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Die in vitro-Langzeitkultivierung von Zellen in einer Drei-Dimensionalen Matrix (3D-Matrix) stellt nach wie vor eine Herausforderung im Tissue engineering dar. Die Kultivierung von Zellen auf/in komplexen 3D-Trägern erfordert hohe Zellzahlen und lange Kulturzeiten. Um die Probleme des schnellen Mediumverbrauches und der limitierten Zellzahl bzw. Zelldichte in konventionellen Kulturmethoden zu umgehen, wurde ein „Zweikreis-Perfusionssystem“ entwickelt. Hierzu wurde ein Cell-Pharm System (Cell-Pharm System 100®-Basisgerät) modifi-ziert. Das Grundprinzip des Systems besteht darin, dass ein kleinvolumiger (50-70 ml) „Zellkultur-Kreislauf“ über einen Bioreaktor (semipermeable Hohlfasermembran) durch einen großvolumigen (1000 ml) „Regenerations-Kreislauf“ kontinuierlich im Gegenstromprinzip regeneriert wird. Die Regulation des ph-Wertes und der Sauerstoffsättigung des Kulturmediums geschieht über einen integrierten, Druckluft-CO2-begasten Oxygenator. Während die Zirkulationsgeschwindigkeit (Durchflussrate) und Temperatur (37°C) im Regenerations-Kreislauf konstant gehalten werden, lassen sich diese Parameter im „Zellkultur-Kreislauf“ beliebig variieren. Es hat sich gezeigt, dass sich auf diese Weise kontinuierlich über einen langen Zeitraum ohne Mediumwechsel konstante und optimale Milieuverhältnisse in beiden Mediumkompartments einstellen lassen. Zur Untersuchung der Wachstumseigenschaften von Zellen in diesem Perfusions-system wurden humane osteoblastenähnliche Zellen oder Ratten-Knochenmarkszellen auf eine Matrix aus demineralisierter, GuHCl-extrahierter Rinderspongiosa unterschiedlicher Größe (Zylinder zwischen 5x3 mm und 5x10 mm) aufgetragen. Unter intermittierender Perfusion der Kulturkammern (z.B. Minucells cell container®) mit 50-70 ml/d kam es zu einem gleichmäßigen, intertrabekulären Wachstum der Zellen innerhalb des gesamten Trägers. Nach 6-8 Wochen konnte immer noch ein dichtes Netz interdigitierender ALP-positiver osteoblastenähnlicher Zellen innerhalb der gesamten Matrix beobachtet werden. Dabei scheint die physikalisch-mechanische Komponente der „Umspülung“ der Zellen mit dem kontinuierlich regenerierten Nährmedium einen positiven Einfluss auf das Anwachsverhalten und Proliferation der Zellen zu haben. Somit erlaubt das modifizierten „Zweikreisperfusionssystem“ eine gute Möglichkeit für die Langzeitperfusionskultur in einem geschlossenen System mit indi-viduell steuerbaren Strömungsverhältnissen im Zellkompartment bei einer kontinuierlichen Regeneration des Mediums.
Osteocytes and their cell processes reside in a large, interconnected network of voids pervading the mineralized bone matrix of most vertebrates. This osteocyte lacuno-canalicular network (OLCN) is believed to play important roles in mechanosensing, mineral homeostasis, and for the mechanical properties of bone. While the extracellular matrix structure of bone is extensively studied on ultrastructural and macroscopic scales, there is a lack of quantitative knowledge on how the cellular network is organized. Using a recently introduced imaging and quantification approach, we analyze the OLCN in different bone types from mouse and sheep that exhibit different degrees of structural organization not only of the cell network but also of the fibrous matrix deposited by the cells. We define a number of robust, quantitative measures that are derived from the theory of complex networks. These measures enable us to gain insights into how efficient the network is organized with regard to intercellular transport and communication. Our analysis shows that the cell network in regularly organized, slow-growing bone tissue from sheep is less connected, but more efficiently organized compared to irregular and fast-growing bone tissue from mice. On the level of statistical topological properties (edges per node, edge length and degree distribution), both network types are indistinguishable, highlighting that despite pronounced differences at the tissue level, the topological architecture of the osteocyte canalicular network at the subcellular level may be independent of species and bone type. Our results suggest a universal mechanism underlying the self-organization of individual cells into a large, interconnected network during bone formation and mineralization.
Autologous bone still represents today’s gold standard for the treatment of critical size bone defects and fracture non-unions despite associated disadvantages regarding limitations in availability, donor site morbidity, costs and efficacy. Bone tissue engineered constructs would present a promising alternative to currently available treatments. However, research on preclinical animal studies still fails to provide clinical applicable results able to allow the replacement of currently applied methods. It seems that the idea of bone tissue engineering, which has now been integral part of academic studies for over 30 years, got somehow stuck at an intermediate level, in between intense preclinical research and striven stages of initial clinical trial phases. A clear discrepancy exists between the number of studies with preclinical animal models for bone tissue engineering and the number of clinically approved bone tissue engineered constructs available to patients.
