On-line-Kontrolle von Auswertealgorithmen am Bildschirm mit Anwendung zur Identifikation der Schluckfunktion - A Tool for Monitoring Biosignal Processing with an Application to the Analysis of Esophageal Function

Liu, J.; Faust, U.; Bressmer, H.; Schneider, John A.

doi:10.1515/bmte.1992.37.6.137

Cited by 8 publications

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Functional disconnection of axonal fibers generated by high frequency stimulation in the hippocampal CA1 region in-vivo

Feng¹,

Zheng²,

Yu³

et al. 2013

Brain Research

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High frequency stimulation (HFS) applied in the brain has been shown to be efficient for treating several brain disorders, such as Parkinson's disease and epilepsy. But the mechanisms underlying HFS are not clear. In particular, the effect of HFS on axons has been intriguing since axonal propagation plays an important role in the functional outcome of HFS. In order to study the potential effect of axonal block by HFS in-vivo, both orthodromic- and antidromic-HFS (O-HFS, A-HFS) with biphasic pulses were applied to the hippocampal CA1 region in anaesthetized rats. Changes in the amplitude and latency of orthodromic- and antidromic-population spikes within 1-min long period of stimulation at 50, 100 and 200 Hz HFS were analyzed. The results show that except for a short onset period, activity evoked by O-HFS with a frequency over 100 Hz could not be sustained. For A-HFS at frequencies over 100 Hz, the amplitudes and the latencies of antidromic population spike (APS) greatly decreased and increased respectively. Significantly larger changes in APS latency were observed in HFS than those generated at low frequency, suggesting a suppression of axon conduction by HFS. Furthermore, the CA1 somata remained excitable while failing to respond to excitation from orthodromic or antidromic HFS. Taken together, these results show that HFS produces an axonal block of both afferent and efferent fibres localized to the area of stimulation since it does not affect the excitability of CA1 somata. This effect of HFS on axons causes a functional disconnection of axonal pathways that is reversible and temporary. The reversible disconnection or temporary deafferentation between putative therapeutic targets could have extensive implication for various clinical applications of HFS to treat brain diseases.

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Functional disconnection of axonal fibers generated by high frequency stimulation in the hippocampal CA1 region in-vivo

Feng¹,

Zheng²,

Yu³

et al. 2013

Brain Research

View full text Add to dashboard Cite

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Kilohertz-frequency stimulation of the nervous system: A review of underlying mechanisms

et al. 2021

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Background: Electrical stimulation in the kilohertz-frequency range has gained interest in the field of neuroscience. The mechanisms underlying stimulation in this frequency range, however, are poorly characterized to date. Objective/hypothesis: To summarize the manifold biological effects elicited by kilohertz-frequency stimulation in the context of the currently existing literature and provide a mechanistic framework for the neural responses observed in this frequency range. Methods: A comprehensive search of the peer-reviewed literature was conducted across electronic databases. Relevant computational, clinical, and mechanistic studies were selected for review. Results: The effects of kilohertz-frequency stimulation on neural tissue are diverse and yield effects that are distinct from conventional stimulation. Broadly, these can be divided into 1) subthreshold, 2) suprathreshold, 3) synaptic and 4) thermal effects. While facilitation is the dominating mechanism at the subthreshold level, desynchronization, spike-rate adaptation, conduction block, and non-monotonic activation can be observed during suprathreshold kilohertz-frequency stimulation. At the synaptic level, kilohertz-frequency stimulation has been associated with the transient depletion of the available neurotransmitter pool e also known as synaptic fatigue. Finally, thermal effects associated with extrinsic (environmental) and intrinsic (associated with kilohertz-frequency stimulation) temperature changes have been suggested to alter the neural response to stimulation paradigms. Conclusion:The diverse spectrum of neural responses to stimulation in the kilohertz-frequency range is distinct from that associated with conventional stimulation. This offers the potential for new therapeutic avenues across stimulation modalities. However, stimulation in the kilohertz-frequency range is associated with distinct challenges and caveats that need to be considered in experimental paradigms.

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Whey - From waste to a valuable resource

Besediuk,

Yatskov,

Korchyk

et al. 2024

Journal of Agriculture and Food Research

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On-line-Kontrolle von Auswertealgorithmen am Bildschirm mit Anwendung zur Identifikation der Schluckfunktion - A Tool for Monitoring Biosignal Processing with an Application to the Analysis of Esophageal Function

Cited by 8 publications

References 0 publications

Functional disconnection of axonal fibers generated by high frequency stimulation in the hippocampal CA1 region in-vivo

Functional disconnection of axonal fibers generated by high frequency stimulation in the hippocampal CA1 region in-vivo

Kilohertz-frequency stimulation of the nervous system: A review of underlying mechanisms

Whey - From waste to a valuable resource

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