The testing of the acuity of the sense of hearing to determine the thresholds of the lowest intensity levels at which an individual can hear a set of tones. The frequencies between 125 and 8000 Hz are used to test air conduction thresholds and the frequencies between 250 and 4000 Hz are used to test bone conduction thresholds.
Measurement of hearing based on the use of pure tones of various frequencies and intensities as auditory stimuli.
A form of electrophysiologic audiometry in which an analog computer is included in the circuit to average out ongoing or spontaneous brain wave activity. A characteristic pattern of response to a sound stimulus may then become evident. Evoked response audiometry is known also as electric response audiometry.
The audibility limit of discriminating sound intensity and pitch.
Hearing loss in frequencies above 1000 hertz.
Conditions that impair the transmission of auditory impulses and information from the level of the ear to the temporal cortices, including the sensorineural pathways.
Objective tests of middle ear function based on the difficulty (impedance) or ease (admittance) of sound flow through the middle ear. These include static impedance and dynamic impedance (i.e., tympanometry and impedance tests in conjunction with intra-aural muscle reflex elicitation). This term is used also for various components of impedance and admittance (e.g., compliance, conductance, reactance, resistance, susceptance).
Hearing loss due to exposure to explosive loud noise or chronic exposure to sound level greater than 85 dB. The hearing loss is often in the frequency range 4000-6000 hertz.
A general term for the complete or partial loss of the ability to hear from one or both ears.
Part of an ear examination that measures the ability of sound to reach the brain.
Noise present in occupational, industrial, and factory situations.
The ability or act of sensing and transducing ACOUSTIC STIMULATION to the CENTRAL NERVOUS SYSTEM. It is also called audition.
A nonspecific symptom of hearing disorder characterized by the sensation of buzzing, ringing, clicking, pulsations, and other noises in the ear. Objective tinnitus refers to noises generated from within the ear or adjacent structures that can be heard by other individuals. The term subjective tinnitus is used when the sound is audible only to the affected individual. Tinnitus may occur as a manifestation of COCHLEAR DISEASES; VESTIBULOCOCHLEAR NERVE DISEASES; INTRACRANIAL HYPERTENSION; CRANIOCEREBRAL TRAUMA; and other conditions.
Use of sound to elicit a response in the nervous system.
Self-generated faint acoustic signals from the inner ear (COCHLEA) without external stimulation. These faint signals can be recorded in the EAR CANAL and are indications of active OUTER AUDITORY HAIR CELLS. Spontaneous otoacoustic emissions are found in all classes of land vertebrates.
Hearing loss resulting from damage to the COCHLEA and the sensorineural elements which lie internally beyond the oval and round windows. These elements include the AUDITORY NERVE and its connections in the BRAINSTEM.
Personal devices for protection of the ears from loud or high intensity noise, water, or cold. These include earmuffs and earplugs.
Electrical waves in the CEREBRAL CORTEX generated by BRAIN STEM structures in response to auditory click stimuli. These are found to be abnormal in many patients with CEREBELLOPONTINE ANGLE lesions, MULTIPLE SCLEROSIS, or other DEMYELINATING DISEASES.
Loss of sensitivity to sounds as a result of auditory stimulation, manifesting as a temporary shift in auditory threshold. The temporary threshold shift, TTS, is expressed in decibels.
The ability to differentiate tones.
Hearing loss due to interference with the mechanical reception or amplification of sound to the COCHLEA. The interference is in the outer or middle ear involving the EAR CANAL; TYMPANIC MEMBRANE; or EAR OSSICLES.
Measurement of the ability to hear speech under various conditions of intensity and noise interference using sound-field as well as earphones and bone oscillators.
Any sound which is unwanted or interferes with HEARING other sounds.
A dimension of auditory sensation varying with cycles per second of the sound stimulus.
Transmission of sound waves through vibration of bones in the SKULL to the inner ear (COCHLEA). By using bone conduction stimulation and by bypassing any OUTER EAR or MIDDLE EAR abnormalities, hearing thresholds of the cochlea can be determined. Bone conduction hearing differs from normal hearing which is based on air conduction stimulation via the EAR CANAL and the TYMPANIC MEMBRANE.
The electric response evoked in the CEREBRAL CORTEX by ACOUSTIC STIMULATION or stimulation of the AUDITORY PATHWAYS.
The process whereby auditory stimuli are selected, organized, and interpreted by the organism.
The region of the cerebral cortex that receives the auditory radiation from the MEDIAL GENICULATE BODY.
The science pertaining to the interrelationship of psychologic phenomena and the individual's response to the physical properties of sound.
Examination of the EAR CANAL and eardrum with an OTOSCOPE.
Disorders of hearing or auditory perception due to pathological processes of the AUDITORY PATHWAYS in the CENTRAL NERVOUS SYSTEM. These include CENTRAL HEARING LOSS and AUDITORY PERCEPTUAL DISORDERS.
A type of non-ionizing radiation in which energy is transmitted through solid, liquid, or gas as compression waves. Sound (acoustic or sonic) radiation with frequencies above the audible range is classified as ultrasonic. Sound radiation below the audible range is classified as infrasonic.
Intra-aural contraction of tensor tympani and stapedius in response to sound.
Surgical reconstruction of the hearing mechanism of the middle ear, with restoration of the drum membrane to protect the round window from sound pressure, and establishment of ossicular continuity between the tympanic membrane and the oval window. (Dorland, 28th ed.)
NEURAL PATHWAYS and connections within the CENTRAL NERVOUS SYSTEM, beginning at the hair cells of the ORGAN OF CORTI, continuing along the eighth cranial nerve, and terminating at the AUDITORY CORTEX.
A term used in Eastern European research literature for the functional neural unit that provides the basis for differential sensitivity; the analyzer consists of receptor, afferent nerves, and their central connections. (From Campbell's Psychiatric Dictionary, 8th ed.)
Sound that expresses emotion through rhythm, melody, and harmony.
Wearable sound-amplifying devices that are intended to compensate for impaired hearing. These generic devices include air-conduction hearing aids and bone-conduction hearing aids. (UMDNS, 1999)
Acquired or developmental cognitive disorders of AUDITORY PERCEPTION characterized by a reduced ability to perceive information contained in auditory stimuli despite intact auditory pathways. Affected individuals have difficulty with speech perception, sound localization, and comprehending the meaning of inflections of speech.
Pathological processes of the ear, the hearing, and the equilibrium system of the body.
Pathological processes of the VESTIBULAR LABYRINTH which contains part of the balancing apparatus. Patients with vestibular diseases show instability and are at risk of frequent falls.
An illusion of movement, either of the external world revolving around the individual or of the individual revolving in space. Vertigo may be associated with disorders of the inner ear (EAR, INNER); VESTIBULAR NERVE; BRAINSTEM; or CEREBRAL CORTEX. Lesions in the TEMPORAL LOBE and PARIETAL LOBE may be associated with FOCAL SEIZURES that may feature vertigo as an ictal manifestation. (From Adams et al., Principles of Neurology, 6th ed, pp300-1)
Formation of spongy bone in the labyrinth capsule which can progress toward the STAPES (stapedial fixation) or anteriorly toward the COCHLEA leading to conductive, sensorineural, or mixed HEARING LOSS. Several genes are associated with familial otosclerosis with varied clinical signs.
The cochlear part of the 8th cranial nerve (VESTIBULOCOCHLEAR NERVE). The cochlear nerve fibers originate from neurons of the SPIRAL GANGLION and project peripherally to cochlear hair cells and centrally to the cochlear nuclei (COCHLEAR NUCLEUS) of the BRAIN STEM. They mediate the sense of hearing.
Surgery performed in which part of the STAPES, a bone in the middle ear, is removed and a prosthesis is placed to help transmit sound between the middle ear and inner ear.
The perceived attribute of a sound which corresponds to the physical attribute of intensity.
Hearing loss without a physical basis. Often observed in patients with psychological or behavioral disorders.
The process whereby an utterance is decoded into a representation in terms of linguistic units (sequences of phonetic segments which combine to form lexical and grammatical morphemes).
Partial hearing loss in both ears.
A number of tests used to determine if the brain or balance portion of the inner ear are causing dizziness.
The graphic registration of the frequency and intensity of sounds, such as speech, infant crying, and animal vocalizations.
The state of activity or tension of a muscle beyond that related to its physical properties, that is, its active resistance to stretch. In skeletal muscle, tonus is dependent upon efferent innervation. (Stedman, 25th ed)
The dorsal portion or roof of the midbrain which is composed of two pairs of bumps, the INFERIOR COLLICULI and the SUPERIOR COLLICULI. These four colliculi are also called the quadrigeminal bodies (TECTUM MESENCEPHALI). They are centers for visual sensorimotor integration.
The part of the inner ear (LABYRINTH) that is concerned with hearing. It forms the anterior part of the labyrinth, as a snail-like structure that is situated almost horizontally anterior to the VESTIBULAR LABYRINTH.
Recording of nystagmus based on changes in the electrical field surrounding the eye produced by the difference in potential between the cornea and the retina.
The space and structures directly internal to the TYMPANIC MEMBRANE and external to the inner ear (LABYRINTH). Its major components include the AUDITORY OSSICLES and the EUSTACHIAN TUBE that connects the cavity of middle ear (tympanic cavity) to the upper part of the throat.
The sounds produced by humans by the passage of air through the LARYNX and over the VOCAL CORDS, and then modified by the resonance organs, the NASOPHARYNX, and the MOUTH.
A part of the MEDULLA OBLONGATA situated in the olivary body. It is involved with motor control and is a major source of sensory input to the CEREBELLUM.
The hearing and equilibrium system of the body. It consists of three parts: the EXTERNAL EAR, the MIDDLE EAR, and the INNER EAR. Sound waves are transmitted through this organ where vibration is transduced to nerve signals that pass through the ACOUSTIC NERVE to the CENTRAL NERVOUS SYSTEM. The inner ear also contains the vestibular organ that maintains equilibrium by transducing signals to the VESTIBULAR NERVE.
The aggregate business enterprise of manufacturing textiles. (From Random House Unabridged Dictionary, 2d ed)
The posterior pair of the quadrigeminal bodies which contain centers for auditory function.
The interference of one perceptual stimulus with another causing a decrease or lessening in perceptual effectiveness.
A basement membrane in the cochlea that supports the hair cells of the ORGAN OF CORTI, consisting keratin-like fibrils. It stretches from the SPIRAL LAMINA to the basilar crest. The movement of fluid in the cochlea, induced by sound, causes displacement of the basilar membrane and subsequent stimulation of the attached hair cells which transform the mechanical signal into neural activity.
An auditory orientation mechanism involving the emission of high frequency sounds which are reflected back to the emitter (animal).
Order of mammals whose members are adapted for flight. It includes bats, flying foxes, and fruit bats.
Three long canals (anterior, posterior, and lateral) of the bony labyrinth. They are set at right angles to each other and are situated posterosuperior to the vestibule of the bony labyrinth (VESTIBULAR LABYRINTH). The semicircular canals have five openings into the vestibule with one shared by the anterior and the posterior canals. Within the canals are the SEMICIRCULAR DUCTS.
A benign SCHWANNOMA of the eighth cranial nerve (VESTIBULOCOCHLEAR NERVE), mostly arising from the vestibular branch (VESTIBULAR NERVE) during the fifth or sixth decade of life. Clinical manifestations include HEARING LOSS; HEADACHE; VERTIGO; TINNITUS; and FACIAL PAIN. Bilateral acoustic neuromas are associated with NEUROFIBROMATOSIS 2. (From Adams et al., Principles of Neurology, 6th ed, p673)
Psychophysical technique that permits the estimation of the bias of the observer as well as detectability of the signal (i.e., stimulus) in any sensory modality. (From APA, Thesaurus of Psychological Index Terms, 8th ed.)
Pathological processes of the VESTIBULOCOCHLEAR NERVE, including the branches of COCHLEAR NERVE and VESTIBULAR NERVE. Common examples are VESTIBULAR NEURITIS, cochlear neuritis, and ACOUSTIC NEUROMA. Clinical signs are varying degree of HEARING LOSS; VERTIGO; and TINNITUS.
Ability to determine the specific location of a sound source.
The time from the onset of a stimulus until a response is observed.
The exposure to potentially harmful chemical, physical, or biological agents that occurs as a result of one's occupation.
The measurement of magnetic fields over the head generated by electric currents in the brain. As in any electrical conductor, electric fields in the brain are accompanied by orthogonal magnetic fields. The measurement of these fields provides information about the localization of brain activity which is complementary to that provided by ELECTROENCEPHALOGRAPHY. Magnetoencephalography may be used alone or together with electroencephalography, for measurement of spontaneous or evoked activity, and for research or clinical purposes.
Gradual bilateral hearing loss associated with aging that is due to progressive degeneration of cochlear structures and central auditory pathways. Hearing loss usually begins with the high frequencies then progresses to sounds of middle and low frequencies.
Studies in which the presence or absence of disease or other health-related variables are determined in each member of the study population or in a representative sample at one particular time. This contrasts with LONGITUDINAL STUDIES which are followed over a period of time.
Diseases caused by factors involved in one's employment.
The brain stem nucleus that receives the central input from the cochlear nerve. The cochlear nucleus is located lateral and dorsolateral to the inferior cerebellar peduncles and is functionally divided into dorsal and ventral parts. It is tonotopically organized, performs the first stage of central auditory processing, and projects (directly or indirectly) to higher auditory areas including the superior olivary nuclei, the medial geniculi, the inferior colliculi, and the auditory cortex.
Elements of limited time intervals, contributing to particular results or situations.
Electronic hearing devices typically used for patients with normal outer and middle ear function, but defective inner ear function. In the COCHLEA, the hair cells (HAIR CELLS, VESTIBULAR) may be absent or damaged but there are residual nerve fibers. The device electrically stimulates the COCHLEAR NERVE to create sound sensation.
Sounds used in animal communication.
The ability to estimate periods of time lapsed or duration of time.
Sensorineural hearing loss which develops suddenly over a period of hours or a few days. It varies in severity from mild to total deafness. Sudden deafness can be due to head trauma, vascular diseases, infections, or can appear without obvious cause or warning.
Studies which start with the identification of persons with a disease of interest and a control (comparison, referent) group without the disease. The relationship of an attribute to the disease is examined by comparing diseased and non-diseased persons with regard to the frequency or levels of the attribute in each group.
Observation of a population for a sufficient number of persons over a sufficient number of years to generate incidence or mortality rates subsequent to the selection of the study group.
An oval semitransparent membrane separating the external EAR CANAL from the tympanic cavity (EAR, MIDDLE). It contains three layers: the skin of the external ear canal; the core of radially and circularly arranged collagen fibers; and the MUCOSA of the middle ear.
A subfamily of the Muridae consisting of several genera including Gerbillus, Rhombomys, Tatera, Meriones, and Psammomys.
Surgically placed electric conductors through which ELECTRIC STIMULATION is delivered to or electrical activity is recorded from a specific point inside the body.
Behavioral manifestations of cerebral dominance in which there is preferential use and superior functioning of either the left or the right side, as in the preferred use of the right hand or right foot.
Differential response to different stimuli.
The basic cellular units of nervous tissue. Each neuron consists of a body, an axon, and dendrites. Their purpose is to receive, conduct, and transmit impulses in the NERVOUS SYSTEM.
A common name used for the genus Cavia. The most common species is Cavia porcellus which is the domesticated guinea pig used for pets and biomedical research.
Surgical insertion of an electronic hearing device (COCHLEAR IMPLANTS) with electrodes to the COCHLEAR NERVE in the inner ear to create sound sensation in patients with residual nerve fibers.
A continuing periodic change in displacement with respect to a fixed reference. (McGraw-Hill Dictionary of Scientific and Technical Terms, 6th ed)
A genus of the subfamily CALLITRICHINAE occurring in forests of Brazil and Bolivia and containing seventeen species.
A general term for the complete loss of the ability to hear from both ears.
Imaging techniques used to colocalize sites of brain functions or physiological activity with brain structures.
A type of MAGNETIC RESONANCE IMAGING that uses only one nuclear spin excitation per image and therefore can obtain images in a fraction of a second rather than the minutes required in traditional MRI techniques. It is used in a variety of medical and scientific applications.
Sensory cells in the organ of Corti, characterized by their apical stereocilia (hair-like projections). The inner and outer hair cells, as defined by their proximity to the core of spongy bone (the modiolus), change morphologically along the COCHLEA. Towards the cochlear apex, the length of hair cell bodies and their apical STEREOCILIA increase, allowing differential responses to various frequencies of sound.
The domestic cat, Felis catus, of the carnivore family FELIDAE, comprising over 30 different breeds. The domestic cat is descended primarily from the wild cat of Africa and extreme southwestern Asia. Though probably present in towns in Palestine as long ago as 7000 years, actual domestication occurred in Egypt about 4000 years ago. (From Walker's Mammals of the World, 6th ed, p801)
Abrupt changes in the membrane potential that sweep along the CELL MEMBRANE of excitable cells in response to excitation stimuli.
The range or frequency distribution of a measurement in a population (of organisms, organs or things) that has not been selected for the presence of disease or abnormality.

