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Every year, stroke affects over 100 million people worldwide and the number of cases continues to grow. Ischemic stroke is the most prevalent form of stroke and rapid restoration of blood flow is the primary therapeutic aim. However, recanalization might fail or reperfusion itself induces detrimental processes leading to infarct progression. Previous studies identified platelets and immune cells as drivers of this so-called ischemia/reperfusion (I/R) injury, establishing the concept of ischemic stroke as thrombo-inflammatory disease. Reduced cerebral blood flow despite recanalization promoted the hypothesis that thrombus formation within the cerebral microcirculation induces further tissue damage. The results presented in this thesis refute this: using complementary methodologies, it was shown that infarct growth precedes the occurrence of thrombi excluding them as I/R injury-underlying cause. Blood brain barrier disruption is one of the hallmarks of ischemic stroke pathology and was confirmed as early event during reperfusion injury in the second part of this study. Abolished platelet α-granule release protects mice from vascular leakage in the early reperfusion phase resulting in smaller infarcts. Using in vitro assays, platelet α-granule-derived PDGF-AB was identified as one factor contributing to blood-brain barrier disruption.
In vivo visualization of platelet activation would provide important insights in the spatio-temporal context of platelet activation in stroke pathology. As platelet signaling results in elevated intracellular Ca2+ levels, this is an ideal readout. To overcome the limitations of chemical calcium indicators, a mouse line expressing an endogenous calcium reporter specifically in platelets and megakaryocytes was generated. Presence of the reporter did not interfere with platelet function, consequently these mice were characterized in in vivo and ex vivo models.
Upon ischemic stroke, neutrophils are among the first cells that are recruited to the brain. Since for neutrophils both, beneficial and detrimental effects are described, their role was investigated within this thesis. Neither neutrophil depletion nor absence of NADPH-dependent ROS production (Ncf-/- mice) affected stroke outcome. In contrast, abolished NET-formation in Pad4-/- mice resulted in reduced infarct sizes, revealing detrimental effects of NETosis in the context of ischemic stroke, which might become a potential therapeutic target.
Cerebral venous (sinus) thrombosis, CV(S)T is a rare type of stroke with mainly idiopathic onset. Whereas for arterial thrombosis a critical contribution of platelets is known and widely accepted, for venous thrombosis this is less clear but considered more and more. In the last part of this thesis, it was shown that fab-fragments of the anti-CLEC-2 antibody INU1 trigger pathological platelet activation in vivo, resulting in foudroyant CVT accompanied by heavy neurological symptoms. Using this novel animal model for CVT, cooperative signaling of the two platelet receptors CLEC-2 and GPIIb/IIIa was revealed as major trigger of CVT and potential target for treatment.
Beinahe jeder dritte ischämische Schlaganfall ist ursächlich auf Erkrankungen des Herzens zurückzuführen. Daher empfehlen Leitlinien allen Patienten und Patientinnen, bei denen eine kardioembolische Ätiologie des Schlaganfalls vermutet wird und bei denen ein Vorhofflimmern nicht bereits bekannt ist, als Teil der Routinediagnostik eine echokardiographische Untersuchung, um Hinweise auf die Ätiologie des ischämischen Schlaganfalls zu gewinnen und um gegebenenfalls Maßnahmen zur Sekundärprävention einleiten zu können. Jedoch ist der Zugang zu solchen echokardiographischen Untersuchungen oftmals limitiert, besonders für Patienten und Patientinnen auf Stroke Units, denn dort überschreitet die Nachfrage häufig die verfügbaren personellen und instrumentellen Kapazitäten. Zudem stellt der Transport bettlägeriger Patienten und Patientinnen in andere Abteilungen eine Belastung dar.
