Your search keyword '"Duering, M."' showing total 4 results

1. Strategic role of frontal white matter tracts in vascular cognitive impairment: a voxel-based lesion-symptom mapping study in CADASIL.

Author

Duering M, Zieren N, Hervé D, Jouvent E, Reyes S, Peters N, Pachai C, Opherk C, Chabriat H, and Dichgans M

Published

2011

2. Reversible cerebral vasoconstriction syndrome associated with hormone therapy for intrauterine insemination.

Author

Freilinger, T., Schmidt, C., Duering, M., Linn, J., Straube, A., and Peters, N.

Subjects

*HORMONE therapy complications, *CEREBRAL arterial diseases, *HUMAN artificial insemination, *ACUTE diseases, *HEADACHE, *PATHOLOGICAL physiology

Abstract

Introduction: Reversible cerebral vasoconstriction syndrome (RCVS) comprises a heterogeneous group of acute neurological diseases which are characterized by thunderclap headache and evidence of reversible multifocal constriction of cerebral arteries. A number of precipitating factors have been described in the literature, including recent childbirth and use of vasoactive substances.Case description: Here we present the case of a female patient with RCVS which occurred in the setting of hormonal ovarian stimulation for intrauterine insemination.Discussion: This case possibly contributes to the understanding of the pathophysiological mechanisms underlying reversible cerebral vasoconstriction. [ABSTRACT FROM PUBLISHER]

Published

2010

3. The human corticocortical vestibular network.

Author

Raiser, T.M., Flanagin, V.L., Duering, M., van Ombergen, A., Ruehl, R.M., and zu Eulenburg, P.

Subjects

*FUNCTIONAL connectivity, *HUMAN information processing, *VESTIBULAR stimulation, *VESTIBULAR apparatus diseases, *MAGNETIC resonance imaging, *PRIMATES

Abstract

• Robust modularity of the structural corticocortical vestibular network (CVN). • Similarities in the sensory organization of the CVN between humans and macaques. • Laterality preference in vestibular processing for the right hemisphere. • Structural CVN is characterized by a substantial intrahemispheric connectivity. • Functional CVN is characterized by a strong connectivity for homotopic nodes. Little is known about the cortical organization of human vestibular information processing. Instead of a dedicated primary vestibular cortex, a distributed network of regions across the cortex respond to vestibular input. The aim of this study is to characterize the human corticocortical vestibular network and compare it to established results in non-human primates. We collected high-resolution multi-shell diffusion-weighted (DWI) and state-of-the-art resting-state functional MR images of 29 right-handed normal subjects. Ten cortical vestibular regions per hemisphere were predefined from previous vestibular stimulation studies and applied as regions of interest. Four different structural corticocortical vestibular networks accounting for relevant constraints were investigated. The analyses included the investigation of common network measures and hemispheric differences for functional and structural connectivity patterns alike. In addition, the results of the structural vestibular network were compared to findings previously reported in non-human primates with respect to tracer injections (Guldin and Grusser, 1998). All structural networks independent of the applied constraints showed a recurring subdivision into identical three submodules. The structural human network was characterized by a predominantly intrahemispheric connectivity, whereas the functional pattern highlighted a strong connectivity for all homotopic nodes. A significant laterality preference towards the right hemisphere can be observed throughout the analyses: (1) with larger nodes, (2) stronger connectivity values structurally and functionally, and (3) a higher functional relevance. Similar connectivity patterns to non-human primate data were found in sensory and higher association cortices rather than premotor and motor areas. Our analysis delineated a remarkably stable organization of cortical vestibular connectivity. Differences found between primate species may be attributed to phylogeny as well as methodological differences. With our work we solidified evidence for lateralization within the corticocortical vestibular network. Our results might explain why cortical lesions in humans do not lead to persistent vestibular symptoms. Redundant structural routing throughout the network and a high-degree functional connectivity may buffer the network and reestablish network integrity quickly in case of injury. Image, graphical abstract [ABSTRACT FROM AUTHOR]

Published

2020

4. Table-top 50-W laser system for ultra-fast laser ablation.

Author

Luther-Davies, B., Kolev, V. Z., Lederer, M. J., Madsen, N. R., Rode, A. V., Giesekus, J., Du, K.-M., and Duering, M.

Subjects

*LASER ablation, *LASER cavity resonators, *MICROMACHINING, *SILICON, *OPTICAL films, *CHEMICAL vapor deposition

Abstract

We have built a mode-locked Nd:YVO4 laser with a very long resonator which produces an average power of 50 W in 13-ps pulses at 1064 nm and was designed for applications in micro-machining, the deposition of optical thin films, and the growth of nano-clusters in the laser-ablated plumes. By operating the laser at very low mode-locking repetition rates (1.5 MHz, 2.6 MHz, and 4.1 MHz), high pulse power is available in a near diffraction limited beam, allowing focused intensities to exceed 1012 W/cm2 and permitting efficient evaporation of difficult materials such as Si. The high power also allows conversion into the second harmonic at 532 nm with an efficiency exceeding 80%. Measurements of the ablation mass in experiments with metals show a 30–100 times increase in the ablation rate compared to the conventional low-repetition-rate ns-range lasers. [ABSTRACT FROM AUTHOR]

Published

2004