Age-related hearing loss, vitamin B-12, and folate in elderly women. (1/570)

BACKGROUND: Hearing impairment is 1 of the 4 most prevalent chronic conditions in the elderly. However, the biological basis of age-related hearing loss is unknown. OBJECTIVE: The objective was to test the hypothesis that age-related hearing loss may be associated with poor vitamin B-12 and folate status. DESIGN: A thorough audiometric assessment was conducted in 55 healthy women aged 60-71 y. Hearing function was determined by the average of pure-tone air conduction thresholds at 0.5, 1, 2, and 4 kHz and was categorized into 2 groups for logistic regression analyses: normal hearing (<20 dB hearing level; n = 44) and impaired hearing (> or = 20 dB hearing level; n = 11). RESULTS: Mean age was the same (65 y) for the normal hearing and impaired hearing groups. Pure-tone averages were inversely correlated with serum vitamin B-12 (r = -0.58, P = 0.0001) and red cell folate (r = -0.37, P = 0.01). Women with impaired hearing had 38% lower serum vitamin B-12 (236 compared with 380 pmol/L, respectively, P = 0.008) and 31% lower red cell folate (425 compared with 619 nmol/L, respectively, P = 0.02) than women with normal hearing. Among participants who did not take supplements containing vitamin B-12 or folate, women with impaired hearing had 48% lower serum vitamin B-12 (156 compared with 302 pmol/L, respectively, P = 0.0007) and 43% lower red cell folate (288 compared with 502 nmol/L, respectively, P = 0.001) than women with normal hearing. CONCLUSION: Poor vitamin B-12 and folate status may be associated with age-related auditory dysfunction.  (+info)

A possible neurophysiological basis of the octave enlargement effect. (2/570)

Although the physical octave is defined as a simple ratio of 2:1, listeners prefer slightly greater octave ratios. Ohgushi [J. Acoust. Soc. Am. 73, 1694-1700 (1983)] suggested that a temporal model for octave matching would predict this octave enlargement effect because, in response to pure tones, auditory-nerve interspike intervals are slightly larger than the stimulus period. In an effort to test Ohgushi's hypothesis, auditory-nerve single-unit responses to pure-tone stimuli were collected from Dial-anesthetized cats. It was found that although interspike interval distributions show clear phase-locking to the stimulus, intervals systematically deviate from integer multiples of the stimulus period. Due to refractory effects, intervals smaller than 5 msec are slightly larger than the stimulus period and deviate most for small intervals. On the other hand, first-order intervals are smaller than the stimulus period for stimulus frequencies less than 500 Hz. It is shown that this deviation is the combined effect of phase-locking and multiple spikes within one stimulus period. A model for octave matching was implemented which compares frequency estimates of two tones based on their interspike interval distributions. The model quantitatively predicts the octave enlargement effect. These results are consistent with the idea that musical pitch is derived from auditory-nerve interspike interval distributions.  (+info)

Auditory and electroencephalographic effects of midazolam and alpha-hydroxy-midazolam in healthy subjects. (3/570)

AIMS: Whereas cortical EEG effects of benzodiazepines are well characterized, information about benzodiazepine effects in other areas of the central nervous system is sparse. This study investigated the action of midazolam and its active metabolite alpha-hydroxy-midazolam on different parts of the auditory pathway in six healthy volunteers in a randomized, double-blind, three-way cross-over study. METHODS: Acoustically evoked short (SLP) and middle (MLP) latency potentials, transitory evoked otoacoustic emissions (TEOAE), and EEG power spectra were analysed after short i. v. injections of placebo, or 0.15 mg kg-1 midazolam, or alpha-hydroxy-midazolam, respectively. RESULTS: All subjects fell asleep during the 4 min infusion of active drug. SLP showed a significant transient increase of Jewett wave V 10 min after injection for midazolam and alpha-hydroxy-midazolam while the latency of wave I was unchanged. Both benzodiazepines induced a marked and long-lasting MLP amplitude decrease for 240 min with slow recovery over the following 360 min. No changes of TEOAE were observed. In agreement with earlier reports, increases in EEG beta activity and decreases in alpha activity were observed after administration of either drug. CONCLUSIONS: Systemically administered benzodiazepines modulate the auditory pathway above the level of the cochlea. While SLP changes were closely associated with sedation and high plasma benzodiazepine concentrations, MLP effects persisted for hours after sedation even at low benzodiazepine plasma levels. Evoked potentials may therefore be more sensitive than EEG as a tool to monitor benzodiazepine effects.  (+info)

Functional specificity in the right human auditory cortex for perceiving pitch direction. (4/570)

Previous lesion and functional imaging studies in humans suggest a greater involvement of right rather than left auditory cortical areas in certain aspects of pitch processing. In the present study, adaptive psychophysical procedures were used to determine auditory perceptual thresholds in 14 neurologically normal subjects, and in 31 patients who had undergone surgical resection from either the right or left temporal lobe for the relief of intractable epilepsy. In a subset of the patients, the lesion encroached significantly upon the gyrus of Heschl or its underlying white matter as determined from MRI analysis. Subjects were asked to perform two different perceptual tasks on the same set of stimuli. In a pitch discrimination task, the subject had to decide whether two elements of a pure tone pair were the same or different. In a task requiring the judgement of direction of pitch change, subjects decided whether pitch rose or fell from the first tone to the second. Thresholds were determined by measuring the minimum pitch difference required for correct task performance. Mean thresholds in the pitch discrimination task did not differ between patient groups and control subjects. In contrast, patients with temporal lobe excisions that encroached upon the gyrus of Heschl in the right hemisphere (but not in the left) showed significantly elevated thresholds when judging the direction of pitch change. These findings support a specialization of function linked to right auditory cortical areas for the processing of pitch direction, and specifically suggest a dissociation between simple sensory discrimination and higher order perception.  (+info)

Incidence of presbycusis of Korean populations in Seoul, Kyunggi and Kangwon provinces. (5/570)

Presbycusis, a bilateral sensorineural hearing loss caused by changes in the inner ear, is related to multiple factors such as noise exposure and otologic disease. In institute-based studies, we tried to determine the incidence of presbycusis in Korean populations living in Seoul, Kyunggi and Kangwon provinces by gender and age groups. The subjects were people who had visited health promotion centers. Pure tone audiometry was done over 20 years on 6,028 subjects. In a community-based study, the subjects were elderly residents of Kanghwa-do area. There were no obvious factors that could cause hearing impairment in the subjects. For the pure tone audiometry, hearing threshold was obtained by using the six-dimension method. The incidence of presbycusis for subjects aged 65 years and older was 37.8% and 8.3% for > or = 27 dB HL criterion and > or = 41 dB HL criterion, respectively. The incidence increased with age. A statistically significant difference in the hearing threshold was found between men and women aged 65 years or older. No differences were found between the community-based study and the institute- based studies. There was a high incidence (about 40%) of presbycusis among Koreans aged 65 years or older (for > or = 27 dB HL criterion). With an aging population, we anticipate that this report could be used to provide a basic data for the study of presbycusis.  (+info)

Children's detection of pure-tone signals with random multitone maskers. (6/570)

Preschoolers and adults were asked to detect a 1000-Hz signal, which was masked by a multitone complex. The frequencies and amplitudes of the components in the complex varied randomly and independently on each presentation. A staircase, cued two-interval, forced-choice procedure disguised as a "listening game" was used to obtain signal thresholds in quiet and in the presence of the multitone maskers. The number of components in the masker was fixed within an experimental condition and varied from 2 to 906 across experimental conditions. Thresholds were also measured with a broadband noise masker. Eight preschool children and eight adults were tested. Although individual differences were large, among both adults and children, there was little difference between the groups in the mean amount of masking produced by the maskers with large numbers of components (400 and 906). There was also a small but significant difference between adults and children in the mean amount of masking produced by the broadband noise. The difference between the groups was much larger with smaller numbers of components. Data obtained from the adults were basically similar to that previously reported [cf. Neff and Green, Percept. Psychophys. 41, 409-415 (1987); Oh and Lutfi, J. Acoust. Soc. Am. 104, 3489-3499 (1998)]: maskers comprised of 10-40 components produced as much as 30 to 60 dB of masking in some, but not all listeners. Those same maskers produced larger amounts of masking (70-83 dB) in many of the preschool children, although, as in the adult group, individual differences were large. The component-relative-entropy (CoRE) model [Lutfi, J. Acoust. Soc. Am. 94, 748-758 (1993)] was used to describe the differences in performance between the children and adults. According to this model the average child appears to integrate information over a larger number of auditory filters than the average adult.  (+info)

Hearing restoration from deafness after resection of a large cerebellopontine angle meningioma--case report. (7/570)

A 61-year-old man presented with a large cerebellopontine angle meningioma manifesting as a 1-year history of deafness on the right side, in whom hearing was restored from the deaf state immediately after tumor resection. Neuroimaging demonstrated a large mass in the right cerebellopontine angle, originating at the region adjacent to the jugular foramen. Audiometry showed his hearing was off-scale (> 105 dB) on the right. The tumor was successfully removed through the retrosigmoid approach, and the integrity of the 7th and 8th cranial nerves was maintained. The patient regained hearing on the day after the operation, which continued to improve until near-normal. The 8th cranial nerve function may recover dramatically after removal of non-acoustic tumors, even if preoperative hearing loss is profound. To maximize the opportunity to regain hearing, approaches which devastate cochlear function should be avoided and more meticulous manipulation during tumor removal is needed.  (+info)

Occurrence and risk of cochleotoxicity in cystic fibrosis patients receiving repeated high-dose aminoglycoside therapy. (8/570)

Cystic fibrosis (CF) patients receive repeated courses of aminoglycoside therapy. These patients would consequently be expected to be more susceptible to cochleotoxicity, a recognized side effect with single courses of aminoglycoside therapy. The primary aim of this retrospective study was to establish the incidence and severity of auditory deficit in CF patients. Standard (0.25- to 8-kHz) and high-frequency (10- to 16-kHz) pure-tone audiometry was carried out in 70 CF patients, and the results were compared with the results from 91 control subjects. These subjects were further divided into pediatric and adult groups. Of 70 CF patients, 12 (1 pediatric) displayed hearing loss considered to be caused by repeated exposure to aminoglycosides. There was a nonlinear relationship between the courses of therapy received and the incidence of hearing loss. The severity of the loss did not appear to be related to the number of courses received. Assuming the risk of loss to be independent for each course, preliminary estimates of per course risk of hearing loss were less than 2%. Upon comparison with previous clinical studies and experimental work, these findings suggest that the incidence of cochleotoxicity in CF patients is considerably lower than would be expected, suggesting that the CF condition may confer protection against aminoglycoside cochleotoxicity.  (+info)

Audiometry is the testing of a person's ability to hear different sounds, pitches, or frequencies. It is typically conducted using an audiometer, a device that emits tones at varying volumes and frequencies. The person being tested wears headphones and indicates when they can hear the tone by pressing a button or raising their hand.

There are two main types of audiometry: pure-tone audiometry and speech audiometry. Pure-tone audiometry measures a person's ability to hear different frequencies at varying volumes, while speech audiometry measures a person's ability to understand spoken words at different volumes and in the presence of background noise.

The results of an audiometry test are typically plotted on an audiogram, which shows the quietest sounds that a person can hear at different frequencies. This information can be used to diagnose hearing loss, determine its cause, and develop a treatment plan.

Pure-tone audiometry is a hearing test that measures a person's ability to hear different sounds, pitches, or frequencies. During the test, pure tones are presented to the patient through headphones or ear inserts, and the patient is asked to indicate each time they hear the sound by raising their hand, pressing a button, or responding verbally.

The softest sound that the person can hear at each frequency is recorded as the hearing threshold, and a graph called an audiogram is created to show the results. The audiogram provides information about the type and degree of hearing loss in each ear. Pure-tone audiometry is a standard hearing test used to diagnose and monitor hearing disorders.

Audiometry, evoked response is a hearing test that measures the brain's response to sound. It is often used to detect hearing loss in infants and young children, as well as in people who are unable to cooperate or communicate during traditional hearing tests.

During the test, electrodes are placed on the scalp to measure the electrical activity produced by the brain in response to sounds presented through earphones. The responses are recorded and analyzed to determine the quietest sounds that can be heard at different frequencies. This information is used to help diagnose and manage hearing disorders.

There are several types of evoked response audiometry, including:

* Auditory Brainstem Response (ABR): measures the electrical activity from the brainstem in response to sound.
* Auditory Steady-State Response (ASSR): measures the brain's response to continuous sounds at different frequencies and loudness levels.
* Auditory Middle Latency Response (AMLR): measures the electrical activity from the auditory cortex in response to sound.

These tests are usually performed in a quiet, sound-treated room and can take several hours to complete.

The auditory threshold is the minimum sound intensity or loudness level that a person can detect 50% of the time, for a given tone frequency. It is typically measured in decibels (dB) and represents the quietest sound that a person can hear. The auditory threshold can be affected by various factors such as age, exposure to noise, and certain medical conditions. Hearing tests, such as pure-tone audiometry, are used to measure an individual's auditory thresholds for different frequencies.

High-frequency hearing loss is a type of sensorineural hearing impairment in which the ability to hear and discriminate sounds in the higher frequency range (3000 Hz or above) is diminished. This type of hearing loss can make it difficult for individuals to understand speech, especially in noisy environments, as many consonant sounds fall within this frequency range. High-frequency hearing loss can be caused by various factors including aging, exposure to loud noises, genetics, certain medical conditions, and ototoxic medications. It is typically diagnosed through a series of hearing tests, such as pure tone audiometry, and may be treated with hearing aids or other assistive listening devices.

Hearing disorders, also known as hearing impairments or auditory impairments, refer to conditions that affect an individual's ability to hear sounds in one or both ears. These disorders can range from mild to profound and may result from genetic factors, aging, exposure to loud noises, infections, trauma, or certain medical conditions.

There are mainly two types of hearing disorders: conductive hearing loss and sensorineural hearing loss. Conductive hearing loss occurs when there is a problem with the outer or middle ear, preventing sound waves from reaching the inner ear. Causes include earwax buildup, fluid in the middle ear, a perforated eardrum, or damage to the ossicles (the bones in the middle ear).

Sensorineural hearing loss, on the other hand, is caused by damage to the inner ear (cochlea) or the nerve pathways from the inner ear to the brain. This type of hearing loss is often permanent and can be due to aging (presbycusis), exposure to loud noises, genetics, viral infections, certain medications, or head injuries.

Mixed hearing loss is a combination of both conductive and sensorineural components. In some cases, hearing disorders can also involve tinnitus (ringing or other sounds in the ears) or vestibular problems that affect balance and equilibrium.

Early identification and intervention for hearing disorders are crucial to prevent further deterioration and to help individuals develop appropriate communication skills and maintain a good quality of life.

Acoustic impedance tests are diagnostic procedures used to measure the impedance or resistance of various parts of the ear to sound waves. These tests are often used to assess hearing function and diagnose any issues related to the middle ear, such as fluid buildup or problems with the eardrum.

The most common type of acoustic impedance test is tympanometry, which measures the mobility of the eardrum and the middle ear system by creating variations in air pressure within the ear canal. During this test, a small probe is inserted into the ear canal, and sound waves are generated while the pressure is varied. The resulting measurements provide information about the condition of the middle ear and can help identify any issues that may be affecting hearing.

Another type of acoustic impedance test is acoustic reflex testing, which measures the body's natural response to loud sounds. This involves measuring the contraction of the stapedius muscle in the middle ear, which occurs in response to loud noises. By measuring the strength and timing of this reflex, audiologists can gain additional insights into the functioning of the middle ear and identify any abnormalities that may be present.

Overall, acoustic impedance tests are important tools for diagnosing hearing problems and identifying any underlying issues in the middle ear. They are often used in conjunction with other hearing tests to provide a comprehensive assessment of an individual's hearing function.

Noise-induced hearing loss (NIHL) is a type of sensorineural hearing loss that occurs due to exposure to harmful levels of noise. The damage can be caused by a one-time exposure to an extremely loud sound or by continuous exposure to lower level sounds over time. NIHL can affect people of all ages and can cause permanent damage to the hair cells in the cochlea, leading to hearing loss, tinnitus (ringing in the ears), and difficulty understanding speech in noisy environments. Prevention measures include avoiding excessive noise exposure, wearing hearing protection, and taking regular breaks from noisy activities.

