Your search keyword '"Vera Flocke"' showing total 12 results

1. Magnetic resonance reveals early lipid deposition in murine prediabetes as predictive marker for cardiovascular injury

Author

Katja Heller, Vera Flocke, Tamara Straub, Zhaoping Ding, Tanu Srivastava, Melissa Nowak, Florian Funk, Bodo Levkau, Joachim Schmitt, Maria Grandoch, and Ulrich Flögel

Subjects

Medical technology, R855-855.5, Medical physics. Medical radiology. Nuclear medicine, R895-920

Abstract

Abstract People with diabetes have an increased cardiovascular risk and a poorer outcome after myocardial infarction (MI). However, the exact underlying mechanisms are still unclear, as is the question of which non-invasive measures could be used to predict the altered risk for the patient at early stages of the disease and adapt personalized treatment. Here, we used a holistic magnetic resonance approach to monitor longitudinally not only the main target heart, but also liver, peripheral/skeletal muscle, bone marrow, and hematopoiesis during disease development and subsequent MI. In prediabetic mice, we found a strong accumulation of lipids in all organs which preceded even a significant whole-body weight gain. Intramyocellular lipids (IMCLs) were most sensitive to reveal in vivo very early alterations in tissue properties during the prediabetic state. Subsequent induction of MI led to a persistent impairment of contractile function in septal/posterior segments of prediabetic hearts which correlated with their lipid load prior MI. At the same time, prediabetic cardiomyocytes exhibited sarcomere function at its limit resulting in overload and lower compensatory contractility of the healthy myocardium after MI. In summary, we identified IMCLs as very early marker in murine prediabetes and together with the cardiac lipid load as predictive for the functional outcome after MI.

Published

2024

2. Publisher Correction: Magnetic resonance reveals early lipid deposition in murine prediabetes as predictive marker for cardiovascular injury

Author

Katja Heller, Vera Flocke, Tamara Straub, Zhaoping Ding, Tanu Srivastava, Melissa Nowak, Florian Funk, Bodo Levkau, Joachim Schmitt, Maria Grandoch, and Ulrich Flögel

Subjects

Medical technology, R855-855.5, Medical physics. Medical radiology. Nuclear medicine, R895-920

Published

2024

3. Biodegradable polyphosphoester micelles act as both background-free 31P magnetic resonance imaging agents and drug nanocarriers

Author

Olga Koshkina, Timo Rheinberger, Vera Flocke, Anton Windfelder, Pascal Bouvain, Naomi M. Hamelmann, Jos M. J. Paulusse, Hubert Gojzewski, Ulrich Flögel, and Frederik R. Wurm

Subjects

Science

Abstract

Abstract In vivo monitoring of polymers is crucial for drug delivery and tissue regeneration. Magnetic resonance imaging (MRI) is a whole-body imaging technique, and heteronuclear MRI allows quantitative imaging. However, MRI agents can result in environmental pollution and organ accumulation. To address this, we introduce biocompatible and biodegradable polyphosphoesters, as MRI-traceable polymers using the 31P centers in the polymer backbone. We overcome challenges in 31P MRI, including background interference and low sensitivity, by modifying the molecular environment of 31P, assembling polymers into colloids, and tailoring the polymers’ microstructure to adjust MRI-relaxation times. Specifically, gradient-type polyphosphonate-copolymers demonstrate improved MRI-relaxation times compared to homo- and block copolymers, making them suitable for imaging. We validate background-free imaging and biodegradation in vivo using Manduca sexta. Furthermore, encapsulating the potent drug PROTAC allows using these amphiphilic copolymers to simultaneously deliver drugs, enabling theranostics. This first report paves the way for polyphosphoesters as background-free MRI-traceable polymers for theranostic applications.

Published

2023

4. Noninvasive assessment of metabolic turnover during inflammation by in vivo deuterium magnetic resonance spectroscopy

Author

Vera Flocke, Sebastian Temme, Pascal Bouvain, Maria Grandoch, and Ulrich Flögel

Subjects

inflammation, metabolism, neutrophils, glycolysis, deuterium, magnetic resonance spectroscopy and imaging, Immunologic diseases. Allergy, RC581-607

