Sentences with phrase «auditory system»
The phrase "auditory system" refers to the parts of our body that allow us to hear, such as the ears and the parts of the brain that process sound. Full definition
GABA and glycine in the central auditory system of the mustache bat: structural substrates for inhibitory neuronal organization.
semanticscholar.org
In addition to the discovery of new FFR origins, the use of MEG to pinpoint FFR origin is itself an important step forward for research into the human auditory system.
C57BR / cdJ did not exhibit aberrant ABR wave patterns, suggesting that the hearing loss results from defects of the peripheral, rather than central auditory system (Zheng et al. 1999).
A new study in ferrets shows how auditory systems might separate the signal from the noise.
Soothing music can relax babies and make them more comfortable with their environment, and different musical notes and tunes can also develop auditory system and hearing skills.
Yelling at my son, especially when he was little, was especially damaging to him because of having SPD and an extra-sensitive auditory system.
The reason we think the sound of a jet aircraft is really loud has more to do with the sensitivity of our remarkable auditory system than with the energy in the sound wave itself.
«Ideally, what you want — whether in your natural auditory system or through a cochlear implant — is the most precise representation in the brain of the various frequencies,» says Burger.
Indeed, in his opinion, the best speech recognition systems are much less efficient than auditory system at best, there is a 92 % success rate compared to over 99.9 % for humans.
As a hypothesis this has the advantage that we have auditory systems capable of making sense of the sounds of people moving in our midst — an angry stomper approaching, a delicate lilter passing, and so on.
Elizabeth Sheldon - The role of semaphorin as a molecular guidance cue for dendritic regeneration in the cricket auditory system
Scientists at the Montreal Neurological Institute and Hospital at McGill University have made an important discovery about the human auditory system and how to study it, findings that could lead to better testing and diagnosis of hearing - related disorders.
Though an established and effective treatment for many, cochlear implants can not currently simulate the precision of sound experienced by those with a naturally - developed auditory system.
Our GIF grant on «Function of microRNAs in the peripheral and central auditory system» with Prof Hans Gerd Nothwang has begun!
Again, the little sound generated from the rattle can also contribute to improving your kid's auditory system.
As a conscious parent, you can do things that can stimulate kid's visual and auditory system.
And because the bones and nerves that make up the auditory system are nearly complete, loud noises can now wake your baby up.
By the time my son comes home from school, he's been heavily using his visual system, he's been stressing his auditory system, and he's pretty worn out.
Remember how the small bones that make up baby's auditory system were starting to make serious headway a couple of weeks ago?
Your baby's auditory system is continuing to develop, and he or she may be able to distinguish your voice from others» this week.
The paper goes on to point out that, «Evidence, primarily from animal studies, suggests that the functional development of the auditory system is largely influenced by environmental acoustic inputs early in life.»
The perception of sensory dissonance is a function of the physical properties of auditory stimuli, as well as those of basic physiological and anatomical constraints, resulting from limitations of the auditory system in resolving tones that are too proximal in pitch (54).
«Navigating the genome to cure deafness: Discovery of long - encoding RNAs in the auditory system may solve a piece of the deafness puzzle.»
«The research on long non-coding RNAs is crucial to understanding how gene expression and regulatory elements influence the auditory system,» says Prof. Karen Avraham, Vice Dean of TAU's Sackler Faculty of Medicine.
A new Tel Aviv University study solves a critical piece of the puzzle of human deafness by identifying the first group of long non-coding RNAs (lncRNAs) in the auditory system.
Moreover, both the diameter of the axons and the thickness of their myelin sheaths progressively increased until they reached the values observed in the auditory system of the adult animal.
«Such losses are particularly critical in the auditory system, because they reduce the temporal precision of signal transmission — and the quality of our perception of the acoustic environment is primarily dependent on rates of action potential generation and precise neural computation of their temporal sequences.»
Using the mouse as an experimental model, LMU neurobiologist PD Dr. Conny Kopp - Scheinpflug and her research group have now demonstrated that the activity of nerve cells in the auditory system has a direct effect on myelinization — higher levels of activity correlate with the formation of thicker myelin sheaths.
«The mouse is a particularly suitable model in which to study the development of the auditory system, because newborn mice are deaf and only begin to perceive acoustic signals at 12 days after birth.
In mammals, the functional demands made on the auditory system require extremely precise and rapid neural processing of acoustic information, and it contains a strikingly high proportion of myelinated axons.
An Ludwig - Maximilians - Universitaet (LMU) in Munich study reveals that sound - evoked activity of neurons in the auditory system of the mouse increases the thickness of their myelin sheaths — and enhances the speed of signal transmission — both during development and in the adult brain.
New research reveals how developing ears generate their own noise, a process that may help calibrate our auditory system.
Johns Hopkins University researchers studied the auditory systems of rats, which are deaf until about 12 days of age.
«It appears that this activity plays an important role in the development of the auditory system,» lead researcher Dwight E. Bergles says.
From the moment we begin to hear, our auditory system is precisely tuned, able to distinguish subtle differences between sounds.
Kraus is a biologist who studies the auditory system, which is at the nexus of our cognitive, sensory and limbic systems.
The groundbreaking research, to be published Dec. 22 in the journal Nature, Scientific Reports, has found a biological marker in the auditory system that could take the ambiguity and controversy out of diagnosing concussions and tracking recovery.
Each ear hears separate pieces of information, which is then combined during processing throughout the auditory system.
How does our auditory system represent time within a sound?
In essence, ear differences in processing abilities are lost on tests using four items because our auditory system can handle more information.
However, young children's auditory systems can not sort and separate the simultaneous information from both ears.
Although the auditory systems of the four - legged animals have undergone many changes since, they have in common the middle ear with eardrum and ossicles, which emerged independently in the major lineages.
If they can hear, their auditory system must be a survivor of life forms on the ancient supercontinent Gondwana.»
«This interaction between self - motion and the auditory system is remarkable,» says Wiegrebe.
Using direct, controlled acoustic stimulation, the scientists were able to prove that the auditory system of mice lacking in pejvakin is affected by their acoustic environment.
«That suggests these neurons are providing a copy of the motor command directly to the auditory system,» said David M. Schneider, Ph.D., co-lead author of the study and a postdoctoral fellow in Mooney's lab.
«Researchers will be able to ask new and useful questions about how the auditory system is organized and what has gone wrong when it's not working properly.»
Even short - term blockages of this kind can lead to remarkable changes in the auditory system, altering the behavior and structure of nerve cells that relay information from the ear to the brain, according to a new University at Buffalo study.
Now, researchers have developed the first diagram of the brain circuitry that enables this complex interplay between the motor system and the auditory system to occur.
«We will be able to more effectively think about and test treatments because this technique allows us to observe the interactions of components of the auditory system as we process sound, and maybe target training to improve poorly functioning parts.»