Hearing loss is a partial or total inability to hear sounds in one or both ears. It can occur due to damage to the structures of the ear, including the outer ear, middle ear, inner ear, or nerve pathways that transmit sound to the brain. The degree of hearing loss can vary from mild (difficulty hearing soft sounds) to severe (inability to hear even loud sounds). Hearing loss can be temporary or permanent and may be caused by factors such as exposure to loud noises, genetics, aging, infections, trauma, or certain medical conditions. It is important to note that hearing loss can have significant impacts on a person's communication abilities, social interactions, and overall quality of life.

A hearing test is a procedure used to evaluate a person's ability to hear different sounds, pitches, or frequencies. It is performed by a hearing healthcare professional in a sound-treated booth or room with calibrated audiometers. The test measures a person's hearing sensitivity at different frequencies and determines the quietest sounds they can hear, known as their hearing thresholds.

There are several types of hearing tests, including:

1. Pure Tone Audiometry (PTA): This is the most common type of hearing test, where the person is presented with pure tones at different frequencies and volumes through headphones or ear inserts. The person indicates when they hear the sound by pressing a button or raising their hand.
2. Speech Audiometry: This test measures a person's ability to understand speech at different volume levels. The person is asked to repeat words presented to them in quiet and in background noise.
3. Tympanometry: This test measures the function of the middle ear by creating variations in air pressure in the ear canal. It can help identify issues such as fluid buildup or a perforated eardrum.
4. Acoustic Reflex Testing: This test measures the body's natural response to loud sounds and can help identify the location of damage in the hearing system.
5. Otoacoustic Emissions (OAEs): This test measures the sound that is produced by the inner ear when it is stimulated by a sound. It can help identify cochlear damage or abnormalities.

Hearing tests are important for diagnosing and monitoring hearing loss, as well as identifying any underlying medical conditions that may be causing the hearing problems.

Occupational noise is defined as exposure to excessive or harmful levels of sound in the workplace that has the potential to cause adverse health effects such as hearing loss, tinnitus, and stress-related symptoms. The measurement of occupational noise is typically expressed in units of decibels (dB), and the permissible exposure limits are regulated by organizations such as the Occupational Safety and Health Administration (OSHA) in the United States.

Exposure to high levels of occupational noise can lead to permanent hearing loss, which is often irreversible. It can also interfere with communication and concentration, leading to decreased productivity and increased risk of accidents. Therefore, it is essential to implement appropriate measures to control and reduce occupational noise exposure in the workplace.

Hearing is the ability to perceive sounds by detecting vibrations in the air or other mediums and translating them into nerve impulses that are sent to the brain for interpretation. In medical terms, hearing is defined as the sense of sound perception, which is mediated by the ear and interpreted by the brain. It involves a complex series of processes, including the conduction of sound waves through the outer ear to the eardrum, the vibration of the middle ear bones, and the movement of fluid in the inner ear, which stimulates hair cells to send electrical signals to the auditory nerve and ultimately to the brain. Hearing allows us to communicate with others, appreciate music and sounds, and detect danger or important events in our environment.

Tinnitus is the perception of ringing or other sounds in the ears or head when no external sound is present. It can be described as a sensation of hearing sound even when no actual noise is present. The sounds perceived can vary widely, from a whistling, buzzing, hissing, swooshing, to a pulsating sound, and can be soft or loud.

Tinnitus is not a disease itself but a symptom that can result from a wide range of underlying causes, such as hearing loss, exposure to loud noises, ear infections, earwax blockage, head or neck injuries, circulatory system disorders, certain medications, and age-related hearing loss.

Tinnitus can be temporary or chronic, and it may affect one or both ears. While tinnitus is not usually a sign of a serious medical condition, it can significantly impact quality of life and interfere with daily activities, sleep, and concentration.

Acoustic stimulation refers to the use of sound waves or vibrations to elicit a response in an individual, typically for the purpose of assessing or treating hearing, balance, or neurological disorders. In a medical context, acoustic stimulation may involve presenting pure tones, speech sounds, or other types of auditory signals through headphones, speakers, or specialized devices such as bone conduction transducers.

The response to acoustic stimulation can be measured using various techniques, including electrophysiological tests like auditory brainstem responses (ABRs) or otoacoustic emissions (OAEs), behavioral observations, or functional imaging methods like fMRI. Acoustic stimulation is also used in therapeutic settings, such as auditory training programs for hearing impairment or vestibular rehabilitation for balance disorders.

It's important to note that acoustic stimulation should be administered under the guidance of a qualified healthcare professional to ensure safety and effectiveness.

Spontaneous otoacoustic emissions (SOAEs) are low-level sounds that are produced by the inner ear (cochlea) without any external stimulation. They can be recorded in a quiet room using specialized microphones placed inside the ear canal. SOAEs are thought to arise from the motion of the hair cells within the cochlea, which generate tiny currents in response to sound. These currents then cause the surrounding fluid and tissue to vibrate, producing sound waves that can be detected with a microphone.

SOAEs are typically present in individuals with normal hearing, although their presence or absence is not a definitive indicator of hearing ability. They tend to occur at specific frequencies and can vary from person to person. In some cases, SOAEs may be absent or reduced in individuals with hearing loss or damage to the hair cells in the cochlea.

It's worth noting that SOAEs are different from evoked otoacoustic emissions (EOAEs), which are sounds produced by the inner ear in response to external stimuli, such as clicks or tones. Both types of otoacoustic emissions are used in hearing tests and research to assess cochlear function and health.

Sensorineural hearing loss (SNHL) is a type of hearing impairment that occurs due to damage to the inner ear (cochlea) or to the nerve pathways from the inner ear to the brain. It can be caused by various factors such as aging, exposure to loud noises, genetics, certain medical conditions (like diabetes and heart disease), and ototoxic medications.

SNHL affects the ability of the hair cells in the cochlea to convert sound waves into electrical signals that are sent to the brain via the auditory nerve. As a result, sounds may be perceived as muffled, faint, or distorted, making it difficult to understand speech, especially in noisy environments.

SNHL is typically permanent and cannot be corrected with medication or surgery, but hearing aids or cochlear implants can help improve communication and quality of life for those affected.

Ear protective devices are types of personal protective equipment designed to protect the ears from potential damage or injury caused by excessive noise or pressure changes. These devices typically come in two main forms: earplugs and earmuffs.

Earplugs are small disposable or reusable plugs that are inserted into the ear canal to block out or reduce loud noises. They can be made of foam, rubber, plastic, or other materials and are available in different sizes to fit various ear shapes and sizes.

Earmuffs, on the other hand, are headbands with cups that cover the entire outer ear. The cups are typically made of sound-absorbing materials such as foam or fluid-filled cushions that help to block out noise. Earmuffs can be used in combination with earplugs for added protection.

Both earplugs and earmuffs are commonly used in industrial settings, construction sites, concerts, shooting ranges, and other noisy environments to prevent hearing loss or damage. It is important to choose the right type of ear protective device based on the level and type of noise exposure, as well as individual comfort and fit.

Auditory brainstem evoked potentials (ABEPs or BAEPs) are medical tests that measure the electrical activity in the auditory pathway of the brain in response to sound stimulation. The test involves placing electrodes on the scalp and recording the tiny electrical signals generated by the nerve cells in the brainstem as they respond to clicks or tone bursts presented through earphones.

The resulting waveform is analyzed for latency (the time it takes for the signal to travel from the ear to the brain) and amplitude (the strength of the signal). Abnormalities in the waveform can indicate damage to the auditory nerve or brainstem, and are often used in the diagnosis of various neurological conditions such as multiple sclerosis, acoustic neuroma, and brainstem tumors.

The test is non-invasive, painless, and takes only a few minutes to perform. It provides valuable information about the functioning of the auditory pathway and can help guide treatment decisions for patients with hearing or balance disorders.

Auditory fatigue, also known as temporary threshold shift, refers to a temporary decrease in hearing sensitivity that occurs after exposure to loud sounds. It is usually temporary and recovers after a period of rest and avoidance of further noise exposure. However, repeated or prolonged exposures to loud sounds can lead to permanent hearing damage or tinnitus.

The exact mechanism of auditory fatigue is not fully understood, but it is believed to be related to the temporary reduction in the sensitivity of hair cells in the inner ear (cochlea) that are responsible for converting sound waves into electrical signals that are sent to the brain. This reduction in sensitivity can make it difficult to hear quiet sounds and may cause sounds to seem distorted or muffled.

If you experience auditory fatigue, it is important to give your ears a rest and avoid further exposure to loud noises until your hearing returns to normal. If you are regularly exposed to loud noises as part of your job or hobbies, it is important to use appropriate hearing protection to prevent permanent damage to your hearing.

Pitch discrimination, in the context of audiology and neuroscience, refers to the ability to perceive and identify the difference in pitch between two or more sounds. It is the measure of how accurately an individual can distinguish between different frequencies or tones. This ability is crucial for various aspects of hearing, such as understanding speech, appreciating music, and localizing sound sources.

Pitch discrimination is typically measured using psychoacoustic tests, where a listener is presented with two sequential tones and asked to determine whether the second tone is higher or lower in pitch than the first one. The smallest detectable difference between the frequencies of these two tones is referred to as the "just noticeable difference" (JND) or the "difference limen." This value can be used to quantify an individual's pitch discrimination abilities and may vary depending on factors such as frequency, intensity, and age.

Deficits in pitch discrimination can have significant consequences for various aspects of daily life, including communication difficulties and reduced enjoyment of music. These deficits can result from damage to the auditory system due to factors like noise exposure, aging, or certain medical conditions, such as hearing loss or neurological disorders.

Conductive hearing loss is a type of hearing loss that occurs when there is a problem with the outer or middle ear. Sound waves are not able to transmit efficiently through the ear canal to the eardrum and the small bones in the middle ear, resulting in a reduction of sound that reaches the inner ear. Causes of conductive hearing loss may include earwax buildup, fluid in the middle ear, a middle ear infection, a hole in the eardrum, or problems with the tiny bones in the middle ear. This type of hearing loss can often be treated through medical intervention or surgery.

Speech Audiometry is a hearing test that measures a person's ability to understand and recognize spoken words at different volumes and frequencies. It is used to assess the function of the auditory system, particularly in cases where there is a suspected problem with speech discrimination or understanding spoken language.

The test typically involves presenting lists of words to the patient at varying intensity levels and asking them to repeat what they hear. The examiner may also present sentences with missing words that the patient must fill in. Based on the results, the audiologist can determine the quietest level at which the patient can reliably detect speech and the degree of speech discrimination ability.

Speech Audiometry is often used in conjunction with pure-tone audiometry to provide a more comprehensive assessment of hearing function. It can help identify any specific patterns of hearing loss, such as those caused by nerve damage or cochlear dysfunction, and inform decisions about treatment options, including the need for hearing aids or other assistive devices.

In the context of medicine, particularly in audiology and otolaryngology (ear, nose, and throat specialty), "noise" is defined as unwanted or disturbing sound in the environment that can interfere with communication, rest, sleep, or cognitive tasks. It can also refer to sounds that are harmful to hearing, such as loud machinery noises or music, which can cause noise-induced hearing loss if exposure is prolonged or at high enough levels.

In some medical contexts, "noise" may also refer to non-specific signals or interfering factors in diagnostic tests and measurements that can make it difficult to interpret results accurately.

Pitch perception is the ability to identify and discriminate different frequencies or musical notes. It is the way our auditory system interprets and organizes sounds based on their highness or lowness, which is determined by the frequency of the sound waves. A higher pitch corresponds to a higher frequency, while a lower pitch corresponds to a lower frequency. Pitch perception is an important aspect of hearing and is crucial for understanding speech, enjoying music, and localizing sounds in our environment. It involves complex processing in the inner ear and auditory nervous system.

Bone conduction is a type of hearing mechanism that involves the transmission of sound vibrations directly to the inner ear through the bones of the skull, bypassing the outer and middle ears. This occurs when sound waves cause the bones in the skull to vibrate, stimulating the cochlea (the spiral cavity of the inner ear) and its hair cells, which convert the mechanical energy of the vibrations into electrical signals that are sent to the brain and interpreted as sound.

Bone conduction is a natural part of the hearing process in humans, but it can also be used artificially through the use of bone-conduction devices, such as hearing aids or headphones, which transmit sound vibrations directly to the skull. This type of transmission can provide improved hearing for individuals with conductive hearing loss, mixed hearing loss, or single-sided deafness, as it bypasses damaged or obstructed outer and middle ears.

Auditory evoked potentials (AEP) are medical tests that measure the electrical activity in the brain in response to sound stimuli. These tests are often used to assess hearing function and neural processing in individuals, particularly those who cannot perform traditional behavioral hearing tests.

There are several types of AEP tests, including:

1. Brainstem Auditory Evoked Response (BAER) or Brainstem Auditory Evoked Potentials (BAEP): This test measures the electrical activity generated by the brainstem in response to a click or tone stimulus. It is often used to assess the integrity of the auditory nerve and brainstem pathways, and can help diagnose conditions such as auditory neuropathy and retrocochlear lesions.
2. Middle Latency Auditory Evoked Potentials (MLAEP): This test measures the electrical activity generated by the cortical auditory areas of the brain in response to a click or tone stimulus. It is often used to assess higher-level auditory processing, and can help diagnose conditions such as auditory processing disorders and central auditory dysfunction.
3. Long Latency Auditory Evoked Potentials (LLAEP): This test measures the electrical activity generated by the cortical auditory areas of the brain in response to a complex stimulus, such as speech. It is often used to assess language processing and cognitive function, and can help diagnose conditions such as learning disabilities and dementia.

Overall, AEP tests are valuable tools for assessing hearing and neural function in individuals who cannot perform traditional behavioral hearing tests or who have complex neurological conditions.

Auditory perception refers to the process by which the brain interprets and makes sense of the sounds we hear. It involves the recognition and interpretation of different frequencies, intensities, and patterns of sound waves that reach our ears through the process of hearing. This allows us to identify and distinguish various sounds such as speech, music, and environmental noises.

The auditory system includes the outer ear, middle ear, inner ear, and the auditory nerve, which transmits electrical signals to the brain's auditory cortex for processing and interpretation. Auditory perception is a complex process that involves multiple areas of the brain working together to identify and make sense of sounds in our environment.

Disorders or impairments in auditory perception can result in difficulties with hearing, understanding speech, and identifying environmental sounds, which can significantly impact communication, learning, and daily functioning.

The auditory cortex is the region of the brain that is responsible for processing and analyzing sounds, including speech. It is located in the temporal lobe of the cerebral cortex, specifically within the Heschl's gyrus and the surrounding areas. The auditory cortex receives input from the auditory nerve, which carries sound information from the inner ear to the brain.

The auditory cortex is divided into several subregions that are responsible for different aspects of sound processing, such as pitch, volume, and location. These regions work together to help us recognize and interpret sounds in our environment, allowing us to communicate with others and respond appropriately to our surroundings. Damage to the auditory cortex can result in hearing loss or difficulty understanding speech.

Psychoacoustics is a branch of psychophysics that deals with the study of the psychological and physiological responses to sound. It involves understanding how people perceive, interpret, and react to different sounds, including speech, music, and environmental noises. This field combines knowledge from various areas such as psychology, acoustics, physics, and engineering to investigate the relationship between physical sound characteristics and human perception. Research in psychoacoustics has applications in fields like hearing aid design, noise control, music perception, and communication systems.

Otoscopy is a medical examination procedure used to evaluate the external auditory canal and tympanic membrane (eardrum). It involves the use of an otoscope, a tool that consists of a lighted speculum attached to a handle. The speculum is inserted into the ear canal, allowing the healthcare provider to visualize and inspect the eardrum for any abnormalities such as perforations, inflammation, fluid accumulation, or foreign bodies. Otoscopy can help diagnose various conditions including ear infections, middle ear disorders, and hearing loss.

Central auditory diseases refer to a group of disorders that affect the processing of auditory information in the central nervous system, specifically in the brainstem and cortex. These disorders can result from various causes, such as head injuries, infections, tumors, or degenerative conditions. They can cause difficulties with understanding speech, locating the source of sounds, and perceiving complex or rapidly changing auditory stimuli.

Central auditory processing disorder (CAPD) is a common type of central auditory disease. It is a hearing problem that affects about 5% of school-aged children. Kids with CAPD can't process what they hear in the same way other kids do because their ears and brain don't fully coordinate. Something interferes with the way the brain recognizes and interprets sounds, especially speech.

CAPD is not a hearing loss or an intelligence problem. Children with CAPD have normal structural hearing and can often hear sounds that are presented to them individually. However, they may struggle to understand speech in noisy environments, follow complex directions, or distinguish similar sounds from one another.

