Thomas Weyh scite author profile

The inhalation of medical aerosols is widely used for the treatment of lung disorders such as asthma, chronic obstructive pulmonary disease, cystic fibrosis, respiratory infection and, more recently, lung cancer. Targeted aerosol delivery to the affected lung tissue may improve therapeutic efficiency and minimize unwanted side effects. Despite enormous progress in optimizing aerosol delivery to the lung, targeted aerosol delivery to specific lung regions other than the airways or the lung periphery has not been adequately achieved to date. Here, we show theoretically by computer-aided simulation, and for the first time experimentally in mice, that targeted aerosol delivery to the lung can be achieved with aerosol droplets comprising superparamagnetic iron oxide nanoparticles--so-called nanomagnetosols--in combination with a target-directed magnetic gradient field. We suggest that nanomagnetosols may be useful for treating localized lung disease, by targeting foci of bacterial infection or tumour nodules.

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Stimulus intensity and coil characteristics influence the efficacy of rTMS to suppress cortical excitability

Lang

Harms

Weyh

et al. 2006

Clinical Neurophysiology

130

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Combined targeting of lentiviral vectors and positioning of transduced cells by magnetic nanoparticles

Hofmann

Wenzel²,

Becher³

et al. 2009

Proc. Natl. Acad. Sci. U.S.A.

102

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Modular Multilevel Converter With Series and Parallel Module Connectivity: Topology and Control

Goetz¹,

Peterchev

Weyh³

2015

IEEE Trans. Power Electron.

124

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Analysis and Optimization of Pulse Dynamics for Magnetic Stimulation

et al. 2013

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Magnetic stimulation is a standard tool in brain research and has found important clinical applications in neurology, psychiatry, and rehabilitation. Whereas coil designs and the spatial field properties have been intensively studied in the literature, the temporal dynamics of the field has received less attention. Typically, the magnetic field waveform is determined by available device circuit topologies rather than by consideration of what is optimal for neural stimulation. This paper analyzes and optimizes the waveform dynamics using a nonlinear model of a mammalian axon. The optimization objective was to minimize the pulse energy loss. The energy loss drives power consumption and heating, which are the dominating limitations of magnetic stimulation. The optimization approach is based on a hybrid global-local method. Different coordinate systems for describing the continuous waveforms in a limited parameter space are defined for numerical stability. The optimization results suggest that there are waveforms with substantially higher efficiency than that of traditional pulse shapes. One class of optimal pulses is analyzed further. Although the coil voltage profile of these waveforms is almost rectangular, the corresponding current shape presents distinctive characteristics, such as a slow low-amplitude first phase which precedes the main pulse and reduces the losses. Representatives of this class of waveforms corresponding to different maximum voltages are linked by a nonlinear transformation. The main phase, however, scales with time only. As with conventional magnetic stimulation pulses, briefer pulses result in lower energy loss but require higher coil voltage than longer pulses.

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Thomas Weyh

Targeted delivery of magnetic aerosol droplets to the lung

Stimulus intensity and coil characteristics influence the efficacy of rTMS to suppress cortical excitability

Combined targeting of lentiviral vectors and positioning of transduced cells by magnetic nanoparticles

Modular Multilevel Converter With Series and Parallel Module Connectivity: Topology and Control

Analysis and Optimization of Pulse Dynamics for Magnetic Stimulation

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