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Related Concept Videos

The Cochlea01:13

The Cochlea

The cochlea is a coiled structure in the inner ear that contains hair cells—the sensory receptors of the auditory system. Sound waves are transmitted to the cochlea by small bones attached to the eardrum called the ossicles, which vibrate the oval window that leads to the inner ear. This causes fluid in the chambers of the cochlea to move, vibrating the basilar membrane.
Compensation Mechanisms01:28

Compensation Mechanisms

The human body employs intricate mechanisms to counteract changes in blood pH, preventing conditions like acidosis (pH < 7.35) and alkalosis (pH > 7.45). These compensatory responses aim to restore normal arterial blood pH by engaging respiratory or renal systems, depending on the source of the imbalance.
Respiratory Compensation
This mechanism addresses metabolic-induced pH imbalances by adjusting breathing rates. Respiratory compensation begins within minutes of detecting a pH...
Hair Cells01:22

Hair Cells

Hair cells are the sensory receptors of the auditory system—they transduce mechanical sound waves into electrical energy that the nervous system can understand. Hair cells are located in the organ of Corti within the cochlea of the inner ear, between the basilar and tectorial membranes. The actual sensory receptors are called inner hair cells. The outer hair cells serve other functions, such as sound amplification in the cochlea, and are not discussed in detail here.
The Role of Ion Channels in Neuronal Computation01:19

The Role of Ion Channels in Neuronal Computation

A postsynaptic neuron usually receives numerous impulses from several other presynaptic neurons. The axon hillock of the postsynaptic neuron integrates all these signals and determines the likelihood of firing an action potential.
Sometimes a single EPSP is strong enough to induce an action potential in the postsynaptic neuron. However, multiple presynaptic inputs must often create EPSPs around the same time for the postsynaptic neuron to be sufficiently depolarized to fire an action potential.
Hearing01:31

Hearing

When we hear a sound, our nervous system is detecting sound waves—pressure waves of mechanical energy traveling through a medium. The frequency of the wave is perceived as pitch, while the amplitude is perceived as loudness.
Interference: Path Lengths01:10

Interference: Path Lengths

Consider two sources of sound, that may or may not be in phase, emitting waves at a single frequency, and consider the frequencies to be the same.
Two special sources may be considered when they are in phase. This can be easily achieved by feeding the two sources from the same source. An example would be synchronizing the two speakers by feeding them with the same source, such as the sound waves produced by a tuning fork. This setup ensures that the two sources have the same frequency and are...

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Related Experiment Video

Updated: May 10, 2026

Systematic Hearing Performance Evaluation Process for Adolescents with Cochlear Implantation at Early Ages
06:04

Systematic Hearing Performance Evaluation Process for Adolescents with Cochlear Implantation at Early Ages

Published on: March 24, 2023

Compensation for channel interaction in a simultaneous cochlear implant coding strategy.

Paul Bader1, Mathias Kals, Reinhold Schatzer

  • 1Institute of Mechatronics, Faculty of Engineering Science, University of Innsbruck, Innsbruck, Austria. paul.bader@uibk.ac.at

The Journal of the Acoustical Society of America
|June 8, 2013
PubMed
Summary
This summary is machine-generated.

Cochlear implant users showed no difference in hearing performance when using simultaneous or sequential stimulation. A new algorithm compensated for channel interaction, potentially improving battery life.

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Systematic Hearing Performance Evaluation Process for Adolescents with Cochlear Implantation at Early Ages
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Published on: March 8, 2022

Area of Science:

  • Audiology
  • Biomedical Engineering
  • Neuroscience

Background:

  • Spatial channel interaction is a challenge in cochlear implants (CIs) during simultaneous stimulation.
  • This interaction can negatively impact hearing performance.
  • Existing CI strategies often use sequential stimulation to avoid this.

Purpose of the Study:

  • To evaluate an algorithm designed to compensate for detrimental effects of simultaneous channel interaction in CIs.
  • To determine if compensated simultaneous stimulation can match the hearing performance of sequential stimulation.
  • To explore strategies for improving CI efficiency and longevity.

Main Methods:

  • Simultaneous stimulation of two or three electrodes in monopolar configuration with a compensation algorithm.
  • Constant overall stimulation rate across conditions.
  • Use of German Oldenburg sentence and vowel tests for speech recognition assessment in 12 CI users.
  • Varied spatial electrode distances and extended pulse phase durations.

Main Results:

  • No significant differences in speech recognition performance between simultaneous and sequential stimulation strategies.
  • Slightly better performance with smaller spatial distances between simultaneous electrodes.
  • Extended pulse phase durations did not significantly affect hearing performance.
  • Extended pulse phase durations significantly reduced required stimulation amplitudes.

Conclusions:

  • The developed algorithm effectively compensates for simultaneous channel interaction in CIs.
  • Compensated simultaneous stimulation is a viable alternative to sequential stimulation, offering comparable hearing performance.
  • Strategies combining channel interaction compensation with extended pulse durations may reduce power consumption, enhancing battery life for cochlear implants.