Central auditory diseases are typically diagnosed through a series of tests that assess different aspects of auditory processing, such as speech recognition in noise, temporal processing, and binaural integration. Treatment for these disorders may include auditory training, assistive listening devices, and environmental modifications to help compensate for the processing difficulties.

In the context of medicine, particularly in the field of auscultation (the act of listening to the internal sounds of the body), "sound" refers to the noises produced by the functioning of the heart, lungs, and other organs. These sounds are typically categorized into two types:

1. **Bradyacoustic sounds**: These are low-pitched sounds that are heard when there is a turbulent flow of blood or when two body structures rub against each other. An example would be the heart sound known as "S1," which is produced by the closure of the mitral and tricuspid valves at the beginning of systole (contraction of the heart's ventricles).

2. **High-pitched sounds**: These are sharper, higher-frequency sounds that can provide valuable diagnostic information. An example would be lung sounds, which include breath sounds like those heard during inhalation and exhalation, as well as adventitious sounds like crackles, wheezes, and pleural friction rubs.

It's important to note that these medical "sounds" are not the same as the everyday definition of sound, which refers to the sensation produced by stimulation of the auditory system by vibrations.

A "reflex, acoustic" is not a standard medical term. However, it seems like you might be looking for a definition of the "acoustic reflex." The acoustic reflex is an involuntary muscle contraction that occurs in the middle ear in response to loud sounds. This reflex helps protect the inner ear from damage caused by high-intensity sounds.

When a loud sound reaches the ear, it stimulates the stapedius muscle in the middle ear, which then contracts and causes the stapes bone (one of the three bones in the middle ear) to become stiffer. This stiffening reduces the amount of sound that is transmitted to the inner ear, thus protecting it from potential harm.

The acoustic reflex can be measured using a device called an impedance audiometer, which measures changes in the pressure within the ear canal caused by muscle contraction during the reflex. This measurement provides valuable information for diagnosing and monitoring various hearing and balance disorders.

Tympanoplasty is a surgical procedure performed to reconstruct or repair the tympanic membrane (eardrum) and/or the small bones of the middle ear (ossicles). The primary goal of this surgery is to restore hearing, but it can also help manage chronic middle ear infections, traumatic eardrum perforations, or cholesteatoma (a skin growth in the middle ear).

During the procedure, a surgeon may use various techniques such as grafting tissue from another part of the body to rebuild the eardrum or using prosthetic materials to reconstruct the ossicles. The choice of technique depends on the extent and location of the damage. Tympanoplasty is typically an outpatient procedure, meaning patients can return home on the same day of the surgery.

Auditory pathways refer to the series of structures and nerves in the body that are involved in processing sound and transmitting it to the brain for interpretation. The process begins when sound waves enter the ear and cause vibrations in the eardrum, which then move the bones in the middle ear. These movements stimulate hair cells in the cochlea, a spiral-shaped structure in the inner ear, causing them to release neurotransmitters that activate auditory nerve fibers.

The auditory nerve carries these signals to the brainstem, where they are relayed through several additional structures before reaching the auditory cortex in the temporal lobe of the brain. Here, the signals are processed and interpreted as sounds, allowing us to hear and understand speech, music, and other environmental noises.

Damage or dysfunction at any point along the auditory pathway can lead to hearing loss or impairment.

I'm sorry for any confusion, but "Neural Analyzers" is not a recognized term in medical science or neurology. It may be a term used in a specific context or field, such as in engineering or technology, to refer to devices that analyze neural signals. However, I would need more context to provide an accurate definition. If you're referring to a specific device or concept, could you please provide more details?

I'm sorry for any confusion, but "music" is not a term that has a medical definition. Music is a form of art that uses sound organized in time. It may include elements such as melody, harmony, rhythm, and dynamics. While music can have various psychological and physiological effects on individuals, it is not considered a medical term with a specific diagnosis or treatment application. If you have any questions related to medicine or health, I'd be happy to try to help answer those for you!

Hearing aids are electronic devices designed to improve hearing and speech comprehension for individuals with hearing loss. They consist of a microphone, an amplifier, a speaker, and a battery. The microphone picks up sounds from the environment, the amplifier increases the volume of these sounds, and the speaker sends the amplified sound into the ear. Modern hearing aids often include additional features such as noise reduction, directional microphones, and wireless connectivity to smartphones or other devices. They are programmed to meet the specific needs of the user's hearing loss and can be adjusted for comfort and effectiveness. Hearing aids are available in various styles, including behind-the-ear (BTE), receiver-in-canal (RIC), in-the-ear (ITE), and completely-in-canal (CIC).

Auditory perceptual disorders, also known as auditory processing disorders (APD), refer to a group of hearing-related problems in which the ears are able to hear sounds normally, but the brain has difficulty interpreting or making sense of those sounds. This means that individuals with APD have difficulty recognizing and discriminating speech sounds, especially in noisy environments. They may also have trouble identifying where sounds are coming from, distinguishing between similar sounds, and understanding spoken language when it is rapid or complex.

APD can lead to difficulties in academic performance, communication, and social interactions. It is important to note that APD is not a hearing loss, but rather a problem with how the brain processes auditory information. Diagnosis of APD typically involves a series of tests administered by an audiologist, and treatment may include specialized therapy and/or assistive listening devices.

Ear diseases are medical conditions that affect the ear and its various components, including the outer ear, middle ear, and inner ear. These diseases can cause a range of symptoms, such as hearing loss, tinnitus (ringing in the ears), vertigo (dizziness), ear pain, and discharge. Some common ear diseases include:

1. Otitis externa (swimmer's ear) - an infection or inflammation of the outer ear and ear canal.
2. Otitis media - an infection or inflammation of the middle ear, often caused by a cold or flu.
3. Cholesteatoma - a skin growth that develops in the middle ear behind the eardrum.
4. Meniere's disease - a disorder of the inner ear that can cause vertigo, hearing loss, and tinnitus.
5. Temporomandibular joint (TMJ) disorders - problems with the joint that connects the jawbone to the skull, which can cause ear pain and other symptoms.
6. Acoustic neuroma - a noncancerous tumor that grows on the nerve that connects the inner ear to the brain.
7. Presbycusis - age-related hearing loss.

Treatment for ear diseases varies depending on the specific condition and its severity. It may include medication, surgery, or other therapies. If you are experiencing symptoms of an ear disease, it is important to seek medical attention from a healthcare professional, such as an otolaryngologist (ear, nose, and throat specialist).

Vestibular diseases are a group of disorders that affect the vestibular system, which is responsible for maintaining balance and spatial orientation. The vestibular system includes the inner ear and parts of the brain that process sensory information related to movement and position.

These diseases can cause symptoms such as vertigo (a spinning sensation), dizziness, imbalance, nausea, and visual disturbances. Examples of vestibular diseases include:

1. Benign paroxysmal positional vertigo (BPPV): a condition in which small crystals in the inner ear become dislodged and cause brief episodes of vertigo triggered by changes in head position.
2. Labyrinthitis: an inner ear infection that can cause sudden onset of vertigo, hearing loss, and tinnitus (ringing in the ears).
3. Vestibular neuronitis: inflammation of the vestibular nerve that causes severe vertigo, nausea, and imbalance but typically spares hearing.
4. Meniere's disease: a disorder characterized by recurrent episodes of vertigo, tinnitus, hearing loss, and a feeling of fullness in the affected ear.
5. Vestibular migraine: a type of migraine that includes vestibular symptoms such as dizziness, imbalance, and disorientation.
6. Superior canal dehiscence syndrome: a condition in which there is a thinning or absence of bone over the superior semicircular canal in the inner ear, leading to vertigo, sound- or pressure-induced dizziness, and hearing loss.
7. Bilateral vestibular hypofunction: reduced function of both vestibular systems, causing chronic imbalance, unsteadiness, and visual disturbances.

Treatment for vestibular diseases varies depending on the specific diagnosis but may include medication, physical therapy, surgery, or a combination of these approaches.

Vertigo is a specific type of dizziness characterized by the sensation that you or your surroundings are spinning or moving, even when you're perfectly still. It's often caused by issues with the inner ear or the balance-sensing systems of the body. Vertigo can be brought on by various conditions, such as benign paroxysmal positional vertigo (BPPV), labyrinthitis, vestibular neuritis, Meniere's disease, and migraines. In some cases, vertigo may also result from head or neck injuries, brain disorders like stroke or tumors, or certain medications. Treatment for vertigo depends on the underlying cause and can include specific exercises, medication, or surgery in severe cases.

Otosclerosis is a medical condition that affects the bones in the middle ear. It is characterized by the abnormal growth and hardening (sclerosis) of the otosclerotic bone near the stapes footplate, one of the tiny bones in the middle ear (ossicles). This abnormal bone growth can cause stiffness or fixation of the stapes bone, preventing it from vibrating properly and leading to conductive hearing loss. In some cases, otosclerosis may also result in sensorineural hearing loss due to involvement of the inner ear structures. The exact cause of otosclerosis is not fully understood, but it is believed to have a genetic component and can sometimes be associated with pregnancy. Treatment options for otosclerosis include hearing aids or surgical procedures like stapedectomy or stapedotomy to bypass or remove the affected bone and improve hearing.

The cochlear nerve, also known as the auditory nerve, is the sensory nerve that transmits sound signals from the inner ear to the brain. It consists of two parts: the outer spiral ganglion and the inner vestibular portion. The spiral ganglion contains the cell bodies of the bipolar neurons that receive input from hair cells in the cochlea, which is the snail-shaped organ in the inner ear responsible for hearing. These neurons then send their axons to form the cochlear nerve, which travels through the internal auditory meatus and synapses with neurons in the cochlear nuclei located in the brainstem.

Damage to the cochlear nerve can result in hearing loss or deafness, depending on the severity of the injury. Common causes of cochlear nerve damage include acoustic trauma, such as exposure to loud noises, viral infections, meningitis, and tumors affecting the nerve or surrounding structures. In some cases, cochlear nerve damage may be treated with hearing aids, cochlear implants, or other assistive devices to help restore or improve hearing function.

Stapes surgery, also known as stapedectomy or stapedotomy, is a surgical procedure performed to correct hearing loss caused by otosclerosis. Otosclerosis is a condition in which the stapes bone in the middle ear becomes fixed and unable to vibrate properly, leading to conductive hearing loss.

During stapes surgery, the surgeon makes an incision behind the ear and creates a small opening in the eardrum. The fixed stapes bone is then removed or modified, and a prosthetic device is inserted in its place to allow sound vibrations to be transmitted to the inner ear. In some cases, a piece of tissue or artificial material may be used to fill the space left by the removed bone.

Stapedectomy involves complete removal of the stapes bone, while stapedotomy involves making a small hole in the stapes bone and inserting a prosthetic device through it. Both procedures are typically performed on an outpatient basis and have a high success rate in restoring hearing. However, as with any surgical procedure, there are risks involved, including infection, permanent hearing loss, and balance problems.

Loudness perception refers to the subjective experience of the intensity or volume of a sound, which is a psychological response to the physical property of sound pressure level. It is a measure of how loud or soft a sound seems to an individual, and it can be influenced by various factors such as frequency, duration, and the context in which the sound is heard.

The perception of loudness is closely related to the concept of sound intensity, which is typically measured in decibels (dB). However, while sound intensity is an objective physical measurement, loudness is a subjective experience that can vary between individuals and even for the same individual under different listening conditions.

Loudness perception is a complex process that involves several stages of auditory processing, including mechanical transduction of sound waves by the ear, neural encoding of sound information in the auditory nerve, and higher-level cognitive processes that interpret and modulate the perceived loudness of sounds. Understanding the mechanisms underlying loudness perception is important for developing hearing aids, cochlear implants, and other assistive listening devices, as well as for diagnosing and treating various hearing disorders.

Functional hearing loss, also known as non-organic or psychogenic hearing loss, is a hearing impairment that is not due to an underlying medical condition or structural damage to the ear. Instead, it is thought to be caused by psychological or emotional factors, such as stress, anxiety, or depression.

In functional hearing loss, the person's hearing ability may appear to fluctuate or vary depending on the situation and their emotional state. They may have difficulty hearing in certain situations or with certain people, but perform better in others. In some cases, they may report hearing sounds that are not present or misinterpret what is being said.

Functional hearing loss can be difficult to diagnose and treat, as there may not be any obvious physical cause for the hearing impairment. A comprehensive evaluation by an audiologist or other healthcare professional is typically necessary to determine the underlying cause of the hearing loss and develop an appropriate treatment plan. Treatment may involve counseling, therapy, or other interventions aimed at addressing the psychological or emotional factors contributing to the hearing loss.

Speech perception is the process by which the brain interprets and understands spoken language. It involves recognizing and discriminating speech sounds (phonemes), organizing them into words, and attaching meaning to those words in order to comprehend spoken language. This process requires the integration of auditory information with prior knowledge and context. Factors such as hearing ability, cognitive function, and language experience can all impact speech perception.

Bilateral hearing loss refers to a type of hearing loss that affects both ears equally or to varying degrees. It can be further categorized into two types: sensorineural and conductive hearing loss. Sensorineural hearing loss occurs due to damage to the inner ear or nerve pathways from the inner ear to the brain, while conductive hearing loss happens when sound waves are not properly transmitted through the outer ear canal to the eardrum and middle ear bones. Bilateral hearing loss can result in difficulty understanding speech, localizing sounds, and may impact communication and quality of life. The diagnosis and management of bilateral hearing loss typically involve a comprehensive audiological evaluation and medical assessment to determine the underlying cause and appropriate treatment options.

Vestibular function tests are a series of diagnostic assessments used to determine the functionality and health of the vestibular system, which is responsible for maintaining balance and spatial orientation. These tests typically include:

1. **Caloric Testing:** This test evaluates the response of each ear to stimulation with warm and cold water or air. The resulting responses are recorded and analyzed to assess the function of the horizontal semicircular canals and the vestibular-ocular reflex (VOR).

2. **Rotary Chair Testing:** This test measures how well the vestibular system adapts to different speeds of rotation. The patient sits in a chair that moves in a controlled, consistent manner while their eye movements are recorded.

3. **Videonystagmography (VNG):** This test uses video goggles to record eye movements in response to various stimuli, such as changes in head position, temperature, and visual environment.

4. **Electronystagmography (ENG):** Similar to VNG, this test records eye movements but uses electrodes placed near the eyes instead of video goggles.

5. **Dix-Hallpike Test:** This is a clinical maneuver used to diagnose benign paroxysmal positional vertigo (BPPV). It involves rapidly moving the patient's head from an upright position to a position where their head is hanging off the end of the examination table.

6. **Head Shaking Test:** This test involves shaking the head back and forth for 15-20 seconds and then observing the patient's eye movements for nystagmus (involuntary eye movement).

These tests help diagnose various vestibular disorders, including benign paroxysmal positional vertigo, labyrinthitis, vestibular neuritis, Meniere's disease, and other balance disorders.

Sound spectrography, also known as voice spectrography, is a diagnostic procedure in which a person's speech sounds are analyzed and displayed as a visual pattern called a spectrogram. This test is used to evaluate voice disorders, speech disorders, and hearing problems. It can help identify patterns of sound production and reveal any abnormalities in the vocal tract or hearing mechanism.

During the test, a person is asked to produce specific sounds or sentences, which are then recorded and analyzed by a computer program. The program breaks down the sound waves into their individual frequencies and amplitudes, and displays them as a series of horizontal lines on a graph. The resulting spectrogram shows how the frequencies and amplitudes change over time, providing valuable information about the person's speech patterns and any underlying problems.

Sound spectrography is a useful tool for diagnosing and treating voice and speech disorders, as well as for researching the acoustic properties of human speech. It can also be used to evaluate hearing aids and other assistive listening devices, and to assess the effectiveness of various treatments for hearing loss and other auditory disorders.

Muscle tonus, also known as muscle tone, refers to the continuous and passive partial contraction of the muscles, which helps to maintain posture and stability. It is the steady state of slight tension that is present in resting muscles, allowing them to quickly respond to stimuli and move. This natural state of mild contraction is maintained by the involuntary activity of the nervous system and can be affected by factors such as injury, disease, or exercise.

It's important to note that muscle tone should not be confused with muscle "tone" in the context of physical appearance or body sculpting, which refers to the amount of muscle definition and leanness seen in an individual's physique.

The "tectum mesencephali" is a term used in anatomy to refer to the roof or dorsal portion of the midbrain, which is a part of the brainstem. It plays a crucial role in visual and auditory processing, as well as motor coordination. The tectum mesencephali contains several important structures, including the superior colliculi and the inferior colliculi, which are involved in the reflexive responses to visual and auditory stimuli, respectively. Additionally, the tectum mesencephali is connected to various other regions of the brain, allowing for the integration of sensory information and the coordination of motor responses.

