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This thesis concerned the design and examination of a scaffold for tissue engineering applications. The template for the presented scaffold came from nature itself: the intercellular space in tissues that provides structure and support to the cells of the respective tissue, known as extracellular matrix (ECM). Fibres are a predominant characteristic feature of ECM, providing adhesion sites for cell-matrix interactions. In this dissertation a fibrous mesh was generated using the electrospinning technique to mimic the fibrous structure of the ECM. Two base polymers were explored: a biodegradable polyester, poly(D,L-lactide-co-glycolide); and a functional PEG-based star polymer, NCO-sP(EO-stat-PO). This topic was described in three major parts: the first part was materials based, concerning the chemical design and characterisation of the polymer scaffolds; the focus was then shifted to the cellular response to this fibrous scaffold; and finally the in vivo performance of the material was preliminarily assessed. The first steps towards an electrospun mesh started with adjusting the spinning parameters for the generation of homogeneous fibres. As reported in Chapter 3 a suitable setup configuration was on the one hand comprised of a spinning solution that consisted of 28.5 w/v% PLGA RG 504 and 6 w/v% NCO-sP(EO-stat-PO) in 450 µL acetone, 50 µL DMSO and 10 µL of an aqueous trifluoroacetic acid solution. On the other hand an ideal spinning behaviour was achieved at process parameters such as a flow rate of 0.5 mL/h, spinneret to collector distance of 12-16 cm and a voltage of 13 kV. The NCO-sP(EO-stat-PO) containing fibres proved to be highly hydrophilic as the functional additive was present on the fibre surface. Furthermore, the fibres featured a bulk degradation pattern as a consequence of the proportion of PLGA. Besides the morphologic similarity to ECM fibres, the functionality of the electrospun fibres is also decisive for a successful ECM mimicry. In Chapter 4, the passive as well as active functionality of the fibres was investigated. The fibres were required to be protein repellent to prevent an unspecific cell adhesion. This was proven as even 6.5 % sP(EO-stat-PO) in the PLGA fibres reduced any unspecific protein adsorption of bovine serum albumin and foetal calf serum to less than 1 %. However, avidin based proteins attached to the fibres. This adhesion process was avoided by an additional fibre surface treatment with glycidol. The active functionalisation of NCO-sP(EO-stat-PO)/PLGA fibres was investigated with two fluorescent dyes and biocytin. A threefold, chemically orthogonal, fibre modification was achieved with these dyes. The chapters about the chemical and mechanical properties laid the basis for the in vitro chapters where a specific fibre functionalisation with peptides was conducted to analyse the cell adhesion and biochemical expressions. Beginning with fibroblasts in Chapter 5 the focus was on the specific cell adhesion on the electrospun fibres. While NCO-sP(EO-stat-PO)/PLGA fibres without peptides did not allow any adhesion of fibroblasts, a fibre modification with GRGDS (an adhesion mediating peptide sequence) induced the adhesion and spreading of human dermal fibroblasts on the fibrous scaffolds. The control sequence GRGES that has no adhesion mediating qualities did not lead to any cell adhesion as observed on fibres without modifications. While the experiments of Chapter 5 were a proof-of-concept, in Chapter 6 a possible application in cartilage tissue engineering was examined. Therefore, primary human chondrocytes were seeded on fibrous scaffolds with various peptide sequences. Though the chondrocytes exhibited high viability on all scaffolds, an active interaction of cells and fibres was only found for the decorin derived sequence CGKLER. Live-cell-imaging revealed both cell attachment and migration within CGKLER-modified meshes. As chondrocytes undergo a de-differentiation towards a fibroblast-like phenotype, the chondrogenic re-differentiation on these scaffolds was investigated in a long term cell culture experiment of 28 days. Therefore, the glycosaminoglycan production was analysed as well as the mRNA expression of genes coding for collagen I and II, aggrecan and proteoglycan 4. In general only low amounts of the