The aim of this thesis was hence to evaluate preclinical animal models for bone tissue engineering as well as the perception of scientists and clinicians towards these models. Moreover, the general role of bone tissue engineering and its clinical need assessed by scientists and surgeons was investigated. A survey was conducted questioning both scientific and clinical opinions on currently available study designs and researchers’ satisfaction with preclinical animal models. Additionally, a literature research was conducted, resulting in 167 papers from the last 10 years that report current designs of preclinical orthotopic animal studies in bone tissue engineering. Thereby, the focus lied on the description of the models regarding animal species, strain, age, gender and defect design. The outcome of the literature search was evaluated and compared to the outcome obtained from the survey.
The survey data revealed that both scientists and surgeons generally remain positive about the future role of bone tissue engineering and its step to clinical translation, at least in the distant future, where it then might replace the current gold standard, autologous bone. Moreover, most of the participants considered preclinical animal models as relevant and well developed but the results as not yet realizable in the clinics. Surgeons thereby demonstrated a slightly more optimistic perception of currently conducted research with animal models compared to scientists. However, a rather inconsistent description of present preclinical study designs could be discerned when evaluating the reported study designs in the survey and the papers of the literature search.
Indeed, defining an appropriate animal species, strain, age, gender, observation time, observation method and surgical design often depends on different indications and research questions and represents a highly challenging task for the establishment of a preclinical animal model. The existing lack of valid guidelines for preclinical testing of bone tissue engineering leads hence to a lack of well standardized preclinical animal models. Moreover, still existing knowledge gaps regarding aspects that affect the process of fracture healing, such as vascularization or immunological aspects, were found to hinder clinical translation of bone tissue engineered constructs.
Using literature review and survey, this thesis points out critical issues that need to be addressed to allow clinical translation of bone tissue engineered constructs. It can be concluded that currently existing study designs with preclinical animal models cannot live up to the claim of providing suitable results for clinical implementation. The here presented comprehensive summary of currently used preclinical animal models for bone tissue engineering reveals a missing consensus on the usage of models such as an apparent lack of reporting and standardization regarding the study designs described in both papers from the literature review and the survey. It thereby indicates a crucial need to improve preclinical animal models in order to allow clinical translation. Despite the fact that participants of the survey generally revealed a positive perception towards the use of bone tissue engineered constructs and affirmed the clinical need for such novel designs, the missing standardization constitutes a main weak point for the provision of reliable study outcome and the translational success of the models. The optimization of reproducibility and reliability, as well as the further understanding of ongoing mechanisms in bone healing in order to develop effective tissue engineered constructs, need to form the basis of all study designs. The study outcomes might then fulfill the requirements of maybe today's and hopefully tomorrow's aging population.
The MEK5/ERK5 mitogen-activated protein kinases (MAPK) cascade is a unique signaling module activated by both mitogens and stress stimuli, including cytokines, fluid shear stress, high osmolarity, and oxidative stress. Physiologically, it is mainly known as a mechanoreceptive pathway in the endothelium, where it transduces the various vasoprotective effects of laminar blood flow. However, it also maintains integrity in other tissues exposed to mechanical stress, including bone, cartilage, and muscle, where it exerts a key function as a survival and differentiation pathway. Beyond its diverse physiological roles, the MEK5/ERK5 pathway has also been implicated in various diseases, including cancer, where it has recently emerged as a major escape route, sustaining tumor cell survival and proliferation under drug stress. In addition, MEK5/ERK5 dysfunction may foster cardiovascular diseases such as atherosclerosis. Here, we highlight the importance of the MEK5/ERK5 pathway in health and disease, focusing on its role as a protective cascade in mechanical stress-exposed healthy tissues and its function as a therapy resistance pathway in cancers. We discuss the perspective of targeting this cascade for cancer treatment and weigh its chances and potential risks when considering its emerging role as a protective stress response pathway.