The cochlea is a part of the inner ear that is responsible for hearing. It is a spiral-shaped structure that looks like a snail shell and is filled with fluid. The cochlea contains hair cells, which are specialized sensory cells that convert sound vibrations into electrical signals that are sent to the brain.

The cochlea has three main parts: the vestibular canal, the tympanic canal, and the cochlear duct. Sound waves enter the inner ear and cause the fluid in the cochlea to move, which in turn causes the hair cells to bend. This bending motion stimulates the hair cells to generate electrical signals that are sent to the brain via the auditory nerve.

The brain then interprets these signals as sound, allowing us to hear and understand speech, music, and other sounds in our environment. Damage to the hair cells or other structures in the cochlea can lead to hearing loss or deafness.

Electronystagmography (ENG) is a medical test used to assess the function of the vestibular system, which is responsible for maintaining balance and eye movements. This test measures involuntary eye movements, called nystagmus, which can be indicative of various conditions affecting the inner ear or brainstem.

During the ENG test, electrodes are placed around the eyes to record eye movements while the patient undergoes a series of stimuli, such as changes in head position, visual stimuli, and caloric irrigations (where warm or cool water is introduced into the ear canal to stimulate the inner ear). The recorded data is then analyzed to evaluate the function of the vestibular system and identify any abnormalities.

ENG testing can help diagnose conditions such as vestibular neuritis, labyrinthitis, benign paroxysmal positional vertigo (BPPV), Meniere's disease, and other balance disorders. It is also used to assess the effectiveness of various treatments for these conditions.

The middle ear is the middle of the three parts of the ear, located between the outer ear and inner ear. It contains three small bones called ossicles (the malleus, incus, and stapes) that transmit and amplify sound vibrations from the eardrum to the inner ear. The middle ear also contains the Eustachian tube, which helps regulate air pressure in the middle ear and protects against infection by allowing fluid to drain from the middle ear into the back of the throat.

In medical terms, the term "voice" refers to the sound produced by vibration of the vocal cords caused by air passing out from the lungs during speech, singing, or breathing. It is a complex process that involves coordination between respiratory, phonatory, and articulatory systems. Any damage or disorder in these systems can affect the quality, pitch, loudness, and flexibility of the voice.

The medical field dealing with voice disorders is called Phoniatrics or Voice Medicine. Voice disorders can present as hoarseness, breathiness, roughness, strain, weakness, or a complete loss of voice, which can significantly impact communication, social interaction, and quality of life.

The olivary nucleus is a structure located in the medulla oblongata, which is a part of the brainstem. It consists of two main parts: the inferior olive and the accessory olive. The inferior olive is further divided into several subnuclei.

The olivary nucleus plays an important role in the coordination of movements, particularly in the regulation of fine motor control and rhythmic movements. It receives input from various sources, including the cerebellum, spinal cord, and other brainstem nuclei, and sends output to the cerebellum via the climbing fibers.

Damage to the olivary nucleus can result in a variety of neurological symptoms, including ataxia (loss of coordination), tremors, and dysarthria (speech difficulties). Certain neurodegenerative disorders, such as multiple system atrophy, may also affect the olivary nucleus and contribute to its degeneration.

The ear is the sensory organ responsible for hearing and maintaining balance. It can be divided into three parts: the outer ear, middle ear, and inner ear. The outer ear consists of the pinna (the visible part of the ear) and the external auditory canal, which directs sound waves toward the eardrum. The middle ear contains three small bones called ossicles that transmit sound vibrations from the eardrum to the inner ear. The inner ear contains the cochlea, a spiral-shaped organ responsible for converting sound vibrations into electrical signals that are sent to the brain, and the vestibular system, which is responsible for maintaining balance.

I'm sorry for any confusion, but "Textile Industry" and "medical definition" are not related. The textile industry is the overall system of designing, producing, and distributing clothing and their raw materials, which include fiber, yarn, and cloth. It involves several processes such as spinning, weaving, knitting, dyeing, and finishing.

If you're looking for a medical term or definition, please provide me with the term so I can assist you better.

The inferior colliculi are a pair of rounded eminences located in the midbrain, specifically in the tectum of the mesencephalon. They play a crucial role in auditory processing and integration. The inferior colliculi receive inputs from various sources, including the cochlear nuclei, superior olivary complex, and cortical areas. They then send their outputs to the medial geniculate body, which is a part of the thalamus that relays auditory information to the auditory cortex.

In summary, the inferior colliculi are important structures in the auditory pathway that help process and integrate auditory information before it reaches the cerebral cortex for further analysis and perception.

Perceptual masking, also known as sensory masking or just masking, is a concept in sensory perception that refers to the interference in the ability to detect or recognize a stimulus (the target) due to the presence of another stimulus (the mask). This phenomenon can occur across different senses, including audition and vision.

In the context of hearing, perceptual masking occurs when one sound (the masker) makes it difficult to hear another sound (the target) because the two sounds are presented simultaneously or in close proximity to each other. The masker can make the target sound less detectable, harder to identify, or even completely inaudible.

There are different types of perceptual masking, including:

1. Simultaneous Masking: When the masker and target sounds occur at the same time.
2. Temporal Masking: When the masker sound precedes or follows the target sound by a short period. This type of masking can be further divided into forward masking (when the masker comes before the target) and backward masking (when the masker comes after the target).
3. Informational Masking: A more complex form of masking that occurs when the listener's cognitive processes, such as attention or memory, are affected by the presence of the masker sound. This type of masking can make it difficult to understand speech in noisy environments, even if the signal-to-noise ratio is favorable.

Perceptual masking has important implications for understanding and addressing hearing difficulties, particularly in situations with background noise or multiple sounds occurring simultaneously.

The basilar membrane is a key structure within the inner ear that plays a crucial role in hearing. It is a narrow, flexible strip of tissue located inside the cochlea, which is the spiral-shaped organ responsible for converting sound waves into neural signals that can be interpreted by the brain.

The basilar membrane runs along the length of the cochlea's duct and is attached to the rigid bony structures at both ends. It varies in width and stiffness along its length, with the widest and most flexible portion located near the entrance of the cochlea and the narrowest and stiffest portion located near the apex.

When sound waves enter the inner ear, they cause vibrations in the fluid-filled cochlear duct. These vibrations are transmitted to the basilar membrane, causing it to flex up and down. The specific pattern of flexion along the length of the basilar membrane depends on the frequency of the sound wave. Higher frequency sounds cause maximum flexion near the base of the cochlea, while lower frequency sounds cause maximum flexion near the apex.

As the basilar membrane flexes, it causes the attached hair cells to bend. This bending stimulates the hair cells to release neurotransmitters, which then activate the auditory nerve fibers. The pattern of neural activity in the auditory nerve encodes the frequency and amplitude of the sound wave, allowing the brain to interpret the sound.

Overall, the basilar membrane is a critical component of the hearing process, enabling us to detect and discriminate different sounds based on their frequency and amplitude.

Echolocation is a biological sonar system used by certain animals to navigate and locate objects in their environment. It is most commonly associated with bats and dolphins, although some other species such as shrews and cave-dwelling birds also use this method.

In echolocation, the animal emits a series of sounds, often in the form of clicks or chirps, which travel through the air or water until they hit an object. The sound then reflects off the object and returns to the animal, providing information about the distance, size, shape, and location of the object.

By analyzing the time delay between the emission of the sound and the reception of the echo, as well as the frequency changes in the echo caused by the movement of the object or the animal itself, the animal can create a mental image of its surroundings and navigate through it with great precision.

Chiroptera is the scientific order that includes all bat species. Bats are the only mammals capable of sustained flight, and they are distributed worldwide with the exception of extremely cold environments. They vary greatly in size, from the bumblebee bat, which weighs less than a penny, to the giant golden-crowned flying fox, which has a wingspan of up to 6 feet.

Bats play a crucial role in many ecosystems as pollinators and seed dispersers for plants, and they also help control insect populations. Some bat species are nocturnal and use echolocation to navigate and find food, while others are diurnal and rely on their vision. Their diet mainly consists of insects, fruits, nectar, and pollen, although a few species feed on blood or small vertebrates.

Unfortunately, many bat populations face significant threats due to habitat loss, disease, and wind turbine collisions, leading to declining numbers and increased conservation efforts.

The semicircular canals are part of the vestibular system in the inner ear that contributes to the sense of balance and spatial orientation. They are composed of three fluid-filled tubes, each located in a different plane (anterior, posterior, and horizontal) and arranged at approximately right angles to each other. The semicircular canals detect rotational movements of the head, enabling us to maintain our equilibrium during movement.

When the head moves, the fluid within the semicircular canals moves in response to that motion. At the end of each canal is a structure called the ampulla, which contains hair cells with hair-like projections (stereocilia) embedded in a gelatinous substance. As the fluid moves, it bends the stereocilia, stimulating the hair cells and sending signals to the brain via the vestibular nerve. The brain then interprets these signals to determine the direction and speed of head movement, allowing us to maintain our balance and orientation in space.

An acoustic neuroma, also known as vestibular schwannoma, is not actually a neuroma but rather a benign (noncancerous) tumor that develops on the vestibular nerve. This nerve is one of the two nerves that transmit sound and balance information from the inner ear to the brain. The tumor arises from an overproduction of Schwann cells, which normally provide a protective covering for the nerve fibers. As the tumor grows, it can press against the hearing and balance nerves, causing symptoms such as hearing loss, ringing in the ear (tinnitus), unsteadiness, and disequilibrium. In some cases, acoustic neuromas can become quite large and cause additional symptoms by pressing on nearby cranial nerves. Treatment options include observation, radiation therapy, or surgical removal of the tumor.

In psychology, Signal Detection Theory (SDT) is a framework used to understand the ability to detect the presence or absence of a signal (such as a stimulus or event) in the presence of noise or uncertainty. It is often applied in sensory perception research, such as hearing and vision, where it helps to separate an observer's sensitivity to the signal from their response bias.

SDT involves measuring both hits (correct detections of the signal) and false alarms (incorrect detections when no signal is present). These measures are then used to calculate measures such as d', which reflects the observer's ability to discriminate between the signal and noise, and criterion (C), which reflects the observer's response bias.

SDT has been applied in various fields of psychology, including cognitive psychology, clinical psychology, and neuroscience, to study decision-making, memory, attention, and perception. It is a valuable tool for understanding how people make decisions under uncertainty and how they trade off accuracy and caution in their responses.

The vestibulocochlear nerve, also known as the 8th cranial nerve, is responsible for transmitting sound and balance information from the inner ear to the brain. Vestibulocochlear nerve diseases refer to conditions that affect this nerve and can result in hearing loss, vertigo, and balance problems.

These diseases can be caused by various factors, including genetics, infection, trauma, tumors, or degeneration. Some examples of vestibulocochlear nerve diseases include:

1. Vestibular neuritis: an inner ear infection that causes severe vertigo, nausea, and balance problems.
2. Labyrinthitis: an inner ear infection that affects both the vestibular and cochlear nerves, causing vertigo, hearing loss, and tinnitus.
3. Acoustic neuroma: a benign tumor that grows on the vestibulocochlear nerve, causing hearing loss, tinnitus, and balance problems.
4. Meniere's disease: a inner ear disorder that causes vertigo, hearing loss, tinnitus, and a feeling of fullness in the ear.
5. Ototoxicity: damage to the inner ear caused by certain medications or chemicals that can result in hearing loss and balance problems.
6. Vestibular migraine: a type of migraine that is associated with vertigo, dizziness, and balance problems.

Treatment for vestibulocochlear nerve diseases varies depending on the specific condition and its severity. It may include medication, physical therapy, surgery, or a combination of these approaches.

Sound localization is the ability of the auditory system to identify the location or origin of a sound source in the environment. It is a crucial aspect of hearing and enables us to navigate and interact with our surroundings effectively. The process involves several cues, including time differences in the arrival of sound to each ear (interaural time difference), differences in sound level at each ear (interaural level difference), and spectral information derived from the filtering effects of the head and external ears on incoming sounds. These cues are analyzed by the brain to determine the direction and distance of the sound source, allowing for accurate localization.

Reaction time, in the context of medicine and physiology, refers to the time period between the presentation of a stimulus and the subsequent initiation of a response. This complex process involves the central nervous system, particularly the brain, which perceives the stimulus, processes it, and then sends signals to the appropriate muscles or glands to react.

There are different types of reaction times, including simple reaction time (responding to a single, expected stimulus) and choice reaction time (choosing an appropriate response from multiple possibilities). These measures can be used in clinical settings to assess various aspects of neurological function, such as cognitive processing speed, motor control, and alertness.

However, it is important to note that reaction times can be influenced by several factors, including age, fatigue, attention, and the use of certain medications or substances.

Occupational exposure refers to the contact of an individual with potentially harmful chemical, physical, or biological agents as a result of their job or occupation. This can include exposure to hazardous substances such as chemicals, heavy metals, or dusts; physical agents such as noise, radiation, or ergonomic stressors; and biological agents such as viruses, bacteria, or fungi.

Occupational exposure can occur through various routes, including inhalation, skin contact, ingestion, or injection. Prolonged or repeated exposure to these hazards can increase the risk of developing acute or chronic health conditions, such as respiratory diseases, skin disorders, neurological damage, or cancer.

Employers have a legal and ethical responsibility to minimize occupational exposures through the implementation of appropriate control measures, including engineering controls, administrative controls, personal protective equipment, and training programs. Regular monitoring and surveillance of workers' health can also help identify and prevent potential health hazards in the workplace.

Magnetoencephalography (MEG) is a non-invasive functional neuroimaging technique used to measure the magnetic fields produced by electrical activity in the brain. These magnetic fields are detected by very sensitive devices called superconducting quantum interference devices (SQUIDs), which are cooled to extremely low temperatures to enhance their sensitivity. MEG provides direct and real-time measurement of neural electrical activity with high temporal resolution, typically on the order of milliseconds, allowing for the investigation of brain function during various cognitive, sensory, and motor tasks. It is often used in conjunction with other neuroimaging techniques, such as fMRI, to provide complementary information about brain structure and function.

Presbycusis is an age-related hearing loss, typically characterized by the progressive loss of sensitivity to high-frequency sounds. It's a result of natural aging of the auditory system and is often seen as a type of sensorineural hearing loss. The term comes from the Greek words "presbus" meaning old man and "akousis" meaning hearing.

This condition usually develops slowly over many years and can affect both ears equally. Presbycusis can make understanding speech, especially in noisy environments, quite challenging. It's a common condition, and its prevalence increases with age. While it's not reversible, various assistive devices like hearing aids can help manage the symptoms.

A cross-sectional study is a type of observational research design that examines the relationship between variables at one point in time. It provides a snapshot or a "cross-section" of the population at a particular moment, allowing researchers to estimate the prevalence of a disease or condition and identify potential risk factors or associations.

In a cross-sectional study, data is collected from a sample of participants at a single time point, and the variables of interest are measured simultaneously. This design can be used to investigate the association between exposure and outcome, but it cannot establish causality because it does not follow changes over time.

Cross-sectional studies can be conducted using various data collection methods, such as surveys, interviews, or medical examinations. They are often used in epidemiology to estimate the prevalence of a disease or condition in a population and to identify potential risk factors that may contribute to its development. However, because cross-sectional studies only provide a snapshot of the population at one point in time, they cannot account for changes over time or determine whether exposure preceded the outcome.

Therefore, while cross-sectional studies can be useful for generating hypotheses and identifying potential associations between variables, further research using other study designs, such as cohort or case-control studies, is necessary to establish causality and confirm any findings.

Occupational diseases are health conditions or illnesses that occur as a result of exposure to hazards in the workplace. These hazards can include physical, chemical, and biological agents, as well as ergonomic factors and work-related psychosocial stressors. Examples of occupational diseases include respiratory illnesses caused by inhaling dust or fumes, hearing loss due to excessive noise exposure, and musculoskeletal disorders caused by repetitive movements or poor ergonomics. The development of an occupational disease is typically related to the nature of the work being performed and the conditions in which it is carried out. It's important to note that these diseases can be prevented or minimized through proper risk assessment, implementation of control measures, and adherence to safety regulations.

The cochlear nucleus is the first relay station in the auditory pathway within the central nervous system. It is a structure located in the lower pons region of the brainstem and receives sensory information from the cochlea, which is the spiral-shaped organ of hearing in the inner ear.

The cochlear nucleus consists of several subdivisions, each with distinct neuronal populations that process different aspects of auditory information. These subdivisions include the anteroventral cochlear nucleus (AVCN), posteroventral cochlear nucleus (PVCN), dorsal cochlear nucleus (DCN), and the granule cell domain.