Abstract

BackgroundInflammation and metabolism exhibit a complex interplay, where inflammation influences metabolic pathways, and in turn, metabolism shapes the quality of immune responses. Here, glucose turnover is of special interest, as proinflammatory immune cells mainly utilize glycolysis to meet their energy needs. Noninvasive approaches to monitor both processes would help elucidate this interwoven relationship to identify new therapeutic targets and diagnostic opportunities.MethodsFor induction of defined inflammatory hotspots, LPS-doped Matrigel plugs were implanted into the neck of C57BL/6J mice. Subsequently, 1H/19F magnetic resonance imaging (MRI) was used to track the recruitment of 19F-loaded immune cells to the inflammatory focus and deuterium (2H) magnetic resonance spectroscopy (MRS) was used to monitor the metabolic fate of [6,6-2H2]glucose within the affected tissue. Histology and flow cytometry were used to validate the in vivo data.ResultsAfter plug implantation and intravenous administration of the 19F-containing contrast agent, 1H/19F MRI confirmed the infiltration of 19F-labeled immune cells into LPS-doped plugs while no 19F signal was observed in PBS-containing control plugs. Identification of the inflammatory focus was followed by i.p. bolus injection of deuterated glucose and continuous 2H MRS. Inflammation-induced alterations in metabolic fluxes could be tracked with an excellent temporal resolution of 2 min up to approximately 60 min after injection and demonstrated a more anaerobic glucose utilization in the initial phase of immune cell recruitment.Conclusion1H/2H/19F MRI/MRS was successfully employed for noninvasive monitoring of metabolic alterations in an inflammatory environment, paving the way for simultaneous in vivo registration of immunometabolic data in basic research and patients.

Published

2023

5. High-throughput screening of caterpillars as a platform to study host–microbe interactions and enteric immunity

Author

Anton G. Windfelder, Frank H. H. Müller, Benedict Mc Larney, Michael Hentschel, Anna Christina Böhringer, Christoph-Rüdiger von Bredow, Florian H. Leinberger, Marian Kampschulte, Lorenz Maier, Yvette M. von Bredow, Vera Flocke, Hans Merzendorfer, Gabriele A. Krombach, Andreas Vilcinskas, Jan Grimm, Tina E. Trenczek, and Ulrich Flögel

Subjects

Science

Abstract

Here, combining diagnostic imaging modalities and in vivo assays, Windfelder and colleagues established tobacco hornworm larvae Manduca sexta as an alternative high-throughput platform to study the innate immunity of the gut and host-pathogen interactions. Using the platform, the authors identify mediators of gut inflammation, differentiate pathogens from gut mutualist bacteria, and demonstrate pharmacological interventions.

Published

2022

6. Dynamic monitoring of vital functions and tissue re-organization in Saturnia pavonia (Lepidoptera, Saturniidae) during final metamorphosis by non-invasive MRI

Author

Tim Laussmann, Paul Urspruch, Vera Flocke, Anton G. Windfelder, Hermann Aberle, Klaus Lunau, and Ulrich Flögel

Subjects

Medicine, Science

Abstract

Abstract Magnetic resonance imaging (MRI) is the key whole-body imaging technology for observing processes within a living object providing excellent resolution and contrast between soft tissues. In the present work, we exploited the non-destructive properties of MRI to track longitudinally the dynamic changes that take place in developing pupae of the Emperor Moth (Saturnia pavonia) during the last days before eclosion. While in diapause pupae, body fluid was almost homogeneously distributed over the internal compartments, as soon as wings, legs, flight muscles and the head region were fully developed, a significant redistribution of water levels occurred between thoracic and abdominal regions. During the last two days before eclosion, the developing moths transferred substantial amounts of liquid into the gut and the labial gland, and in case of females, into developing eggs. Concomitantly, the volume of the air sacs increased drastically and their expansion/compression became clearly visible in time-resolved MR images. Furthermore, besides ventilation of the tracheal system, air sacs are likely to serve as volume reservoir for liquid transfer during development of the moths inside their pupal case. In parallel, we were able to monitor noninvasively lipid consumption, cardiac activity and haemolymph circulation during final metamorphosis.

Published

2022

7. Multi-targeted 1H/19F MRI unmasks specific danger patterns for emerging cardiovascular disorders

Author

Ulrich Flögel, Sebastian Temme, Christoph Jacoby, Thomas Oerther, Petra Keul, Vera Flocke, Xiaowei Wang, Florian Bönner, Fabian Nienhaus, Karlheinz Peter, Jürgen Schrader, Maria Grandoch, Malte Kelm, and Bodo Levkau

Subjects

Science

Abstract

The prediction of major cardiovascular events is still an unsolved problem. Here, the authors present a multi-color, multi-targeted non-invasive imaging technology that allows reliable in vivo identification of silent but prognostically highly relevant danger patterns prior to myocardial infarction in mice.

