Thomas Rittmann scite author profile

Thomas Rittmann

4Publications

62Citation Statements Received

69Citation Statements Given

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133

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University of Göttingen

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Simple low dose radiography allows precise lung volume assessment in mice

Khan

Markus

Rittmann

et al. 2021

Sci Rep

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X-ray based lung function (XLF) as a planar method uses dramatically less X-ray dose than computed tomography (CT) but so far lacked the ability to relate its parameters to pulmonary air volume. The purpose of this study was to calibrate the functional constituents of XLF that are biomedically decipherable and directly comparable to that of micro-CT and whole-body plethysmography (WBP). Here, we developed a unique set-up for simultaneous assessment of lung function and volume using XLF, micro-CT and WBP on healthy mice. Our results reveal a strong correlation of lung volumes obtained from radiographic XLF and micro-CT and demonstrate that XLF is superior to WBP in sensitivity and precision to assess lung volumes. Importantly, XLF measurement uses only a fraction of the radiation dose and acquisition time required for CT. Therefore, the redefined XLF approach is a promising tool for preclinical longitudinal studies with a substantial potential of clinical translation.

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Coulomb interactions in high-coherence femtosecond electron pulses from tip emitters

Bach

Domröse

Feist

et al. 2019

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Tip-based photoemission electron sources offer unique properties for ultrafast imaging, diffraction, and spectroscopy experiments with highly coherent few-electron pulses. Extending this approach to increased bunch-charges requires a comprehensive experimental study on Coulomb interactions in nanoscale electron pulses and their impact on beam quality. For a laser-driven Schottky field emitter, we assess the transverse and longitudinal electron pulse properties in an ultrafast transmission electron microscope at a high photoemission current density. A quantitative characterization of electron beam emittance, pulse duration, spectral bandwidth, and chirp is performed. Due to the cathode geometry, Coulomb interactions in the pulse predominantly occur in the direct vicinity to the tip apex, resulting in a well-defined pulse chirp and limited emittance growth. Strategies for optimizing electron source parameters are identified, enabling advanced ultrafast transmission electron microscopy approaches, such as phase-resolved imaging and holography.

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Quantum Coherent Transverse and Longitudinal Control for Attosecond Shaping of Free Electron Beams

Feist

Priebe

Rathje

et al. 2018

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Probing Nanoscale Optical Fields and Phase-Shaping Electron Beams by Inelastic Electron-Light Scattering

Feist

Rittmann

Harvey

et al. 2019

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Thomas Rittmann

Simple low dose radiography allows precise lung volume assessment in mice

Coulomb interactions in high-coherence femtosecond electron pulses from tip emitters

Quantum Coherent Transverse and Longitudinal Control for Attosecond Shaping of Free Electron Beams

Probing Nanoscale Optical Fields and Phase-Shaping Electron Beams by Inelastic Electron-Light Scattering

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