Neurons in these subdivisions perform various computations on the incoming auditory signals, such as frequency analysis, intensity coding, and sound localization. The output of the cochlear nucleus is then sent via several pathways to higher brain regions for further processing and interpretation, including the inferior colliculus, medial geniculate body, and eventually the auditory cortex.

Damage or dysfunction in the cochlear nucleus can lead to hearing impairments and other auditory processing disorders.

In the field of medicine, "time factors" refer to the duration of symptoms or time elapsed since the onset of a medical condition, which can have significant implications for diagnosis and treatment. Understanding time factors is crucial in determining the progression of a disease, evaluating the effectiveness of treatments, and making critical decisions regarding patient care.

For example, in stroke management, "time is brain," meaning that rapid intervention within a specific time frame (usually within 4.5 hours) is essential to administering tissue plasminogen activator (tPA), a clot-busting drug that can minimize brain damage and improve patient outcomes. Similarly, in trauma care, the "golden hour" concept emphasizes the importance of providing definitive care within the first 60 minutes after injury to increase survival rates and reduce morbidity.

Time factors also play a role in monitoring the progression of chronic conditions like diabetes or heart disease, where regular follow-ups and assessments help determine appropriate treatment adjustments and prevent complications. In infectious diseases, time factors are crucial for initiating antibiotic therapy and identifying potential outbreaks to control their spread.

Overall, "time factors" encompass the significance of recognizing and acting promptly in various medical scenarios to optimize patient outcomes and provide effective care.

Cochlear implants are medical devices that are surgically implanted in the inner ear to help restore hearing in individuals with severe to profound hearing loss. These devices bypass the damaged hair cells in the inner ear and directly stimulate the auditory nerve, allowing the brain to interpret sound signals. Cochlear implants consist of two main components: an external processor that picks up and analyzes sounds from the environment, and an internal receiver/stimulator that receives the processed information and sends electrical impulses to the auditory nerve. The resulting patterns of electrical activity are then perceived as sound by the brain. Cochlear implants can significantly improve communication abilities, language development, and overall quality of life for individuals with profound hearing loss.

Animal vocalization refers to the production of sound by animals through the use of the vocal organs, such as the larynx in mammals or the syrinx in birds. These sounds can serve various purposes, including communication, expressing emotions, attracting mates, warning others of danger, and establishing territory. The complexity and diversity of animal vocalizations are vast, with some species capable of producing intricate songs or using specific calls to convey different messages. In a broader sense, animal vocalizations can also include sounds produced through other means, such as stridulation in insects.

Time perception, in the context of medicine and neuroscience, refers to the subjective experience and cognitive representation of time intervals. It is a complex process that involves the integration of various sensory, attentional, and emotional factors.

Disorders or injuries to certain brain regions, such as the basal ganglia, thalamus, or cerebellum, can affect time perception, leading to symptoms such as time distortion, where time may seem to pass more slowly or quickly than usual. Additionally, some neurological and psychiatric conditions, such as Parkinson's disease, attention deficit hyperactivity disorder (ADHD), and depression, have been associated with altered time perception.

Assessment of time perception is often used in neuropsychological evaluations to help diagnose and monitor the progression of certain neurological disorders. Various tests exist to measure time perception, such as the temporal order judgment task, where individuals are asked to judge which of two stimuli occurred first, or the duration estimation task, where individuals are asked to estimate the duration of a given stimulus.

Sudden hearing loss, also known as sudden sensorineural hearing loss (SSHL), is a type of hearing impairment that occurs suddenly or over a period of up to 3 days. It is typically defined as a hearing reduction of at least 30 decibels in three connected frequencies. The cause of SSHL is often unknown, but it can be associated with viral infections, trauma, neurological disorders, and exposure to certain ototoxic medications. In some cases, the hearing loss may resolve on its own, but prompt medical evaluation and treatment are recommended to improve the chances of recovery. Treatment options include corticosteroids, antiviral medication, and hyperbaric oxygen therapy.

A case-control study is an observational research design used to identify risk factors or causes of a disease or health outcome. In this type of study, individuals with the disease or condition (cases) are compared with similar individuals who do not have the disease or condition (controls). The exposure history or other characteristics of interest are then compared between the two groups to determine if there is an association between the exposure and the disease.

Case-control studies are often used when it is not feasible or ethical to conduct a randomized controlled trial, as they can provide valuable insights into potential causes of diseases or health outcomes in a relatively short period of time and at a lower cost than other study designs. However, because case-control studies rely on retrospective data collection, they are subject to biases such as recall bias and selection bias, which can affect the validity of the results. Therefore, it is important to carefully design and conduct case-control studies to minimize these potential sources of bias.

Prospective studies, also known as longitudinal studies, are a type of cohort study in which data is collected forward in time, following a group of individuals who share a common characteristic or exposure over a period of time. The researchers clearly define the study population and exposure of interest at the beginning of the study and follow up with the participants to determine the outcomes that develop over time. This type of study design allows for the investigation of causal relationships between exposures and outcomes, as well as the identification of risk factors and the estimation of disease incidence rates. Prospective studies are particularly useful in epidemiology and medical research when studying diseases with long latency periods or rare outcomes.

The tympanic membrane, also known as the eardrum, is a thin, cone-shaped membrane that separates the external auditory canal from the middle ear. It serves to transmit sound vibrations from the air to the inner ear, where they are converted into electrical signals that can be interpreted by the brain as sound. The tympanic membrane is composed of three layers: an outer layer of skin, a middle layer of connective tissue, and an inner layer of mucous membrane. It is held in place by several small bones and muscles and is highly sensitive to changes in pressure.

Gerbillinae is a subfamily of rodents that includes gerbils, jirds, and sand rats. These small mammals are primarily found in arid regions of Africa and Asia. They are characterized by their long hind legs, which they use for hopping, and their long, thin tails. Some species have adapted to desert environments by developing specialized kidneys that allow them to survive on minimal water intake.

Implanted electrodes are medical devices that are surgically placed inside the body to interface directly with nerves, neurons, or other electrically excitable tissue for various therapeutic purposes. These electrodes can be used to stimulate or record electrical activity from specific areas of the body, depending on their design and application.

There are several types of implanted electrodes, including:

1. Deep Brain Stimulation (DBS) electrodes: These are placed deep within the brain to treat movement disorders such as Parkinson's disease, essential tremor, and dystonia. DBS electrodes deliver electrical impulses that modulate abnormal neural activity in targeted brain regions.
2. Spinal Cord Stimulation (SCS) electrodes: These are implanted along the spinal cord to treat chronic pain syndromes. SCS electrodes emit low-level electrical pulses that interfere with pain signals traveling to the brain, providing relief for patients.
3. Cochlear Implant electrodes: These are surgically inserted into the cochlea of the inner ear to restore hearing in individuals with severe to profound hearing loss. The electrodes stimulate the auditory nerve directly, bypassing damaged hair cells within the cochlea.
4. Retinal Implant electrodes: These are implanted in the retina to treat certain forms of blindness caused by degenerative eye diseases like retinitis pigmentosa. The electrodes convert visual information from a camera into electrical signals, which stimulate remaining retinal cells and transmit the information to the brain via the optic nerve.
5. Sacral Nerve Stimulation (SNS) electrodes: These are placed near the sacral nerves in the lower back to treat urinary or fecal incontinence and overactive bladder syndrome. SNS electrodes deliver electrical impulses that regulate the function of the affected muscles and nerves.
6. Vagus Nerve Stimulation (VNS) electrodes: These are wrapped around the vagus nerve in the neck to treat epilepsy and depression. VNS electrodes provide intermittent electrical stimulation to the vagus nerve, which has connections to various regions of the brain involved in these conditions.

Overall, implanted electrodes serve as a crucial component in many neuromodulation therapies, offering an effective treatment option for numerous neurological and sensory disorders.

Functional laterality, in a medical context, refers to the preferential use or performance of one side of the body over the other for specific functions. This is often demonstrated in hand dominance, where an individual may be right-handed or left-handed, meaning they primarily use their right or left hand for tasks such as writing, eating, or throwing.

However, functional laterality can also apply to other bodily functions and structures, including the eyes (ocular dominance), ears (auditory dominance), or legs. It's important to note that functional laterality is not a strict binary concept; some individuals may exhibit mixed dominance or no strong preference for one side over the other.

In clinical settings, assessing functional laterality can be useful in diagnosing and treating various neurological conditions, such as stroke or traumatic brain injury, where understanding any resulting lateralized impairments can inform rehabilitation strategies.

Neurons, also known as nerve cells or neurocytes, are specialized cells that constitute the basic unit of the nervous system. They are responsible for receiving, processing, and transmitting information and signals within the body. Neurons have three main parts: the dendrites, the cell body (soma), and the axon. The dendrites receive signals from other neurons or sensory receptors, while the axon transmits these signals to other neurons, muscles, or glands. The junction between two neurons is called a synapse, where neurotransmitters are released to transmit the signal across the gap (synaptic cleft) to the next neuron. Neurons vary in size, shape, and structure depending on their function and location within the nervous system.

I must clarify that the term "Guinea Pigs" is not typically used in medical definitions. However, in colloquial or informal language, it may refer to people who are used as the first to try out a new medical treatment or drug. This is known as being a "test subject" or "in a clinical trial."

In the field of scientific research, particularly in studies involving animals, guinea pigs are small rodents that are often used as experimental subjects due to their size, cost-effectiveness, and ease of handling. They are not actually pigs from Guinea, despite their name's origins being unclear. However, they do not exactly fit the description of being used in human medical experiments.

Cochlear implantation is a surgical procedure in which a device called a cochlear implant is inserted into the inner ear (cochlea) of a person with severe to profound hearing loss. The implant consists of an external component, which includes a microphone, processor, and transmitter, and an internal component, which includes a receiver and electrode array.

The microphone picks up sounds from the environment and sends them to the processor, which analyzes and converts the sounds into electrical signals. These signals are then transmitted to the receiver, which stimulates the electrode array in the cochlea. The electrodes directly stimulate the auditory nerve fibers, bypassing the damaged hair cells in the inner ear that are responsible for normal hearing.

The brain interprets these electrical signals as sound, allowing the person to perceive and understand speech and other sounds. Cochlear implantation is typically recommended for people who do not benefit from traditional hearing aids and can significantly improve communication, quality of life, and social integration for those with severe to profound hearing loss.

In the context of medicine and physiology, vibration refers to the mechanical oscillation of a physical body or substance with a periodic back-and-forth motion around an equilibrium point. This motion can be produced by external forces or internal processes within the body.

Vibration is often measured in terms of frequency (the number of cycles per second) and amplitude (the maximum displacement from the equilibrium position). In clinical settings, vibration perception tests are used to assess peripheral nerve function and diagnose conditions such as neuropathy.

Prolonged exposure to whole-body vibration or hand-transmitted vibration in certain occupational settings can also have adverse health effects, including hearing loss, musculoskeletal disorders, and vascular damage.

Callithrix is a genus of New World monkeys, also known as marmosets. They are small, active primates found in the forests of South and Central America. The term "Callithrix" itself is derived from the Greek words "kallis" meaning beautiful and "thrix" meaning hair, referring to their thick, vibrantly colored fur.

Marmosets in the genus Callithrix are characterized by their slender bodies, long, bushy tails, and specialized dental structures that allow them to gouge tree bark to extract sap and exudates, which form a significant part of their diet. They also consume fruits, insects, and small vertebrates.

Some well-known species in this genus include the common marmoset (Callithrix jacchus), the white-headed marmoset (Callithrix geoffroyi), and the buffy-tufted-ear marmoset (Callithrix aurita). Marmosets are popular subjects of research due to their small size, short gestation period, and ease of breeding in captivity.

Deafness is a hearing loss that is so severe that it results in significant difficulty in understanding or comprehending speech, even when using hearing aids. It can be congenital (present at birth) or acquired later in life due to various causes such as disease, injury, infection, exposure to loud noises, or aging. Deafness can range from mild to profound and may affect one ear (unilateral) or both ears (bilateral). In some cases, deafness may be accompanied by tinnitus, which is the perception of ringing or other sounds in the ears.

Deaf individuals often use American Sign Language (ASL) or other forms of sign language to communicate. Some people with less severe hearing loss may benefit from hearing aids, cochlear implants, or other assistive listening devices. Deafness can have significant social, educational, and vocational implications, and early intervention and appropriate support services are critical for optimal development and outcomes.

Brain mapping is a broad term that refers to the techniques used to understand the structure and function of the brain. It involves creating maps of the various cognitive, emotional, and behavioral processes in the brain by correlating these processes with physical locations or activities within the nervous system. Brain mapping can be accomplished through a variety of methods, including functional magnetic resonance imaging (fMRI), positron emission tomography (PET) scans, electroencephalography (EEG), and others. These techniques allow researchers to observe which areas of the brain are active during different tasks or thoughts, helping to shed light on how the brain processes information and contributes to our experiences and behaviors. Brain mapping is an important area of research in neuroscience, with potential applications in the diagnosis and treatment of neurological and psychiatric disorders.

Echo-Planar Imaging (EPI) is a type of magnetic resonance imaging (MRI) technique that uses rapidly alternating magnetic field gradients and radiofrequency pulses to acquire multiple images in a very short period of time. This technique allows for the rapid acquisition of images, making it useful for functional MRI (fMRI) studies, diffusion-weighted imaging, and other applications where motion artifacts can be a problem.

In EPI, a single excitation pulse is followed by a series of gradient echoes that are acquired in a rapid succession, with each echo providing information about a different slice or plane of the object being imaged. The resulting images can then be combined to create a 3D representation of the object.

One of the key advantages of EPI is its speed, as it can acquire an entire brain volume in as little as 50 milliseconds. This makes it possible to capture rapid changes in the brain, such as those that occur during cognitive tasks or in response to neural activation. However, the technique can be susceptible to distortions and artifacts, particularly at higher field strengths, which can affect image quality and accuracy.

Auditory hair cells are specialized sensory receptor cells located in the inner ear, more specifically in the organ of Corti within the cochlea. They play a crucial role in hearing by converting sound vibrations into electrical signals that can be interpreted by the brain.

These hair cells have hair-like projections called stereocilia on their apical surface, which are embedded in a gelatinous matrix. When sound waves reach the inner ear, they cause the fluid within the cochlea to move, which in turn causes the stereocilia to bend. This bending motion opens ion channels at the tips of the stereocilia, allowing positively charged ions (such as potassium) to flow into the hair cells and trigger a receptor potential.

The receptor potential then leads to the release of neurotransmitters at the base of the hair cells, which activate afferent nerve fibers that synapse with these cells. The electrical signals generated by this process are transmitted to the brain via the auditory nerve, where they are interpreted as sound.

There are two types of auditory hair cells: inner hair cells and outer hair cells. Inner hair cells are the primary sensory receptors responsible for transmitting information about sound to the brain. They make direct contact with afferent nerve fibers and are more sensitive to mechanical stimulation than outer hair cells.

Outer hair cells, on the other hand, are involved in amplifying and fine-tuning the mechanical response of the inner ear to sound. They have a unique ability to contract and relax in response to electrical signals, which allows them to adjust the stiffness of their stereocilia and enhance the sensitivity of the cochlea to different frequencies.

Damage or loss of auditory hair cells can lead to hearing impairment or deafness, as these cells cannot regenerate spontaneously in mammals. Therefore, understanding the structure and function of hair cells is essential for developing therapies aimed at treating hearing disorders.

"Cat" is a common name that refers to various species of small carnivorous mammals that belong to the family Felidae. The domestic cat, also known as Felis catus or Felis silvestris catus, is a popular pet and companion animal. It is a subspecies of the wildcat, which is found in Europe, Africa, and Asia.

Domestic cats are often kept as pets because of their companionship, playful behavior, and ability to hunt vermin. They are also valued for their ability to provide emotional support and therapy to people. Cats are obligate carnivores, which means that they require a diet that consists mainly of meat to meet their nutritional needs.

Cats are known for their agility, sharp senses, and predatory instincts. They have retractable claws, which they use for hunting and self-defense. Cats also have a keen sense of smell, hearing, and vision, which allow them to detect prey and navigate their environment.

In medical terms, cats can be hosts to various parasites and diseases that can affect humans and other animals. Some common feline diseases include rabies, feline leukemia virus (FeLV), feline immunodeficiency virus (FIV), and toxoplasmosis. It is important for cat owners to keep their pets healthy and up-to-date on vaccinations and preventative treatments to protect both the cats and their human companions.

An action potential is a brief electrical signal that travels along the membrane of a nerve cell (neuron) or muscle cell. It is initiated by a rapid, localized change in the permeability of the cell membrane to specific ions, such as sodium and potassium, resulting in a rapid influx of sodium ions and a subsequent efflux of potassium ions. This ion movement causes a brief reversal of the electrical potential across the membrane, which is known as depolarization. The action potential then propagates along the cell membrane as a wave, allowing the electrical signal to be transmitted over long distances within the body. Action potentials play a crucial role in the communication and functioning of the nervous system and muscle tissue.