chondrogenic markers were measured, suggesting no chondrogenic differentiation. For conclusive evidence follow-up experiments are required that support or reject the findings. The success of an implant for tissue engineering relies not only on the response of the targeted cell type but also on the immune reaction caused by leukocytes. Hence, Chapter 7 dealt with primary human macrophages and their behaviour and phenotype on two-dimensional (2D) surfaces compared to three-dimensional (3D) fibrous substrates. It was found that the general non-adhesiveness of NCO-sP(EO-stat-PO) surfaces and fibres does not apply to macrophages. The cells aligned along the fibres on surfaces or resided in the pores of the meshes. On flat surfaces without 3D structure the macrophages showed a retarded adhesion kinetic accompanied with a high migratory activity indicating their search for a topographical feature to adhere to. Moreover, a detailed investigation of cell surface markers and chemokine signalling revealed that macrophages on 2D surfaces exhibited surface markers indicating a healing phenotype while the chemokine release suggested a pro-inflammatory phenotype. Interestingly, the opposite situation was found on 3D fibrous substrates with pro-inflammatory surface markers and pro-angiogenic cytokine release. As the immune response largely depends on cellular communication, it was concluded that the NCO-sP(EO-stat-PO)/PLGA fibres induce an adequate immune response with promising prospects to be used in a scaffold for tissue engineering. The final chapter of this thesis reports on a first in vivo study conducted with the presented electrospun fibres. Here, the fibres were combined with a polypropylene mesh for the treatment of diaphragmatic hernias in a rabbit model. Two scaffold series were described that differed in the overall surface morphology: while the fibres of Series A were incorporated into a thick gel of NCO-sP(EO-stat-PO), the scaffolds of Series B featured only a thin hydrogel layer so that the overall fibrous structure could be retained. After four months in vivo the treated defects of the diaphragm were significantly smaller and filled mainly with scar tissue. Thick granulomas occurred on scaffolds of Series A while the implants of Series B did not induce any granuloma formation. As a consequence of the generally positive outcome of this study, the constructs were enhanced with a drug release system in a follow-up project. The incorporated drug was the MMP-inhibitor Ilomastat which is intended to reduce the formation of scar tissue. In conclusion, the simple and straight forward fabrication, the threefold functionalisation possibility and general versatile applicability makes the meshes of NCO-sP(EO-stat-PO)/PLGA fibres a promising candidate to be applied in tissue engineering scaffolds in the future.
Das Arbeitsgebiet Tissue Engineering befasst sich mit der Klärung der Mechanismen, die der Funktionen verschiedener Gewebearten zu Grunde liegen sowie mit der Entwicklung alternativer Strategien zur Behandlung von Organversagen bzw. Organverlusten. Einer der kritischsten Punkte im Tissue Engineering ist die ausreichende Versorgung der Zellen mit Nährstoffen und Sauerstoff. Bioartifizielle Gewebe mit einer Dicke von bis zu 200 µm können mittels Diffusion ausreichend versorgt werden. Für dickere Transplantate ist die Versorgung der Zellen alleine durch Diffusion jedoch nicht gegeben. Hierfür müssen Mechanismen und Strategien zur Prävaskularisierung der artifiziellen Gewebekonstrukte entwickelt werden, damit die Nährstoff- und Sauerstoffversorgung aller Zellen, auch im Inneren des Transplantates, von Anfang an gewährleistet ist. Eine wichtige Rolle bei der Prävaskularisierung spielt die Angiogenese. Dabei ist die Wahl einer geeigneten Zellquelle entscheidend, da die Zellen die Basis für die Angiogenese darstellen. Mikrovaskuläre Endothelzellen (mvEZ) sind maßgeblich an der Angiogenese beteiligt. Das Problem bei der Verwendung von humanen primären mvEZ ist ihre geringe Verfügbarkeit, ihre limitierte Proliferationskapazität und der schnelle Verlust ihrer typischen Endothelzellmarker in-vitro. Der Aufbau standardisierter in-vitro Testsysteme ist durch die geringe Zellausbeute auch nicht möglich. Die upcyte® Technologie bietet hierfür einen Lösungsansatz. In der vorliegenden Arbeit konnten upcyte® mvEZ als Alternative