Approaches to mimic the complexity of the skeletal mesenchymal stem/stromal cell niche in vitro
(2019)
Mesenchymal stem/stromal cells (MSCs) are an essential element of most modern tissue engineering and regenerative medicine approaches due to their multipotency and immunoregulatory functions. Despite the prospective value of MSCs for the clinics, the stem cells community is questioning their developmental origin, in vivo localization, identification, and regenerative potential after several years of far-reaching research in the field. Although several major progresses have been made in mimicking the complexity of the MSC niche in vitro, there is need for comprehensive studies of fundamental mechanisms triggered by microenvironmental cues before moving to regenerative medicine cell therapy applications. The present comprehensive review extensively discusses the microenvironmental cues that influence MSC phenotype and function in health and disease – including cellular, chemical and physical interactions. The most recent and relevant illustrative examples of novel bioengineering approaches to mimic biological, chemical, and mechanical microenvironmental signals present in the native MSC niche are summarized, with special emphasis on the forefront techniques to achieve bio-chemical complexity and dynamic cultures. In particular, the skeletal MSC niche and applications focusing on the bone regenerative potential of MSC are addressed. The aim of the review was to recognize the limitations of the current MSC niche in vitro models and to identify potential opportunities to fill the bridge between fundamental science and clinical application of MSCs.
Bioactive glass (BG) scaffolds are being investigated for bone tissue engineering applications because of their osteoconductive and angiogenic nature. However, to increase the in vivo performance of the scaffold, including enhancing the angiogenetic growth into the scaffolds, some researchers use different modifications of the scaffold including addition of inorganic ionic components to the basic BG composition. In this study, we investigated the in vitro biocompatibility and bioactivity of Cu2+-doped BG derived scaffolds in either BMSC (bone-marrow derived mesenchymal stem cells)-only culture or co-culture of BMSC and human dermal microvascular endothelial cells (HDMEC). In BMSC-only culture, cells were seeded either directly on the scaffolds (3D or direct culture) or were exposed to ionic dissolution products of the BG scaffolds, kept in permeable cell culture inserts (2D or indirect culture). Though we did not observe any direct osteoinduction of BMSCs by alkaline phosphatase (ALP) assay or by PCR, there was increased vascular endothelial growth factor (VEGF) expression, observed by PCR and ELISA assays. Additionally, the scaffolds showed no toxicity to BMSCs and there were healthy live cells found throughout the scaffold. To analyze further the reasons behind the increased VEGF expression and to exploit the benefits of the finding, we used the indirect method with HDMECs in culture plastic and Cu2+-doped BG scaffolds with or without BMSCs in cell culture inserts. There was clear observation of increased endothelial markers by both FACS analysis and acetylated LDL (acLDL) uptake assay. Only in presence of Cu2+-doped BG scaffolds with BMSCs, a high VEGF secretion was demonstrated by ELISA; and typical tubular structures were observed in culture plastics. We conclude that Cu2+-doped BG scaffolds release Cu2+, which in turn act on BMSCs to secrete VEGF. This result is of significance for the application of BG scaffolds in bone tissue engineering approaches.
Knochenklebstoffe, welche eine unkonventionelle Möglichkeit im Bereich der chirurgischen Frakturversorgung darstellen, müssen bereits in vitro eine Reihe an klinischen Anforderungen erfüllen. Hinsichtlich entsprechender Prüfverfahren wurde noch keine Normierungsarbeit geleistet, weswegen Ergebnisse verschiedener Arbeiten schwierig vergleichbar sind.
Ziel der Arbeit war es daher Prüfverfahren vorzustellen, welche die Besonderheiten des „Werkstoffes Knochen“ berücksichtigen. In diesem Rahmen werden zwei neuartigen Klebstoffsysteme, ein in situ härtender Knochenzement aus Trimagnesiumphosphat, Magnesiumoxid und organischer Phytinsäure und ein lichthärtender Knochenklebstoff aus Polyethylenglycoldimethacrylat, NCO-sP(EO-stat-PO), Campherchinon und anorganischen Newberyit-Füllern, vorgestellt. Neben diesen sind drei kommerziell erhältliche Klebstoffe Gegenstand der Untersuchung. Dies sind zum einen Histoacryl® und TruGlue® Gewebekleber, zwei Klebstoffe auf Cyanoacrylat-Basis mit unterschiedlich langer Alkyl-Seitenkette, zum anderen Bioglue®, ein Gewebekleber aus Albumin und Glutaraldehyd.
Bei den Klebstoffen wurde die Zug- und Scherfestigkeit unter Einfluss der physiologischen Klebstoffalterung, der Variation der Klebefugenbreite, der Variation von komplementären Fügeteilen, sowie Fügeteiloberflächen inspiziert. Makro- und mikroskopische, sowie elektronenmikroskopischen Untersuchung der Bruchflächen auf mikrostrukturelle Besonderheiten und Versagemechanismus wurden angestellt.
Die neuartigen Klebstoffsysteme unterliegen zwar den konventionellen Cyanoacrylaten hinsichtlich mechanischer Parameter, weisen aber dennoch adäquate Klebefestigkeiten auf bei zugleich zahlreichen Vorteilen gegenüber konventionellen Systemen im Umgang mit Knochen.