Reference values, also known as reference ranges or reference intervals, are the set of values that are considered normal or typical for a particular population or group of people. These values are often used in laboratory tests to help interpret test results and determine whether a patient's value falls within the expected range.

The process of establishing reference values typically involves measuring a particular biomarker or parameter in a large, healthy population and then calculating the mean and standard deviation of the measurements. Based on these statistics, a range is established that includes a certain percentage of the population (often 95%) and excludes extreme outliers.

It's important to note that reference values can vary depending on factors such as age, sex, race, and other demographic characteristics. Therefore, it's essential to use reference values that are specific to the relevant population when interpreting laboratory test results. Additionally, reference values may change over time due to advances in measurement technology or changes in the population being studied.

... is described as the gold standard for assessment of a hearing loss but how accurate pure-tone audiometry ... published Guidelines for Manual Pure-Tone Threshold Audiometry in 2005. There are cases where conventional pure-tone audiometry ... Pure Tone Audiometry: What is Pure Tone Average (PTA) Test?. Springerlink.com. Audition Cochlea Promenade oreille ear organ ... Pure-tone audiometry provides ear specific thresholds, and uses frequency specific pure tones to give place specific responses ...
"A comparison of pure tone auditory thresholds in human infants and adults". Infant Behavior and Development. 6 (1): 3-17. doi: ... Visual reinforcement audiometry (VRA) is a key behavioural test for evaluating hearing in young children. First introduced by ... which is when audiologists introduce Conditioned Play Audiometry. Conditioned orientation reflex (COR) is a variant of VRA ...
Pure Tone Audiometry , Silber Records (2003) Or you could just go through your whole life… , Darla Records (2002) Morning One ...
In conjunction with pure-tone audiometry, it can aid in determining the degree and type of hearing loss. Speech audiometry also ... Immittance audiometry is superior to pure tone audiometry in detecting middle ear pathology. Tympanometry Acoustic reflex ... Audiometry of children Conditioned play audiometry Behavioral observation audiometry Visual reinforcement audiometry Objective ... A pure tone audiometry hearing test is the gold standard for evaluation of hearing loss or disability.[medical citation needed ...
SSHL is diagnosed via pure tone audiometry. If the test shows a loss of at least 30 dB in three adjacent frequencies, the ... The most common type of hearing test is pure tone audiometry (PTA). It charts the thresholds of hearing sensitivity at a ... There is also high frequency pure tone audiometry which tests frequencies from 8000-20,000 Hz. PTA can be used to differentiate ... Identification of sensorineural hearing loss is usually made by performing a pure tone audiometry (an audiogram) in which bone ...
Other tests would include pure-tone and speech audiometry. AN patients can have a range of hearing thresholds with difficulty ...
Online pure-tone threshold audiometry (or screening) tests, electrophysiological measures, for example distortion-product OAEs ... Cox, Marco; de Vries, Bert (2021). "Bayesian Pure-Tone Audiometry Through Active Learning Under Informed Priors". Frontiers in ... Machine learning has been applied to audiometry to create flexible, efficient estimation tools that do not require excessive ... "Online Machine Learning Audiometry". Ear & Hearing. 40 (4): 918-926. doi:10.1097/AUD.0000000000000669. ISSN 0196-0202. PMC ...
Pure-tone audiometry tests provide accurate descriptions of a person's hearing. Since hearing perception encompasses both ... A common type of subjective hearing test requires the user to push a button if they can hear a tone that is played at a ... The tones are created from signals produced either in the headphones themselves or via Bluetooth from the mobile device. ... The user responds on the mobile application interface if they perceive tones. The device must communicate with the mobile app ...
Audiology Audiogram Audiometry Hearing test Pure tone audiometry IEC 60645-1. (November 19, 2001) "Audiometers. Pure-tone ... Bekesy audiometry typically yields lower thresholds and standard deviations than pure tone audiometry. Audiometer requirements ... An audiometer typically transmits recorded sounds such as pure tones or speech to the headphones of the test subject at varying ... The most common type of audiometer generates pure tones, or transmits parts of speech. Another kind of audiometer is the Bekesy ...
... carefully analyzes pure tone audiometry results aiming to identify early changes, and finally; continuously improving their ...
In pure tone audiometry, an audiometer is used to play a series of tones using headphones. The participants listen to the tones ... Some hearing tests include the whispered speech test, pure tone audiometry, the tuning fork test, speech reception and word ... When two simple tones are put together they create a complex tone. The simple tones of an instrument are called harmonics or ... The test will play with the volume controls and the participant is asked to signal when he or she can no longer hear the tone ...
"Conventional" pure tone audiometry (testing frequencies up to 8 kHz) is the basic measure of hearing status. For research ... pure tone audiometry in Meniere's disease Archived 2008-12-08 at the Wayback Machine from General Practice Notebook. Retrieved ... pure tone audiometry in otosclerosis Archived 2008-12-08 at the Wayback Machine from General Practice Notebook. Retrieved 2012 ... Hearing range Equal-loudness contour Minimum audibility curve Articulation index Pure tone audiometry Hearing (sense) Audiology ...
It was found that OAEs were more sensitive to identifying noise-induced cochlear damage than pure tone audiometry. In ... a composer who used this phenomenon in her music Pure tone audiometry The Hum Kemp, D. T. (1 January 1978). "Stimulated ... Stimulus-frequency OAEs (SFOAEs) are measured during the application of a pure-tone stimulus and are detected by the vectorial ... brief duration pure tone) stimulus. The evoked response from a click covers the frequency range up to around 4 kHz, while a ...
In clinical audiology, pure tones are used for pure-tone audiometry to characterize hearing thresholds at different frequencies ... In this situation, the instantaneous phase of the pure tone varies linearly with time. If a pure tone gives rise to a constant ... Sound localization is often more difficult with pure tones than with other sounds. Pure tones have been used by 19th century ... Pure tone for C3, an octave below middle C. The frequency is half that of middle C (131 Hz). Pure tone oscillogram of C5, an ...
"The Relevance of the High Frequency Audiometry in Tinnitus Patients with Normal Hearing in Conventional Pure-Tone Audiometry". ... Since most people with tinnitus also have hearing loss, a pure tone hearing test resulting in an audiogram may help diagnose a ... Spontaneous otoacoustic emissions (SOAEs)-faint high-frequency tones that are produced in the inner ear and can be measured in ... Henry, James A.; Meikle, Mary B. (May 1999). "Pulsed versus Continuous Tones for Evaluating the Loudness of Tinnitus". Journal ...
However, this type of hearing impairment is often undetectable by conventional pure tone audiometry, thus the name "hidden" ... The overall prevalence of hearing loss (defined as a puretone average threshold across frequencies 1000, 2000, 3000, and 4000 ... "Distributions of pure-tone hearing threshold levels among adolescents and adults in the United States by gender, ethnicity, and ... As race and ethnicity are some of the factors that can affect the expected distribution of pure-tone hearing thresholds several ...
Pure-tone audiometry screening, in which there is typically no attempt to find threshold, has been found to accurately assess ... pure-tone audiometry screening, and otoacoustic emissions (OAEs). Otoscopy is useful in the examination of the external ear, ... OAEs can be used in populations where responses to pure-tone audiometry are either unable to be obtained or results are ... ASHA) (1985). Guidelines for identification audiometry. ASHA, 27(5), 49-52. World Health Organization (WHO). (1997). Report of ...
... as measured with pure tone audiometry. Using this test, auditory agnosia patients were often reported capable of detecting pure ... The primary distinction between auditory agnosia and cerebral deafness is the ability to detect pure tones, ... Iizuka O, Suzuki K, Endo K, Fujii T, Mori E (April 2007). "Pure word deafness and pure anarthria in a patient with ... and confirmed intact pure tone perception. Similarly, Barrett's aphasic patient, who was incapable of comprehending speech, had ...
Tests of auditory system (hearing) function include pure tone audiometry, speech audiometry, acoustic reflex, ... which is pure vertical/torsional). Central pathology can cause disequilibrium, which is the sensation of being off balance. The ...
... assess the sensitivity of hearing and the results of this test should always be viewed in conjunction with pure tone audiometry ... The instrument changes the pressure in the ear, generates a pure tone, and measures the eardrum responses to the sound at ... A tone of 226 Hz is generated by a probe tip inserted into the external ear canal, where the sound strikes the tympanic ... While 226 Hz is the most common probe tone, others can be used. In infants under 4 months of age, research has shown a 1000 Hz ...
... is a health-care professional technician who has received special training in the use of Pure tone audiometry equipment. An ... "audiometry - assessmentofhearing". audiometry.sydneyinstitute.wikispaces.net. "Audiometry" (PDF). hsa.ie. See talk page on this ... "Audiometric Officer Course - Audiometry Courses, Occupational Audiometry, WorkCover Approved, The Hearing Company". www. ... Hearing Audiometry Audiometer Audiogram Audiologist Audiology Hearing test Hearing loss Occupational Health "What is an ...
Pure-tone audiometry for air conduction thresholds at 250, 500, 1000, 2000, 4000, 6000 and 8000 Hz is traditionally used to ... A hearing test administered by a medical doctor, otolaryngologist (ENT) or audiologist including pure tone audiometry and ... One early consequence is that even young adults may lose the ability to hear very high frequency tones above 15 or 16 kHz. ... Abilities of young people to hear high frequency tones inaudible to those over 25 or so has led to the development of ...
It is also used in various kinds of audiometry, including pure tone audiometry, and the standard hearing test to test each ear ... Combination tones can interact with primary tones resulting in secondary combination tones due to being like their original ... An example of this is 3F1 - 2F2 Secondary combination tones are again similar to the combination tones of the primary tone. Off ... For example, a powerful spike at 1 kHz will tend to mask out a lower-level tone at 1.1 kHz. Also, two sine tones at 440 and 450 ...
Pure tone audiometry, a standardized hearing test over a set of frequencies from 250 Hz to 8000 Hz, may be conducted by a ...
The standard and most common type of hearing test is pure tone audiometry, which measures the air and bone conduction ... Unlike a pure-tone audiogram, the WIN test may provide a more functional test of a person's hearing in a situation that is ... noise masking effect of tone signals Advantages of the audiometry conducted with a specialized application or hearing aid ... In this test a probe is placed in the ear and a loud tone, greater than 70 dBSPL, is produced. The test measures the reflexive ...
... as indexed through pure tone audiometry). These symptoms may lead to difficulty attending to auditory information causing many ...
In pure-tone audiometry, this manifests as air-bone gaps on the audiogram (i.e. a difference of more than 10 dB between the air ... On audiometry, the hearing loss is characteristically low-frequency, with higher frequencies being affected later. ... Carhart R (June 1950). "Clinical application of bone conduction audiometry". Archives of Otolaryngology. 51 (6): 798-808. doi: ...
... the same concept in vision Mel scale Pure tone audiometry Robinson-Dadson curves Sound level meter Weighting filter Suzuki, ... However, research in the 1960s demonstrated that determinations of equal-loudness made using pure tones are not directly ... Fletcher and Munson adjusted the reference tone until the listener perceived that it was the same loudness as the test tone. ... "A re-determination of the equal-loudness relations for pure tones", Br. J. Appl. Phys. 7 (1956), pp.166-181. Yôiti Suzuki, et ...
... technique to detect gravitational waves Pure tone audiometry, hearing test Purified terephthalic acid, organic compound used to ...
Psychoacoustics Pure tone audiometry Hearing Loss by Robert Thayer Sataloff (Pages using div col with small parameter, Otology ... Articulation index Audiogram Audiology Audiometry A-weighting Equal-loudness contour Hearing range Hearing (sense) ...
Pure-tone audiometry is described as the gold standard for assessment of a hearing loss but how accurate pure-tone audiometry ... published Guidelines for Manual Pure-Tone Threshold Audiometry in 2005. There are cases where conventional pure-tone audiometry ... Pure Tone Audiometry: What is Pure Tone Average (PTA) Test?. Springerlink.com. Audition Cochlea Promenade oreille ear organ ... Pure-tone audiometry provides ear specific thresholds, and uses frequency specific pure tones to give place specific responses ...
Learn about Audiometry, Pure-Tone at online-medical-dictionary.org ... Audiometry, Pure-Tone. Synonyms. Audiometry, Bekesy. Audiometry, Pure Tone. Bekesy Audiometry. Pure-Tone Audiometry. ... Measurement of hearing based on the use of pure tones of various frequencies and intensities as auditory stimuli. ...
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Tag: pure tone audiometry Hearing Tests, Hearing Aids & other Equipment for Hearing Impaired and Deaf individuals For a list of ...
Pure tone audiometry and impedance screening of school entrant children by nurses: evaluation in a practical setting. ... Pure tone audiometry and impedance screening of school entrant children by nurses: evaluation in a practical setting. ...
This study compared pure tone thresholds and distortion product otoacoustic emissions (DPOAEs) in this high frequency range for ... Pure tone thresholds were obtained at 250-16 kHz and distortion product otoacoustic emissions (DPOAE) 2,211-17,675 were ... Behavioral thresholds demonstrated an increase with increasing frequency of the pure tone stimulus. Pearson r-correlation ... obtained from 50 ears showed a decline in DPOAE amplitude with increasing frequency of the F1 and F2 primary stimulus tones. ...
Pure Tone Audiometry. Audiometry (pure tone audiometry, audiogram, and hearing test) is an examination designed to measure ... Audiometry tests help otolaryngologist to define the cause of hearing loss and to diagnose, in particular; to identify hearing ... Audiometry is done by the special equipment, audiometer with earphones attached to it. Examination and diagnosing have to be ... Note that the selection of hearing aids and their setting also better be done on the basis of audiometry test results.. ...
The pure-tone audiometer must be able to produce pure tones at certain frequencies, precisely control the levels of these tones ... The test sounds used to determine the degree of hearing loss are usually pure tones of different frequencies. ... Pure Tone Average in dB HL. ,15. 16-25. 26-40. 41-55. 56-70. 71-90. ​, or = 90 ...
Pure-tone audiometry. The human ear is capable of hearing frequencies from 20-20,000 Hz. Pure-tone audiometry is used to assess ... standard pure-tone and speech audiometry tests are used to screen likely candidates. For children aged 12-23 months, the pure- ... Pure-tone audiometry may reveal normal to profound hearing loss, but poor performance on speech discrimination testing is the ... A notch at 4000 Hz on pure-tone audiometry is fairly common in the setting of noise-induced hearing loss, but hearing loss may ...
Pure Tone Audiometry. After excluding middle ear pathologies by otoscopic examination and tympanometry test, a pure tone ... audiometry test was conducted in a sound-proof cabin in the frequency range of 0.25-8 kHz. Pure tone average (PTA) was ... For patients with secondary BPPV (s-BPPV), comprehensive neurotologic evaluations, including audiometry, videonystagmography, ...
Pure-Tone Audiometry. Pure-tone thresholds (air conduction: 0.25, 0.5, 1, 2, 4, and 8 kHz; bone conduction: 0.5 and 4 kHz) were ... Hearing thresholds with pure-tone audiometry were obtained, and other detailed information on a large number of possible ... We included participants from cohorts RS-I-1, RS-II-3, and RS-III-2, who underwent pure-tone audiometry between 2011 and 2013. ... We would like to thank Tekla Enser for her extensive work in performing all pure-tone audiometry on participants in this study ...
View cost for Pure Tone Audiometry Test, book appointment for Pure Tone Audiometry Test on DoctoriDuniya ... Doctor for Pure Tone Audiometry Test in Basti. ... Pure Tone Audiometry Test in Basti. ENT is the branch of ... pure tone audiometry test in basti - Book Online Appointment/Online Consultation. .basic3 { background-color: #16A085; margin: ...
Pure tone air conduction threshold audiometry for hearing conservation purposes ... be adversely affected by occupational noise exposure and presents techniques for automatic recording and manual audiometry. ...
Conditioned Play Audiometry. Older children are given a fun version of the pure tone audiometry test. Sounds of varying volume ... Pure Tone Audiometry. This test usually takes place in a soundproof booth. You will put on headphones that are connected to an ... Audiometry is a test that measures how well a person can hear. It is done by an audiologist. This is a person who is trained to ... Speech Audiometry. You will wear special headphones. You will hear simple, 2-syllable words. Words will be sent to one ear at a ...