Daher stellt sich die Frage, ob zukünftig im Rahmen wissenschaftlicher Studien POC-Echokardiographie-Geräte zur Diagnostik bestimmter Herzerkrankungen einschließlich einer systolischen Dysfunktion bei Patienten und Patientinnen mit ischämischem Schlaganfall eingesetzt werden können, mit dem Ziel Patienten und Patientinnen zu identifizieren, die von einer erweiterten echokardiographischen Untersuchung profitieren könnten. Im Rahmen der vorliegenden prospektiven Validierungsstudie untersuchte eine Studentin 78 Patienten und Patientinnen mit akutem ischämischem Schlaganfall mithilfe eines POC-Echokardiographie-Geräts auf der Stroke Unit der Neurologischen Abteilung des Universitätsklinikums Würzburg. Im Anschluss daran erhielten alle 78 Patienten und Patientinnen eine Kontrolluntersuchung durch eine erfahrene Echokardiographie-Raterin mithilfe eines SE-Geräts in einem externen Herzzentrum.
Die diagnostischen Qualitäten des POC-Echokardiographie-Geräts für Forschungszwecke zur fokussierten kardialen Diagnostik nach ischämischem Schlaganfall im Vergleich zu einer SE-Untersuchung konnten mithilfe der Validierungsstudie bestätigt werden. Es zeigte sich insbesondere, dass die POC-Echokardiographie für die Detektion einer LVEF≤55% mit einer Sensitivität von 100% geeignet war.
Um zu evaluieren, ob sich das POC-Echokardiographie-Gerät in Zukunft auch in der klinischen Praxis als Screeninginstrument eignet, mit dem Ziel eine individuelle Behandlung von Schlaganfallpatienten und -patientinnen zu gewährleisten, müssen größere, prospektive Studien durchgeführt werden, in denen die Fallzahl für bestimmte kardiologische Erkrankungen ausreichend hoch ist.
In mammals, anucleate platelets circulate in the blood flow and are primarily responsible for maintaining functional hemostasis. Platelets are generated in the bone marrow (BM) by megakaryocytes (MKs), which mainly reside directly next to the BM sinusoids to release proplatelets into the blood. MKs originate from hematopoietic stem cells and are thought to migrate from the endosteal to the vascular niche during their maturation, a process, which is, despite being intensively investigated, still not fully understood.
Long-term intravital two photon microscopy (2PM) of MKs and vasculature in murine bone marrow was performed and mean squared displacement analysis of cell migration was performed. The MKs exhibited no migration, but wobbling-like movement on time scales of 3 h. Directed cell migration always results in non-random spatial distribution. Thus, a computational modelling algorithm simulating random MK distribution using real 3D light-sheet fluorescence microscopy data sets was developed. Direct comparison of real and simulated random MK distributions showed, that MKs exhibit a strong bias to vessel-contact. However, this bias is not caused by cell migration, as non-vessel-associated MKs were randomly distributed in the intervascular space. Furthermore, simulation studies revealed that MKs strongly impair migration of other cells in the bone marrow by acting as large-sized obstacles. MKs are thought to migrate from the regions close to the endosteum towards the vasculature during their maturation process. MK distribution as a function of their localization relative to the endosteal regions of the bones was investigated by light sheet fluorescence microscopy (LSFM). The results show no bone-region dependent distribution of MKs. Taken together, the newly established methods and obtained results refute the model of MK migration during their maturation.
Ischemia reperfusion (I/R) injury is a frequent complication of cerebral ischemic stroke, where brain tissue damage occurs despite successful recanalization. Platelets, endothelial cells and immune cells have been demonstrated to affect the progression of I/R injury in experimental mouse models 24 h after recanalization. However, the underlying Pathomechanisms, especially in the first hours after recanalization, are poorly understood.
Here, LSFM, 2PM and complemental advanced image analysis workflows were established for investigation of platelets, the vasculature and neutrophils in ischemic brains. Quantitative analysis of thrombus formation in the ipsilateral and contralateral hemispheres at different time points revealed that platelet aggregate formation is minimal during the first 8 h after recanalization and occurs in both hemispheres. Considering that maximal tissue damage already is present at this time point, it can be concluded that infarct progression and neurological damage do not result from platelet aggregated formation. Furthermore, LSFM allowed to confirm neutrophil infiltration into the infarcted hemisphere and, here, the levels of endothelial cell marker PECAM1 were strongly reduced. However, further investigations must be carried out to clearly identify the role of neutrophils and the endothelial cells in I/R injury.