Published

2021

8. Phagocytosis of a PFOB-Nanoemulsion for 19F Magnetic Resonance Imaging: First Results in Monocytes of Patients with Stable Coronary Artery Disease and ST-Elevation Myocardial Infarction

Author

Fabian Nienhaus, Denise Colley, Annika Jahn, Susanne Pfeiler, Vera Flocke, Sebastian Temme, Malte Kelm, Norbert Gerdes, Ulrich Flögel, and Florian Bönner

Subjects

19F MRI, phagocytosis, monocytes, perfluorocarbons, perfluorooctyl bromide, PFOB, STEMI, inflammation, Organic chemistry, QD241-441

Abstract

Fluorine-19 magnetic resonance imaging (19F MRI) with intravenously applied perfluorooctyl bromide-nanoemulsions (PFOB-NE) has proven its feasibility to visualize inflammatory processes in experimental disease models. This approach is based on the properties of monocytes/macrophages to ingest PFOB-NE particles enabling specific cell tracking in vivo. However, information on safety (cellular function and viability), mechanism of ingestion and impact of specific disease environment on PFOB-NE uptake is lacking. This information is, however, crucial for the interpretation of 19F MRI signals and a possible translation to clinical application. To address these issues, whole blood samples were collected from patients with acute ST-elevation myocardial infarction (STEMI), stable coronary artery disease (SCAD) and healthy volunteers. Samples were exposed to fluorescently-labeled PFOB-NE and particle uptake, cell viability and migration activity was evaluated by flow cytometry and MRI. We were able to show that PFOB-NE is ingested by human monocytes in a time- and subset-dependent manner via active phagocytosis. Monocyte function (migration, phagocytosis) and viability was maintained after PFOB-NE uptake. Monocytes of STEMI and SCAD patients did not differ in their maximal PFOB-NE uptake compared to healthy controls. In sum, our study provides further evidence for a safe translation of PFOB-NE for imaging purposes in humans.

Published

2019

9. Non-invasive mapping of systemic neutrophil dynamics upon cardiovascular injury

Author

Pascal Bouvain, Zhaoping Ding, Shiwa Kadir, Patricia Kleimann, Nils Kluge, Zeynep-Büsra Tiren, Bodo Steckel, Vera Flocke, Ria Zalfen, Patrick Petzsch, Thorsten Wachtmeister, Gordon John, Nirojah Subramaniam, Wolfgang Krämer, Tobias Strasdeit, Mehrnaz Mehrabipour, Jens M. Moll, Rolf Schubert, Mohammad Reza Ahmadian, Florian Bönner, Udo Boeken, Ralf Westenfeld, Daniel Robert Engel, Malte Kelm, Jürgen Schrader, Karl Köhrer, Maria Grandoch, Sebastian Temme, and Ulrich Flögel

Abstract

Neutrophils play a complex role during onset of tissue injury and subsequent resolution and healing. To assess neutrophil dynamics upon cardiovascular injury, here we develop a non-invasive, background-free approach for specific mapping of neutrophil dynamics by whole-body magnetic resonance imaging using targeted multimodal fluorine-loaded nanotracers engineered with binding peptides specifically directed against murine or human neutrophils. Intravenous tracer application before injury allowed non-invasive three-dimensional visualization of neutrophils within their different hematopoietic niches over the entire body and subsequent monitoring of their egress into affected tissues. Stimulated murine and human neutrophils exhibited enhanced labeling due to upregulation of their target receptors, which could be exploited as an in vivo readout for their activation state in both sterile and nonsterile cardiovascular inflammation. This non-invasive approach will allow us to identify hidden origins of bacterial or sterile inflammation in patients and also to unravel cardiovascular disease states on the verge of severe aggravation due to enhanced neutrophil infiltration or activation.

Published

2023

10. Biodegradable Polyphosphoester Micelles Act as Both Background-free 31P Magnetic Resonance Imaging Agents and Drug Nanocarriers

Author

Olga Koshkina, Timo Rheinberger, Vera Flocke, Anton Windfelder, Pascal Bouvain, Naomi M. Hamelmann, Jos M.J. Paulusse, Hubert Hubert Gojzewski, Ulrich Flögel, and Frederik Wurm