Gerade der Magnesiumphosphatzement scheint auf Grund mechanischer Parameter und Vorzügen wie der guten Biokompatibilität und biologischen Abbaubarkeit, Osteoinduktivität, Osteokonduktivität, der einfachen Applizierbarkeit, einem hohen Kosten-Nutzen-Faktor oder dem günstigen Verhalten in wässrigen Milieu vielversprechend.
Knochendefekte, die in der Behandlung von gutartigen Knochentumoren und tumorähnlichen Läsionen entstehen, stellen ein klinisches Problem mit limitierten Therapieoptionen dar. In der Regel werden diese Defekte mit autologem Knochen aufgefüllt. Die Gewinnung von autologem Knochen, z. B. vom Beckenkamm ist jedoch quantitativ limitiert und häufig mit Komplikationen verbunden. Aus diesem Grund wird versucht, synthetische Knochenersatzmaterialien mit ähnlichen Eigenschaften, wie denen des autologen Knochens, zu entwickeln. In der vorliegenden prospektiven Studie wurde die Anwendung einer biphasischen Keramik aus 60% Hydroxylapatit und 40% beta-Tricalciumphosphat in Verbindung mit verdünntem Fibrinkleber für die Therapie von gutartigen Knochentumoren und tumorähnlichen Läsionen bei 51 Patienten untersucht. Hierfür wurden die Röntgenbilder analysiert und das Resorptionsverhalten beurteilt. Eine komplette Resorption wurde anhand der radiologischen Verläufe in keinem Fall beobachtet. Die günstigsten Voraussetzungen für eine Resorption wurde bei kleinen Defekten (< 10,5 cm³) beobachtet (p < 0,05). Die übrigen Einflussgrößen zeigten nach einer Nachuntersuchungszeit von bis zu 56 Monaten keine statistisch signifikanten Unterschiede. In der histologischen Untersuchung eines Präparates bei einer Revision wurde Knochenneubildung auf dem Knochenersatzmaterial nachgewiesen. In diesem Fall war das Knochenersatzmaterial noch nachweisbar. Die Verwendung des Materials ist klinisch einfach und sicher. Die aufgetrete-nen Komplikationen entsprechen in ihrer Häufigkeit den zu erwartenden postoperativen Komplikationen und sind mit den Angaben der Literatur vergleichbar. Es wurden keine postoperativen Frakturen oder Beeinträchtigung des Längenwachstums von Röhrenknochen beobachtet. In einem Fall musste aufgrund eines intraossären Ganglions eine operative Revision erfolgen. In der histologischen Aufarbeitung dieser Biopsie konnte Knochenneubildung und Osseointegration sowie eine partielle Resorption des Knochenersatzmaterials nachgewiesen werden. Die Verwendung des Knochenersatzmaterials wird von den Patienten überwiegend als positiv beurteilt. Zusammenfassend ist das verwendete Knochenersatzmaterial eine einfach und sicher anzuwendende Alternative zu autologem Knochen in der Therapie von gutartigen Knochentumoren und tumorähnlichen Läsionen.
The skeletal system forms the mechanical structure of the body and consists of bone, which is hard connective tissue. The tasks the skeleton and bones take over are of mechanical, metabolic and synthetic nature. Lastly, bones enable the production of blood cells by housing the bone marrow. Bone has a scarless self-healing capacity to a certain degree. Injuries exceeding this capacity caused by trauma, surgical removal of infected or tumoral bone or as a result from treatment-related osteonecrosis, will not heal. Critical size bone defects that will not heal by themselves are still object of comprehensive clinical investigation. The conventional treatments often result in therapies including burdening methods as for example the harvesting of autologous bone material. The aim of this thesis was the creation of a prevascularized bone implant employing minimally invasive methods in order to minimize inconvenience for patients and surgical site morbidity. The basis for the implant was a decellularized, naturally derived vascular scaffold (BioVaSc-TERM®) providing functional vessel structures after reseeding with autologous endothelial cells. The bone compartment was built by the combination of the aforementioned scaffold with synthetic β-tricalcium phosphate. In vitro culture for tissue maturation was performed using bioreactor technology before the testing of the regenerative potential of the implant in large animal experiments in sheep. A tibia defect was treated without the anastomosis of the implant’s innate vasculature to the host’s circulatory system and in a second study, with anastomosis of the vessel system in a mandibular defect. While the non-anastomosed implant revealed a mostly osteoconductive effect, the implants that were anastomosed achieved formation of bony islands evenly distributed over the defect.
In order to prepare preconditions for a rapid approval of an implant making use of this vascularization strategy, the manufacturing of the BioVaSc-TERM® as vascularizing scaffold was adjusted to GMP requirements.