusing on its anatomy, structure and meniscal markers such as aggrecan, collagen type I (Col I) and Col II. The components relevant for meniscus tissue engineering, namely cells, Col I scaffolds, biochemical and biomechanical stimuli were studied. Meniscal cells (MCs) were isolated from meniscus, mesenchymal stem cells (MSCs) from bone marrow and dermal microvascular endothelial cells (d-mvECs) from foreskin biopsies. For the human (h) meniscus model, wedge-shape compression of a hMSC-laden Col I gel was successfully established. During three weeks of static culture, the biochemical stimulus transforming growth factor beta-3 (TGF beta-3) led to a compact collagen structure. On day 21, this meniscus model showed high metabolic activity and matrix remodeling as confirmed by matrix metalloproteinases detection. The fibrochondrogenic properties were illustrated by immunohistochemical detection of meniscal markers, significant GAG/DNA increase and increased compressive properties. For further improvement, biomechanical stimulation systems by compression and hydrostatic pressure were designed. As one vascularization approach, direct stimulation with ciclopirox olamine (CPX) significantly increased sprouting of hd-mvEC spheroids even in absence of auxiliary cells such as MSCs. Second, a cell sheet composed of hMSCs and hd-mvECs was fabricated by temperature triggered cell sheet engineering and transferred onto the wedge-shaped meniscus model. Third, a biological vascularized scaffold (BioVaSc-TERM) was re-endothelialized with hd-mvECs providing a viable vascularized network. The vascularized BioVaSc-TERM was suggested as wrapping scaffold of the meniscus model by using two suture techniques, the all-inside-repair (AIR) for the posterior horn, and the outside-in-refixation (OIR) for the anterior horn and the middle part.
This meniscus model for replacing torn menisci is a promising approach to be further optimized regarding vascularization, biochemical and biomechanical stimuli.
In reconstructive and plastic surgery, there exists a growing demand of adequate tissue implants, since currently available strategies for autologous transplantation are limited by complications including transplant failure and donor site morbidity. By developing in vitro and in vivo autologous substitutes for defective tissue sites, adipose tissue engineering can address these challenges, although there are several obstacles to overcome. One of the major limitations is the sufficient vascularization of in vitro engineered large constructs that remains crucial and demanding for functional tissues. Decellularized jejunal segments may represent a suitable scaffolding system with preexisting capillary structures that can be repopulated with human microvascular endothelial cells (hMVECs), and a luminal matrix applicable for the adipogenic differentiation of human adipose-derived stem cells (hASCs). Hence, co-culture of these cells in jejunal segments, utilizing a custom-made bioreactor system, was characterized in terms of vascularization and adipose tissue development. Substantial adipogenesis of hASCs was demonstrated within the jejunal lumen in contrast to non-induced controls, and the increase of key adipogenic markers was verified over time upon induction. The development of major extracellular matrix components of mature adipose tissue, such as laminin and collagen IV, was shown within the scaffold in induced samples. Successful reseeding of the vascular network with hMVECs was demonstrated in long-term culture and co-localization of vascular structures and adipogenically differentiated hASCs was observed. Therefore, these results represent a novel approach for in vitro engineering of vascularized adipose tissue constructs that warrants further investigations in preclinical studies.