zu primären mvEZ generiert werden. Es konnte gezeigt werden, dass die Zellen eine erweiterte Proliferationsfähigkeit aufweisen und im Vergleich zu primären mvEZ durchschnittlich 15 zusätzliche Populationsverdopplungen leisten können. Dadurch ist es möglich 3x104-fach mehr upcyte® mvEZ eines Spenders zu generieren verglichen mit den korrespondierenden Primärzellen. Die gute und ausreichende Verfügbarkeit der Zellen macht sie interessant für die Standardisierung von in-vitro Testsystemen, ebenso können die Zellen zur Prävaskularisierung von Transplantaten eingesetzt werden. Upcyte® mvEZ zeigen zahlreiche Primärzellmerkmale, die in der Literatur beschrieben sind. Im konfluenten Zustand zeigen sie die für primäre mvEZ spezifische pflastersteinartige Morphologie. Darüber hinaus exprimieren upcyte® mvEZ typische Endothelzellmarker wie CD31, vWF, eNOS, CD105, CD146 und VEGFR-2 vergleichbar zu primären mvEZ. Eine weitere endothelzellspezifische Eigenschaft ist die Bindung von Ulex europaeus agglutinin I Lektin an die alpha-L-Fucose enthaltene Kohlenhydratstrukturen von mvEZs. Auch hier wurden upcyte® Zellen mit primären mvEZ verglichen und zeigten die hierfür charkteristischen Strukturen. Zusätzlich zu Morphologie, Proliferationskapazität und endothelzellspezifischen Markern, zeigen upcyte® mvEZ auch mehrere funktionelle Eigenschaften, welche in primären mvEZ beobachtet werden können, wie beispielsweise die Aufnahme von Dil-markiertem acetyliertem Low Density Lipoprotein (Dil-Ac-LDL) oder die Fähigkeit den Prozess der Angiognese zu unterstützen. Zusätzlich bilden Sphäroide aus upcyte® mvEZ dreidimensionale luminäre Zellformationen in einer Kollagenmatrix aus. Diese Charakteristika zeigen den quasi-primären Phänotyp der upcyte® mvEZs. Upcyte® mvEZ stellen darüber hinaus eine neuartige mögliche Zellquelle für die Generierung prävaskularisierter Trägermaterialien im Tissue Engineering dar. In der vorliegenden Arbeit konnte die Wiederbesiedlung der biologisch vaskularisierte Matrix (BioVaSc) mit upcyte® mvEZ vergleichbar zu primären mvEZ gezeigt werden. Der Einsatz von upcyte® mvEZ in der BioVaSc stellt einen neuen, vielversprechenden Ansatz zur Herstellung eines vaskularisierten Modells für Gewebekonstrukte dar, wie beispielsweise einem Leberkonstrukt. Zusammenfassend konnte in der vorliegenden Arbeit gezeigt werden, dass upcyte® mvEZ vergleichbar zu primären mvEZs sind und somit eine geeignete Alternative für die Generierung prävaskulierter Trägermaterialien und Aufbau von in-vitro Testsystemen darstellen. Darüber hinaus wurde ein neues, innovatives System für die Generierung einer perfundierten, mit Endothelzellen wiederbesiedelten Matrix für künstliches Gewebe in-vitro entwickelt.
Non-contact, Label-free Monitoring of Cells and Extracellular Matrix using Raman Spectroscopy
(2012)
Non-destructive, non-contact and label-free technologies to monitor cell and tissue cultures are needed in the field of biomedical research.1-5 However, currently available routine methods require processing steps and alter sample integrity. Raman spectroscopy is a fast method that enables the measurement of biological samples without the need for further processing steps. This laser-based technology detects the inelastic scattering of monochromatic light.6 As every chemical vibration is assigned to a specific Raman band (wavenumber in cm-1), each biological sample features a typical spectral pattern due to their inherent biochemical composition.7-9 Within Raman spectra, the peak intensities correlate with the amount of the present molecular bonds.1 Similarities and differences of the spectral data sets can be detected by employing a multivariate analysis (e.g. principal component analysis (PCA)).10
Here, we perform Raman spectroscopy of living cells and native tissues. Cells are either seeded on glass bottom dishes or kept in suspension under normal cell culture conditions (37 °C, 5% CO2) before measurement. Native tissues are dissected and stored in phosphate buffered saline (PBS) at 4 °C prior measurements. Depending on our experimental set up, we then either focused on the cell nucleus or extracellular matrix (ECM) proteins such as elastin and collagen. For all studies, a minimum of 30 cells or 30 random points of interest within the ECM are measured. Data processing steps included background subtraction and normalization.