BSA: Procedure for Pure-tone air-conduction and bone-conduction threshold audiometry with and without masking. 01 June 2020 ... BSA: Procedure for Pure-tone air-conduction and bone-conduction threshold audiometry with and without masking ... This document describes standard procedures and recommendations for effective pure-tone audiometry carried out in most ... It also includes descriptors for pure-tone audiograms and the recommended format for audiogram forms. This document is not ...
The results were compared with pure-tone audiometry. Results: A total of 70 subjects, 34 men and 36 women, aged 18-71 years ( ... The hearing threshold obtained on mobile devices was significantly different from the one determined by pure-tone audiometry ... biologically determined reference sound level with the hearing threshold obtained in pure-tone audiometry. Methods: Trial ... self-test carried out on mobile devices with bundled headphones demonstrates high compatibility with pure-tone audiometry, ...
... high-frequency audiometry, pure tone audiometry and a lot more. ... Pure tone audiometry * Air conduction: hearing level (HL), most ... It can perform advanced clinical audiometry and interfaces with databases and electronic medical record (EMR) systems. ...
Aarktica - Pure Tone Audiometry $10.00 Notify me when this product is available:. ...
However, pure-tone audiometry (PTA), MRI of the brain and internal auditory canal (with and without contrast), and cerebral CT ...
Audiometry, Pure-Tone * Child * Child, Preschool * England / epidemiology * Female * Health Planning / organization & ...
Audiometry, Pure-Tone / methods * Cochlea / physiopathology * Female * Hair Cells, Auditory, Outer / physiology ... The present study recorded 2f(1)-f(2) DPOAE-grams in response to moderate primary tones (L1 = 75, L2 = 65 dB SPL), from 1 to ...
Sound field audiometry with pure tone and narrow-band test signals ... and procedures for sound field audiometry using pure tones, frequency modulated tones or other narrow-band test signals ... Acoustics - Audiometric test methods - Part 2: Sound field audiometry with pure tone and narrow-band test signals. ...
Traditional behavioral tests of hearing (e.g., pure-tone and speech audiometry) are generally successful in the early stages of ... These include simplifying directions, using pulse tones, slowing the presentation of speech stimuli, providing reminders to ...
... and results from pure tone air conduction audiometry. The hearing evaluations data are provided in an ASCII text file ( ... and results from pure tone air conduction audiometry. The hearing evaluations data are provided in an ASCII text file ( ... results from pure tone air conduction audiometry; and results of a screener for specific language impairment. The hearing ...
During an in-office visit, the hearing specialist or audiologist will perform a pure tone audiometry, which Mayfield Clinic in ... The test uses tone frequency to test both your left and right ears. Also called air conduction testing, a pure tone test uses ... Guidelines for Manual Pure-Tone Threshold Audiometry. Found on the internet at https://www.asha.org/policy/gl2005-00014 ... According to the ASHA, an audiogram is "a graph showing the results of a pure-tone hearing test," which is a hearing test that ...
American National Standard Methods for Manual Pure-Tone Threshold Audiometry. *4-228 ANSI ASA S3.20-2015 (Reaffirmed 2020) ...
Pure tone audiometry, impedancemetry, speech audiometry in quiet [...] Read more. In this study, we assessed the impact of ... Pure tone audiometry, impedancemetry, speech audiometry in quiet and noise, the Binaural Fusion Test, the dichotic digits test ... According to pure tone audiometry, 24% of the subjects had normal hearing, while 76% had some degree of hearing loss. No ... The patient underwent careful collection of medical history, otomiscroscopy, pure tone audiometry, tympanometry, reflex ...
Early in the disease course, pure-tone audiometry usually demonstrates low-frequency conductive hearing loss. High-frequency ...
Pure-tone audiometry was conducted in both ears at 500, 1000, 2000, 3000, 4000, 6000, and 8000 Hz. All noise exposures were ... pure-tone audiometry; referee; sports; temporary threshold shift; TTS ... The threshold shifts between the pre- and post-game audiometry were statistically significant in the left ear at 500 (p=.019), ... Noise induced hearing loss; Noise exposure; Hearing; Hearing loss; Hearing threshold; Exposure levels; Risk factors; Audiometry ...
  • In the United States, the American Speech-Language-Hearing Association (ASHA) published Guidelines for Manual Pure-Tone Threshold Audiometry in 2005. (wikipedia.org)
  • There are variations of conventional audiometry testing that are designed specifically for young children and infants, such as behavioral observation audiometry, visual reinforcement audiometry and play audiometry. (wikipedia.org)
  • With headphones on, Play Audiometry teaches your child to carry out a certain task when he hears a specific sound. (widex.com)
  • The auditory condition was verified by visual examination of the external ear canal, pure tone audiometry, and tympanometry. (scielo.br)
  • Otoscopic examination, tympanometry and pure tone audiometry (PTA) were done. (who.int)
  • As pure-tone audiometry uses both air and bone conduction audiometry, the type of loss can also be identified via the air-bone gap. (wikipedia.org)
  • Pure tone audiometry, also called air conduction testing, measures your response to sounds of different volumes and frequencies. (houstonent.com)
  • In people with sensorineural hearing loss, this acoustic curve does not present any difference between bone conduction (tones are transmitted through the bone) and the air duct (tones are transmitted through the air to the eardrum and to the inner ear via the ossicles). (hear.com)
  • In addition, NHANES conducts pure-tone air-conduction audiometry. (cdc.gov)
  • Totally 28 youth undergraduates (56 ears) with normal hearing were selected to conduct the pure tone threshold audiometry (PTA), and the air-conduction auditory threshold of each frequency was no more than 15 dBHL. (who.int)
  • Pure-tone air-conduction thresholds are poorer than bone-conduction thresholds by more than 10 dB (see image below). (medscape.com)
  • Pure-tone air- and bone-conduction thresholds are within 10 dB. (medscape.com)
  • Pure-tone audiometry is the main hearing test used to identify hearing threshold levels of an individual, enabling determination of the degree, type and configuration of a hearing loss and thus providing a basis for diagnosis and management. (wikipedia.org)
  • Pure-tone audiometry is a subjective, behavioural measurement of a hearing threshold, as it relies on patient responses to pure tone stimuli. (wikipedia.org)
  • There are cases where conventional pure-tone audiometry is not an appropriate or effective method of threshold testing. (wikipedia.org)
  • This study aimed to compare the hearing threshold measured by a mobile device that was calibrated using a model-specific, biologically determined reference sound level with the hearing threshold obtained in pure-tone audiometry. (jmir.org)
  • The hearing threshold obtained on mobile devices was significantly different from the one determined by pure-tone audiometry with a mean difference of 2.6 dB (95% CI 2.0-3.1) and SD of 8.3 dB (95% CI 7.9-8.7). (jmir.org)
  • One of the basic hearing tests is pure-tone audiometry, which determines the hearing threshold in relation to the sound frequency. (jmir.org)
  • Specifies relevant test signal characteristics, requirements for free, diffuse and quasi-free sound fields, and procedures for sound field audiometry using pure tones, frequency modulated tones or other narrow-band test signals presented by one or more loudspeakers, primarily for the purpose of determining hearing threshold levels in the frequency range from 125 Hz to 12 500 Hz. (iso.org)
  • The threshold shifts between the pre- and post-game audiometry were statistically significant in the left ear at 500 (p=.019), 2000 (p=.0009), 3000 (p (cdc.gov)
  • 13. Speech threshold audiometry (e.g. (audiology.org)
  • "Hearing impairment" and "hearing loss" are often used interchangeably by health care professionals when referring to hearing below threshold levels for normal hearing determined by audiometry. (nature.com)
  • The hearing improvements were evaluated by comparing the changes in pure tone hearing threshold and speech recognition rate of patients before and after BONEBRIDGE implantation. (bvsalud.org)
  • Pure-tone audiometry only measures audibility thresholds, rather than other aspects of hearing such as sound localization and speech recognition. (wikipedia.org)
  • Pure-tone audiometry provides ear specific thresholds, and uses frequency specific pure tones to give place specific responses, so that the configuration of a hearing loss can be identified. (wikipedia.org)
  • Previous studies show that pure tone thresholds are strongly correlated with distortion product otoacoustic emission amplitudes when evaluating the frequency range from 1 to 8 kHz (Avan & Bonfils, 1993). (pdx.edu)
  • This study compared pure tone thresholds and distortion product otoacoustic emissions (DPOAEs) in this high frequency range for 29 normal hearing subjects ages 18-30. (pdx.edu)
  • Pure tone thresholds were obtained at 250-16 kHz and distortion product otoacoustic emissions (DPOAE) 2,211-17,675 were measured in the same ears. (pdx.edu)
  • Behavioral thresholds demonstrated an increase with increasing frequency of the pure tone stimulus. (pdx.edu)
  • Hearing thresholds with pure-tone audiometry were obtained, and other detailed information on a large number of possible determinants was collected. (karger.com)
  • Deaf (small "d") is a colloquial term that implies hearing thresholds in the severe-to-profound range by audiometry. (nature.com)
  • Pure-tone thresholds (PTTs) indicate the softest sound audible to an individual at least 50% of the time. (medscape.com)
  • Audiometry (pure tone audiometry, audiogram, and hearing test) is an examination designed to measure hearing sensitivity. (vixclinic.com.ua)
  • Tone audiogram display in speech screen. (interacoustics.com)
  • It also includes descriptors for pure-tone audiograms and the recommended format for audiogram forms. (bshaa.org)
  • Multi-frequency audiometry for tinnitus assessments. (interacoustics.com)
  • Pure tone audiometry and tinnitus evaluation at enrolment and after 7 and 13 months. (egms.de)
  • However, there are benefits to using pure-tone audiometry over other forms of hearing test, such as click auditory brainstem response (ABR). (wikipedia.org)
  • Although pure-tone audiometry has many clinical benefits, it is not perfect at identifying all losses, such as 'dead regions' of the cochlea and neuropathies such as auditory processing disorder (APD). (wikipedia.org)
  • Measurement of hearing based on the use of pure tones of various frequencies and intensities as auditory stimuli. (online-medical-dictionary.org)
  • Deafness is a disabling auditory handicap that could benefit from improved management through the use of pure-tone audiometry. (bvsalud.org)
  • Conventional audiometry tests frequencies between 250 hertz (Hz) and 8 kHz, whereas high frequency audiometry tests in the region of 8 kHz-16 kHz. (wikipedia.org)
  • The test sounds used to determine the degree of hearing loss are usually pure tones of different frequencies. (evokedpotential.com)
  • The pure-tone audiometer must be able to produce pure tones at certain frequencies, precisely control the levels of these tones, and deliver them to the patient in the manner intended by the audiologist. (evokedpotential.com)
  • The study took place over a period of 12 months from January 1, 2021, to December 31, 2021, and included patients with hearing loss and/or peripheral vertigo who underwent a pure-tone audiometry revealing deafness. (bvsalud.org)
  • Pure tone audiometry and impedance screening of school entrant children by nurses: evaluation in a practical setting. (bmj.com)
  • During impedance audiometry, the vibrational ability of the eardrums and ossicles are examined, and the pressure in the middle ear is measured. (hear.com)
  • Therefore, pure-tone audiometry is only used on adults and children old enough to cooperate with the test procedure. (wikipedia.org)
  • Note that the selection of hearing aids and their setting also better be done on the basis of audiometry test results. (vixclinic.com.ua)
  • Currently, No result found in Basti for Pure Tone Audiometry Test. (doctoriduniya.com)
  • Audiometry is a test that measures how well a person can hear. (epnet.com)
  • Older children are given a fun version of the pure tone audiometry test. (epnet.com)
  • The method of hearing self-test carried out on mobile devices with bundled headphones demonstrates high compatibility with pure-tone audiometry, which confirms its potential application in hearing monitoring, screening tests, or epidemiological examinations on a large scale. (jmir.org)
  • Further diagnostics can also include a hearing test (audiometry). (hear.com)
  • In the case of labyrinthine hearing loss, the Weber test will ascertain that the tone relocates to the healthy ear, i.e. where it is perceived as louder. (hear.com)
  • Pure Tone Audiometry is for older children, and it's similar to an adult hearing test. (widex.com)
  • Pure-tone audiometry is a behavioral test used to measure hearing sensitivity. (medscape.com)
  • METHODOLOGY: Patients with FM and gender/age matched controls were compared with pure-tone audiometric (PTA), and transient evoked otoacoustic emissions (TEOE) tests after standardised otorhinolaryngologic assessment The subjects were questioned for NSAID uptake and scored with ASAS-NSAID score. (bvsalud.org)
  • The HINT measures word-recognition abilities to evaluate the patient's candidacy for cochlear implantation, in conjunction with conventional pure-tone and speech audiometry. (medscape.com)
  • Pure-tone audiometry examines the patient's tone perception. (hear.com)
  • Tones of varying frequency and increasing volume are then presented to the patient via headphones. (hear.com)
  • Audiometry is done by the special equipment, audiometer with earphones attached to it. (vixclinic.com.ua)
  • It can perform advanced clinical audiometry and interfaces with databases and electronic medical record (EMR) systems. (interacoustics.com)
  • In the United Kingdom, The British Society of Audiology (BSA) is responsible for publishing the recommended procedure for pure-tone audiometry, as well as many other audiological procedures. (wikipedia.org)
  • This document describes standard procedures and recommendations for effective pure-tone audiometry carried out in most audiological contexts. (bshaa.org)
  • Sound field audiometry may be more suitable when patients are unable to wear earphones, as the stimuli are usually presented by loudspeaker. (wikipedia.org)
  • However, it can be used as a simple and ready means for the exchange of specifications and of physical data on hearing aids and for the calibration of specified insert earphones used in audiometry. (saiglobal.com)
  • For adults and children who can respond reliably, standard pure-tone and speech audiometry tests are used to screen likely candidates. (medscape.com)
  • Hearing screening tests based on pure-tone audiometry may be conducted on mobile devices, provided that the devices are specially calibrated for the purpose. (jmir.org)
  • Therefore, it may be necessary to use other stimuli, such as warble tones in sound field testing. (wikipedia.org)
  • Therefore, high frequency audiometry is an effective method of monitoring losses that are suspected to have been caused by these factors. (wikipedia.org)
  • Data obtained from 50 ears showed a decline in DPOAE amplitude with increasing frequency of the F1 and F2 primary stimulus tones. (pdx.edu)
  • Pure-tone audiometry is used to assess a subject's response to a frequency at a specific intensity measured in decibels. (medscape.com)
  • High frequency audiometry (up to 20 kHz). (interacoustics.com)
  • Pure-tone audiometry revealed deterioration of the postoperative hearing in the low frequency range. (hindawi.com)
  • The patient signals as soon as he perceives the tone. (hear.com)
  • For children aged 12-23 months, the pure-tone average (PTA) for both ears should equal or exceed 90 dB. (medscape.com)
  • A small device is placed behind your ear and struck gently, producing vibrations that generate a mechanical tone which should stimulate the cochlea. (houstonent.com)
  • Specifies procedures and requirements without masking that are applicable to individuals whose hearing sensiticity might be adversely affected by occupational noise exposure and presents techniques for automatic recording and manual audiometry. (iso.org)
  • However, a limitation of existing datasets is that hearing health phenotypes are captured at a rudimentary level, with even basic pure-tone audiometry data rarely being available. (nottingham.ac.uk)
  • However, such children are rarely confidence level at 95% (standard value tone audiometry (PTA). (who.int)
  • Measuring your ability to hear tones ranging from low to high helps the audiologist determine degree and type of hearing loss. (christianacare.org)
  • This type of hearing loss is usually accompanied by a reduced perception of high tones. (hear.com)
  • Pure-tone audiometry is the "gold standard" for hearing loss assessment, but it is affected by the subjective cooperation of the assessed person. (bvsalud.org)
  • In addition, response to pure tone stimuli may be limited, because in a sound field pure tones create standing waves, which alter sound intensity within the sound field. (wikipedia.org)
  • Visual Audiometry teaches your baby or toddler to link a sound to a visual element. (widex.com)
  • Due to her young age, limited communicative abilities and concerns for more sinister underlying pathology, a complete neurological examination, MRI and pure tone audiometry were performed. (bvsalud.org)
  • The methods of automated audiometry have been developed over many years. (jmir.org)
  • The present study recorded 2f(1)-f(2) DPOAE-grams in response to moderate primary tones (L1 = 75, L2 = 65 dB SPL), from 1 to 6.3 kHz. (nih.gov)
  • The current International Organization for Standardization (ISO) standard for pure-tone audiometry is ISO:8253-1, which was first published in 1983. (wikipedia.org)
  • The current American National Standards Institute (ANSI) standard for pure-tone audiometry is ANSI/ASA S3.21-2004, prepared by the Acoustical Society of America. (wikipedia.org)
  • The results were compared with pure-tone audiometry. (jmir.org)
  • Once learned, as with the Visual Audiometry, the volume and pitch will be varied. (widex.com)