Another still existing obstacle in adipose tissue engineering is the insufficient knowledge about the applied cells, for instance the understanding of how cells can be optimally expanded and differentiated for successful engineering of tissue transplants. Even though hASCs can be easily isolated from liposuction of abdominal fat depots, yielding low donor site morbidity, huge numbers of cells are required to entirely seed complex and large 3D matrices or scaffolds. Thus, cells need to be large-scale expanded in vitro on the premise of not losing their differentiation capacity caused by replicative aging. Accordingly, an improved differentiation of hASCs in adipose tissue engineering approaches remains still desirable since most engineered constructs exhibit an inhomogeneous differentiation pattern. For mesenchymal stem cells (MSCs), it has been shown that growth factor application can lead to a significant improvement of both proliferation and differentiation capacity. Especially basic fibroblast growth factor (bFGF) represents a potent mitogen for MSCs, while maintaining or even promoting their osteogenic, chondrogenic and adipogenic differentiation potential. As there are currently different contradictory information present in literature about the applied bFGF concentration and the explicit effect of bFGF on ASC differentiation, here, the effect of bFGF on hASC proliferation and differentiation capacity was investigated at different concentrations and time points in 2D culture. Preculture of hASCs with bFGF prior to adipogenic induction showed a remarkable effect, whereas administration of bFGF during culture did not improve adipogenic differentiation capacity. Furthermore, the observations indicated as mode of action an impact of this preculture on cell proliferation capacity, resulting in increased cellular density at the time of adipogenic induction. The difference in cell density at this time point appeared to be pivotal for increased adipogenic capacity of the cells, which was confirmed in a further experiment employing different seeding densities. Interestingly, furthermore, the obtained results suggested a cell-cell contact-mediated mechanism positively influencing adipogenic differentiation. As a consequence, subsequently, studies were conducted focusing on intercellular communication of these cells, which has hardly been investigated to date.
Despite the multitude of literature on the differentiation capacity of ASCs, little is reported about the physiological properties contributing to and controlling the process of lineage differentiation. Direct intercellular communication between adjacent cells via gap junctions has been shown to modulate differentiation processes in other cell types, with connexin 43 (Cx43) being the most abundant isoform of the gap junction-forming connexins. Thus, in the present study we focused on the expression of Cx43 and gap junctional intercellular communication (GJIC) in hASCs, and its significance for adipogenic differentiation of these cells. Cx43 expression in hASCs was demonstrated histologically and on the gene and protein expression level and was shown to be greatly positively influenced by cell seeding density. Functionality of gap junctions was proven by dye transfer analysis in growth medium. Adipogenic differentiation of hASCs was shown to be also distinctly elevated at higher cell seeding densities. Inhibition of GJIC by 18α-glycyrrhetinic acid significantly compromised adipogenic differentiation, as demonstrated by histology, triglyceride quantification, and adipogenic marker gene expression. Flow cytometry analysis showed a lower proportion of cells undergoing adipogenesis when GJIC was inhibited, further indicating the importance of GJIC in the differentiation process. Altogether, these results demonstrate the impact of direct cell-cell communication via gap junctions on the adipogenic differentiation process of hASCs and may contribute to further integrate direct intercellular crosstalk in rationales for tissue engineering approaches.
The culture of human induced pluripotent stem cells (hiPSCs) at large-scale becomes feasible with the aid of scalable suspension setups in continuously stirred tank reactors (CSTRs). Suspension cul- tures of hiPSCs are characterized by the self-aggregation of single cells into macroscopic cell aggre- gates that increase in size over time. The development of these free-floating aggregates is dependent on the culture vessel and thus represents a novel process parameter that is of particular interest for hiPSC suspension culture scaling. Further, aggregates surpassing a critical size are prone to spon- taneous differentiation or cell viability loss. In this regard, and, for the first time, a hiPSC-specific suspension culture unit was developed that utilizes in situ microscope imaging to monitor and to characterize hiPSC aggregation in one specific CSTR setup to a statistically significant degree while omitting the need for error-prone and time-intensive sampling. For this purpose, a small-scale CSTR system was designed and fabricated by fused deposition modeling (FDM) using an in-house 3D- printer. To provide a suitable cell culture environment for the CSTR system and in situ microscope, a custom-built incubator was constructed to accommodate all culture vessels and process control devices. Prior to manufacture, the CSTR design was characterized in silico for standard engineering parameters such as the specific power input, mixing time, and shear stress using computational fluid dynamics (CFD) simulations. The established computational model was successfully validated by comparing CFD-derived mixing time data to manual measurements. Proof for system functionality was provided in the context of long-term expansion (4 passages) of hiPSCs. Thereby, hiPSC aggregate size development was successfully tracked by in situ imaging of CSTR suspensions and subsequent automated image processing. Further, the suitability of the developed hiPSC culture unit was proven by demonstrating the preservation of CSTR-cultured hiPSC pluripotency on RNA level by qRT-PCR and PluriTest, and on protein level by flow cytometry.