Abstract

Imaging and tracing materials inside the body is essential to develop functional materials for personalized therapies, including drug delivering nanocarriers and artificial tissues. Magnetic Resonance Imaging (MRI) is a key whole-body imaging technology, where heteronuclear MRI agents enable background-free, quantitative labeling. However, many MRI agents raised concerns due to environmental pollution and organ accumulation. As a solution, we developed a biodegradable, biocompatible polymer platform for heteronuclear 31P magnetic resonance imaging (MRI). We introduce polyphosphoester colloids for heteronuclear MRI using 31P-nucleus. 31P MRI has been severely hampered by unfavorable magnetic resonance properties of 31P, including intrinsic background and low sensitivity. We overcame these fundamental challenges in imaging of 31P by tailoring molecular and structural features of polymeric colloids. We have synthesized gradient-type polyphosphonate copolymers that self-assemble into well-defined micelles. The gradient leads to favorable MRI characteristics compared with homo- and block copolymers. Background-free imaging and biodegradation were proven in vivo in Manduca sexta. Furthermore, we demonstrate by encapsulation of the potent drug PROTAC ARV-825 that these amphiphilic copolymers can simultaneously deliver hydrophobic drugs and thus enable theranostics. We present a unique platform of biocompatible, degradable polyphosphoesters that inherently act as background-free MRI agents and delivery vehicles.

Published

2022

11. Ontological Expressivism

Author

Vera Flocke

Abstract

Ontological expressivism is the view that ontological existence claims express noncognitive mental states. The chapter develops a version of ontological expressivism that is modeled after Gibbard’s (2003) norm-expressivism. It argues that, when speakers assess whether, say, composite objects exist, they rely on assumptions with regard to what is required for composition to occur. These assumptions guide their assessment, similar to how norms may guide the assessment of normative propositions. Against this backdrop, the chapter argues that “some objects have parts”, uttered in the context of an ontological disagreement, expresses a noncognitive disposition to assess the truth of propositions by using only rules of assessment according to which the proposition that some objects have parts is to be evaluated as true.

Published

2021

12. Multiparametric MRI identifies subtle adaptations for demarcation of disease transition in murine aortic valve stenosis

Author

Christine Quast, Frank Kober, Katrin Becker, Elric Zweck, Jasmina Hoffe, Christoph Jacoby, Vera Flocke, Isabella Gyamfi-Poku, Fabian Keyser, Kerstin Piayda, Ralf Erkens, Sven Niepmann, Matti Adam, Stephan Baldus, Sebastian Zimmer, Georg Nickenig, Maria Grandoch, Florian Bönner, Malte Kelm, Ulrich Flögel, Cardiovascular Research Laboratory, Division of Cardiology, Pulmonary Diseases and Vascular Medicine, Centre de résonance magnétique biologique et médicale (CRMBM), Aix Marseille Université (AMU)-Assistance Publique - Hôpitaux de Marseille (APHM)-Centre National de la Recherche Scientifique (CNRS), University Hospital Bonn, and Clinic for Cardiology, University Hospital Cologne

Subjects

[SDV.IB.IMA]Life Sciences [q-bio]/Bioengineering/Imaging, Physiology, Aortic Valve Stenosis, Vessel wall remodelling, Ventricular Function, Left, Mice, Tissue characterization, Echocardiography, Physiology (medical), Aortic Valve, Aortic flow patterns, Animals, Multiparametric Magnetic Resonance Imaging, Cardiology and Cardiovascular Medicine, MRI

Abstract

Aortic valve stenosis (AS) is the most frequent valve disease with relevant prognostic impact. Experimental model systems for AS are scarce and comprehensive imaging techniques to simultaneously quantify function and morphology in disease progression are lacking. Therefore, we refined an acute murine AS model to closely mimic human disease characteristics and developed a high-resolution magnetic resonance imaging (MRI) approach for simultaneous in-depth analysis of valvular, myocardial as well as aortic morphology/pathophysiology to identify early changes in tissue texture and critical transition points in the adaptive process to AS. AS was induced by wire injury of the aortic valve. Four weeks after surgery, cine loops, velocity, and relaxometry maps were acquired at 9.4 T to monitor structural/functional alterations in valve, aorta, and left ventricle (LV). In vivo MRI data were subsequently validated by histology and compared to echocardiography. AS mice exhibited impaired valve opening accompanied by significant valve thickening due to fibrotic remodelling. While control mice showed bell-shaped flow profiles, AS resulted not only in higher peak flow velocities, but also in fragmented turbulent flow patterns associated with enhanced circumferential strain and an increase in wall thickness of the aortic root. AS mice presented with a mild hypertrophy but unaffected global LV function. Cardiac MR relaxometry revealed reduced values for both T1 and T2 in AS reflecting subtle myocardial tissue remodelling with early alterations in mitochondrial function in response to the enhanced afterload. Concomitantly, incipient impairments of coronary flow reserve and myocardial tissue integrity get apparent accompanied by early troponin release. With this, we identified a premature transition point with still compensated cardiac function but beginning textural changes. This will allow interventional studies to explore early disease pathophysiology and novel therapeutic targets.

Published

2021