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Your search keyword '"Werner Hemmert"' showing total 13 results
Start Over Author "Werner Hemmert" Journal frontiers in computational neuroscience
13 results on '"Werner Hemmert"'

1. High Entrainment Constrains Synaptic Depression Levels of an

Author

Marek, Rudnicki and Werner, Hemmert

Subjects
high-sync neurons, computational model, sound localization, cochlear nucleus, globular bushy cell, temporal processing, short term depression, Neuroscience, Original Research, auditory pathway
Abstract

Globular bushy cells (GBCs) located in the ventral cochlear nucleus are an essential part of the sound localization pathway in the mammalian auditory system. They receive inputs directly from the auditory nerve and are particularly sensitive to temporal cues due to their synaptic and membrane specializations. GBCs act as coincidence detectors for incoming spikes through large synapses—endbulbs of Held—which connect to their soma. Since endbulbs of Held are an integral part of the auditory information conveying and processing pathway, they were extensively studied. Virtually all in vitro studies showed large synaptic depression, but on the other hand a few in vivo studies showed relatively small depression. It is also still not well understood how synaptic properties functionally influence firing properties of GBCs. Here we show how different levels of synaptic depression shape firing properties of GBCs in in vivo-like conditions using computer simulations. We analyzed how an interplay of synaptic depression (0–70%) and the number of auditory nerve fiber inputs (10–70) contributes to the variability of the experimental data from previous studies. We predict that the majority of synapses of GBCs with high characteristic frequencies (CF > 500 Hz) have a rate dependent depression of less than 20%. GBCs with lower CF (

Published
2016

2. A model of the auditory nerve for acoustic- and electric excitation

Author

M. Nicoletti, Marek Rudnicki, and Werner Hemmert

Subjects
medicine.medical_specialty, Auditory masking, Computer science, Refractory period, medicine.medical_treatment, Neuroscience (miscellaneous), Audiology, Cochlear nucleus, ddc, bccn, ss2010, Cellular and Molecular Neuroscience, medicine.anatomical_structure, Analog signal, Cochlear implant, otorhinolaryngologic diseases, medicine, Auditory system, Neural coding, Spiral ganglion
Abstract

Auditory nerve fibers (ANF) convey information about sound to the central nervous system. For both normal hearing subjects and cochlear implant patients the most drastic step of sound coding for neuronal processing is when the analog signal is converted into discrete nerve-action potentials. As any information lost during this process is no longer available for neural processing, it is important to understand the underlying principles of sound coding in the intact auditory system and the limitations in the case of direct electrical stimulation of the auditory nerve. Here we focus on a model of spiral ganglion type I neurons with Hodgkin-Huxley type ion channels, which are also found in cochlear nucleus neurons. Depending on the task, we model the neurons at different levels of detail. Our results show that for acoustic stimuli, the model provides realistic refractoriness and generates more realistic spike trains compared to a spike generator with absolute and exponentially decaying refractoriness added. Not surprisingly, speech discrimination in electrical hearing is lower than in acoustic hearing. On the other hand, the analysis of transmitted information shows that the temporal precision of coding seems to be very high because at levels well above threshold, action potentials are elicited quasi-deterministic by the electrical stimuli. We argue that CIS strategies a) waste as much as 50

Published
2010
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3. Temporal precision of speech coded into nerve-action potentials

Author

M. Nicoletti, S Karg, Werner Hemmert, M. Holmberg, Huan Wang, Michael Isik, and Marek Rudnicki

Subjects
Sound localization, Cellular and Molecular Neuroscience, Cochlear amplifier, Computational neuroscience, Computer science, Speech recognition, Temporal resolution, Neuroscience (miscellaneous), Sensory system, Speech processing, Cochlear nucleus, Coincidence detection in neurobiology
Abstract