Critical size bone defects and nonunion fractures remain difficult to treat. Although cell‐loaded bone substitutes have improved bone ingrowth and formation, the lack of methods for achieving viability and the uniform distribution of cells in the scaffold limits their use as bone grafts. In addition, the predominant mechanical stimulus that drives early osteogenic cell maturation has not been clearly identified. Further, it is challenging to evaluate mechanical stimuli (i.e., deformation and fluid–flow-induced shear stress) because they are interdependent. This thesis compares different mechanical stimuli applied to cell-seeded scaffolds to develop bone grafts efficiently for the treatment of critical size bone defects. It also seeks to understand how deformation strain and interstitial fluid–flow-induced shear stress promote osteogenic lineage commitment. In this thesis, different scaffolds were seeded with primary human bone marrow mesenchymal stem cells (BM-MSCs) from different donors and subjected to static and dynamic culture conditions. In contrast with the static culture conditions, homogenous cell distributions were accomplished under dynamic culture conditions. Additionally, the induction of osteogenic lineage commitment without the addition of soluble factors was observed in the bioreactor system after one week of cell culture. To determine the role of mechanical stimuli, a bioreactor was developed to apply mechanical deformation force to a mesenchymal stem sell (MSC) line (telomerase reverse transcriptase (TERT)) expressing a strain-responsive AP-1 luciferase reporter construct on porous scaffolds. Increased luciferase expression was observed in the deformation strain compared with the shear stress strain. Furthermore, the expression of osteogenic lineage commitment markers such as osteonectin, osteocalcin (OC), osteopontin, runt-related transcription factor 2 (RUNX2), alkaline phosphate (AP), and collagen type 1 was significantly downregulated in the shear stress strain compared with the deformation strain. These findings establish that the deformation strain was the predominant stimulus causing skeletal precursors to undergo osteogenesis in earlier stages of osteogenic cell maturation. Finally, these findings were used to develop a bioreactor in vitro test system in which the effect of medication on osteoporosis could be tested. Primary human BM-MSCs from osteoporotic donors were subjected to strontium ranelate (an osteoporotic drug marketed as Protelos®). Increased expression of collagen type 1 and calcification was seen in the drugtreated osteoporotic stem cells compared with the nondrug-treated osteoporotic stem cells. Thus, this bioreactor technology can easily be adapted into an in vitro osteoporotic drug testing system.
The small intestine represents a strong barrier separating the lumen from blood circulation thereby playing a major role in the absorption and the transport of pharmacological agents prior to their arrival on the respective target site. In order to gain more knowledge about specialized uptake mechanisms and risk assessment for the patient after oral admission of drugs, intestinal in vitro models demonstrating a close similarity to the in vivo situation are needed.
In the past, cell line-based in vitro models composed of Caco-2 cells cultured on synthetic cell carriers represented the “gold standard” in the field of intestinal tissue engineering. Expressive advantages of these models are a reproducible, cost-efficient and standardized model set up, but cell function can be negatively influenced by the low porosity or unwanted molecular adhesion effects of the artificial scaffold material. Natural extracellular matrices (ECM) such as the porcine decellularized small intestinal submucosa (SIS) are used as alternative to overcome some common drawbacks; however, the fabrication of these scaffolds is time- and cost-intensive, less well standardized and the 3Rs (replacement, reduction, refinement) principle is not entirely fulfilled. Nowadays, biopolymer-based scaffolds such as the bacterial nanocellulose (BNC) suggest an interesting option of novel intestinal tissue engineered models, as the BNC shows comparable features to the native ECM regarding fiber arrangement and hydrophilic properties. Furthermore, the BNC is of non-animal origin and the manufacturing process is faster as well as well standardized at low costs.
In this context, the first part of this thesis analyzed the BNC as alternative scaffold to derive standardized and functional organ models in vitro. Therefore, Caco-2 cells were cultured on two versions of BNC with respect to their surface topography, the unmodified BNC as rather smooth surface and the surface-structured BNC presenting an aligned fiber arrangement. As controls, Caco-2 in vitro models were set up on PET and SIS matrices. In this study, the BNC-based models demonstrated organ-specific properties comprising typical cellular morphologies, a characteristic tight junction protein expression profile, representative ultrastructural features and the formation of a tight epithelial barrier together with a corresponding transport activity. In summary, these results validated the high quality of the BNC-based Caco-2 models under cost-efficient conditions and their suitability for pre-clinical research purposes. However, the full functional diversity of the human intestine cannot be presented by Caco-2 cells due to their tumorigenic background and their exclusive representation of mature enterocytes.
Next to the scaffold used for the setup of in vitro models, the cellular unit mainly drives functional performance, which demonstrates the crucial importance of mimicking the cellular diversity of the small intestine in vitro. In this context, intestinal primary organoids are of high interest, as they show a close similarity to the native epithelium regarding their cellular diversity comprising enterocytes, goblet cells, enteroendocrine cells, paneth cells, transit amplifying cells and stem cells. In general, such primary organoids grow in a 3D Matrigel® based environment and a medium formulation supplemented with a variety of growth factors to maintain stemness, to inhibit differentiation and to stimulate cell migration supporting long term in vitro culture.
Intestinal primary spheroid/organoid cultures were set up as Transwell®-like models on both BNC variants, which resulted in a fragmentary cell layer and thereby unfavorable properties of these scaffold materials under the applied circumstances. As the BNC manufacturing process is highly flexible, surface properties could be adapted in future studies to enable a good cell adherence and barrier formation for primary intestinal cells, too. However, the application of these organoid cultures in pre-clinical research represents an enormous challenge, as the in vitro culture is complex and additionally time- and cost-intensive.
With regard to the high potential of primary intestinal spheroids/organoids and the necessity of a simplified but predictive model in pre-clinical research purposes, the second part of this thesis addressed the establishment of a primary-derived immortalized intestinal cell line, which enables a standardized and cost-efficient culture (including in 2D), while maintaining the cellular diversity of the organoid in vitro cultures. In this study, immortalization of murine and human intestinal primary organoids was induced by ectopic expression of a 10- (murine) or 12 component (human) pool of genes regulating stemness and the cell cycle, which was performed in cooperation with the InSCREENeX GmbH in a 2D- and 3D-based transduction strategy. In first line, the established cell lines (cell clones) were investigated for their cell culture prerequisites to grow under simplified and cost-efficient conditions. While murine cell clones grew on uncoated plastic in a medium formulation supplemented with EGF, Noggin, Y-27632 and 10% FCS, the human cell clones demonstrated the necessity of a Col I pre coating together with the need for a medium composition commonly used for primary human spheroid/organoid cultures. Furthermore, the preceding analyses resulted in only one human cell clone and three murine cell clones for ongoing characterization. Studies regarding the proliferative properties and the specific gene as well as protein expression profile of the remaining cell clones have shown, that it is likely that transient amplifying cells (TACs) were immortalized instead of the differentiated cell types localized in primary organoids, as 2D, 3D or Transwell®-based cultures resulted in slightly different gene expression profiles and in a dramatically reduced mRNA transcript level for the analyzed marker genes representative for the differentiated cell types of the native epithelium. Further, 3D cultures demonstrated the formation of spheroid-like structures; however without forming organoid-like structures due to prolonged culture, indicating that these cell populations have lost their ability to differentiate into specific intestinal cell types. The Transwell®-based models set up of each clone exhibit organ-specific properties comprising an epithelial-like morphology, a characteristic protein expression profile with an apical mucus-layer covering the villin-1 positive cell layer, thereby representing goblet cells and enterocytes, together with representative tight junction complexes indicating an integer epithelial barrier. The proof of a functional as well as tight epithelial barrier in TEER measurements and in vivo-like transport activities qualified the established cell clones as alternative cell sources for tissue engineered models representing the small intestine to some extent. Additionally, the easy handling and cell expansion under more cost-efficient conditions compared to primary organoid cultures favors the use of these newly generated cell clones in bioavailability studies.
Altogether, this work demonstrated new components, structural and cellular, for the establishment of alternative in vitro models of the small intestinal epithelium, which could be used in pre-clinical screenings for reproducible drug delivery studies.