The auditory pathway is an excellent system to study temporal aspects of neuronal processing. Unlike other sensory systems, temporal cues cover an extremely wide range of information: for sound localization, interaural time differences with a precision of tens of microseconds are extracted. Phase-locking of auditory nerve responses, which is related to the coding of the temporal fine structure, occurs from the lowest audible frequencies probably up to 3 kHz in humans. Amplitude modulations in speech signals are processed in the ms to tens of ms range. And finally, the energy of spoken speech itself is modulated with a frequency of about 4 Hz, corresponding to a syllable frequency in the order of few hundreds of ms. To extract temporal cues at all timescales, it is important to understand how temporal information is coded. We investigate temporal coding of speech signals using the methods of information theory and a model of the human inner ear. The model is based on a traveling-wave model, a nonlinear compression stage which mimics the function of the "cochlear amplifier", a model of the sensory cells, the afferent synapse and spike generation (Sumner ) which we extended to replicate "offset adaptation" (Zhang). We used the action potentials of the auditory nerve to drive Hodgkin-Huxley-type point models of various neurons in the cochlear nucleus. In this investigation we only report data from onset neurons, which exhibit extraordinary fast membrane time-constants below 1 ms. Onset neurons are known for their precise temporal processing. They achieve precisely timed action potentials by coincidence detection: they fire only if at least 10% of the auditory nerve fibers which innervate them fire synchronously. With information theory, we analyzed the transmitted information rate coded in neural spike trains of modeled neurons in the cochlear nucleus for vowels. We found that onset neurons are able to code temporal information with sub-millisecond precision (

Published
2009
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4. A model of auditory spiral ganglion neurons

Author

Marek Rudnicki, Werner Hemmert, and Bade P.-W.

Subjects
Physics, Synaptic cleft, Refractory period, Neuroscience (miscellaneous), Biological neuron model, Postsynapse, Cochlear nucleus, Cellular and Molecular Neuroscience, medicine.anatomical_structure, Postsynaptic potential, medicine, Hair cell, Neuroscience, Spiral ganglion
Abstract

Our study focuses on biophysical modeling of the auditory periphery and initial stages of neural processing. We examined in detail synaptic excitation between inner hair cells and spiral ganglion type I neurons. Spiral ganglion neurons encode and convey information about sound to the central nervous system in the form of action potentials. For the purpose of our study we utilized a biophysical model of the auditory periphery proposed by Sumner (2002). It consists of outer/middle ear filters, a basilar membrane filter bank, an inner hair cell model coupled with complex vesicle pool dynamics at the presynaptic membrane. Finally, fusion of vesicles, modelled with a probabilistic function, releases neurotransmitter into the synaptic cleft. Response of auditory nerve fibers is modeled with a spike generator. The absolute refractory period is set to 0.75 ms and the relative refractory period is modelled with an exponentially decaying function. In our approach we substituted the artificial spike generation and refraction model with a more realistic spiral ganglion neuron model with Hodgkin-Huxley type ion channels proposed by Negm and Bruce (2008). The model included several channels also found in cochlear nucleus neurons (K_A, K_ht, K_lt). Our model consisted of the postsynaptic bouton (1.5x1.7µm) from high-spontaneous rate fibers. We coupled the model of the synapse with the spiral ganglion neuron using a synaptic excitation model fitted to results from Glowatzki and Fuchs' (2002) experiments, who conducted patch clamp measurements at the afferent postsynapse. We verified our hybrid model against various experiments, mostly pure tone stimulation. Rate intensity functions fitted experimental data well, rates varied from about 40 spikes/s to a maximum of 260 spikes/s. Adaptation properties were investigated with peri-stimulus time histograms (PSTH). As adaptation is mainly governed by vesicle pool dynamics, only small changes occurred compared with the statistical spike generation model and adaptation was consistent with experiments. Interestingly, Hodgkin-Huxley models of spiral ganglion neurons exhibited a notch visible in the PSTH after rapid adaptation that could also be observed in experiments. This was not revealed by the statistical spike generator. The fiber's refractory period was investigated using inter-spike interval histograms. The refractory period varied with simulus intensity from 1ms (spontaneous activity) to 0.7ms (84dB_SPL). We also analyzed phase locking with the synchronization index. It was slightly lower compared to the statistical spike generator. By varying the density of K_lt and K_A channels, we could replicate heterogenity of auditory nerve fibers as shown by Adamson et al. (2002). In summary, replacing the statistical spike generation model with a more realistic model of the postsynaptic membrane obsoletes the introduction of non-physiologic parameters for absolute and relative refraction. It improves the refractory behaviour and provides more realistic spike trains of the auditory nerve. Acknowledgments: Supported by within the Munich Bernstein Center for Computational Neuroscience by the German Federal Ministry of Education and Research (reference numbers 01GQ0441 and 01GQ0443).

Published
2009
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