Distortion-Product Otoacoustic Emissions(DPOAEs) are thought to be generated from the cochlear outer hair cells. DPOAEs can be measured in the external ear canal twofold:amplitude and latency. However, most DPOAE studies deal with amplitude aspects. If DPOAE latency is related to the progression of the traveling wave along the basilar membrane, it may also reflect the cochlear function. The purpose of this study was to investigate if the latency measurement could be used as a clinical test of hearing. For this purpose, DPOAE latency measures were examined as a function of frequency from 1 to 8 kHz in 38 normal ears from 19 adults(7 females and 12 males). Results showed that the latency decreased as frequency increased up to 6 kHz. Test/retest reliability was relatively high in 4-6 kHz and the lowest at 1 kHz. There was no gender effect for all test frequencies. The results suggest that the measurement of DPOAE latency has a clinical potential, but more data be obtained before it can be clinically used.
Basilar Membrane ; Ear Canal ; Ear* ; Female ; Hair ; Hearing ; Humans

Mass and stiffness affect on the peculiar characteristics of transmission of the middle ear and the distinctive behavior of the cochlear mechanics. Applying the principle of the mass and stiffness, the band-pass characteristic transfer function of the middle ear has been explained. The greatest transfer function of the middle ear, approximately 24-29 dB, is observed at 1-2 kHz in both cat and human species. However, at lower frequencies, the transfer function was disturbed by the stiffness of the middle ear primarily due to middle ear cavity. At higher frequencies, the transfer function was disturbed by the stiffness of the middle ear primarily due to middle ear bones. Several examples, such as an acoustic reflex, otitis media, and otosclerosis are discussed. For understanding the traveling wave of the basilar membrane, different place tuning at certain stimulus frequencies, contrastingly shaped basilar membrane to the cochlear duct, and the structural and physical characteristics of the whole cochlear partition were reviewed in terms of changing width, mass, and stiffness from the base to apex. Being about ten times wider, more massive, and one hundredfold stiffer at the base than the apex, the nature of the cochlear partition to absorb high-frequency energy changes in fluid pressure declines toward the apex. Consequently, at the base of the cochlea, high frequencies stimuli are decoded while low frequencies stimuli are decoded at the apex of the cochlea. Due to these characteristics of the cochlear partition, the direction of the traveling wave was also proved to be in the fashion of base-to-apex always.
Animals ; Basilar Membrane ; Cats ; Cochlea ; Cochlear Duct ; Ear, Middle* ; Humans ; Mechanics ; Otitis Media ; Otosclerosis ; Reflex, Acoustic

OBJECTIVETo establish a mechanical simulation model for studying the relationship between the characteristic frequency and feature location of the basilar membrane of the cochlea.

METHODSMacro-mechanical methods were used to simplify the details of the model. With simulation tools, the basilar membrane vibration frequency characteristics were analyzed based on the box model.

RESULTSThe basilar membrane had obvious frequency-selective properties, and the basilar membrane from the stapes was sensitive to high frequencies while the farther membrane was sensitive to low frequencies.

CONCLUSIONThe frequency characteristics of the basilar membrane of the cochlea is mainly a result of the longitudinal variations of the geometric dimensions and material properties and is not related with other structures within the cochlea corti.

OBJECTIVE: To study the relationship of distortion product in cochlea with cochlear activity and hearing. METHOD: Time variances of distortion product of basilar membrane vibration in vitro guineapig cochlea were observed by laser interferometry. RESULT: Within half hour after a cochlea was isolated from a guineapig, distortion product accompanied with two-tone inhibition in cochlea, can be observed. As time passed, distortion product and two-tone inhibition effect disappeared at the same time. After that, the membrane contiune vibrating in response to the sound stimulus, but the vibration amplitude decreased obviously and continued decreasing until it disappeared completely. CONCLUSION Distortion product in cochlea is a symbol of cochlear activity which makes the membrane respond in large amplitude vibration to sound stimulus and exhibit two-tone inhibition. The former makes the hearing highly sensitive to sound stimulus, the later makes the hearing perform information abstract well.
Acoustic Stimulation ; Animals ; Basilar Membrane ; physiology ; Cochlea ; physiology ; Guinea Pigs ; Hearing ; physiology ; Hearing Tests ; Interferometry ; Sound

BACKGROUND AND OBJECTIVES: The diagnosis of Meniere's disease is based on audiological test and clinical symptoms. Cochlear Hydrops Analysis Masking Procedure (CHAMP) was introduced as a test for detecting changes in physical characteristics of basilar membrane by hydrops of endolympahtic system. The aim of this study is to evaluate the diagnostic value and usefulness of CHAMP tests for detection of endolymphatic hydrops. SUBJECTS AND METHOD: This study was performed on 11 cases of Meniere's disease and 10 cases of vestibular neuritis who visited ENT outpatient clinic and 25 cases of normal healthy volunteers. We defined the positive value as being less than 0.3 ms in latency delay (0.5 kHz HPN-click alone) and less than 0.95 nV in compound amplitude ratio (click alone 0.5 kHz HPN/ click alone) regardless of age or sex. RESULTS: There were significant latency delays in the Meniere's disease group compared with the vestibular neuritis and normal control group. The amplitude ratio gave significant differences between the Meniere's disease group and the normal group but there were no differences between the Meniere's disease group and the vestibular neuritis group. Without assuming the test failure, the sensitivity and specificity of latency delay was 81% and 100%, respectively, and the sensitivity and specificity of amplitude ratio was 100% and 84%, respectively. In 8 of 54 cases (14.8%), we couldn't get interpretable wave. CONCLUSION: CHAMP test is a clinically useful method that can detect endolymphatic hydrops and it can be used as an objective test for the diagonosis of Meniere's disease.
Ambulatory Care Facilities ; Basilar Membrane ; Edema ; Endolymphatic Hydrops ; Masks ; Meniere Disease ; Sensitivity and Specificity ; Vestibular Neuronitis

BACKGROUND AND OBJECTIVES: Cisplatin (cis-diamminodichloroplatinum) exercises its ototoxic effect by damaging hair cells of the inner ear. The effect of cisplatin on the vibratory response of the inner ear was investigated in the apical turn of the cochlea in 11 living guinea pigs. MATERIALS AND METHODS: The exposed turn was sealed and fluid coupled to the objective lens of a slit confocal microscope. Individual cells were identified with the microscope and the vibration was measured with a confocal heterodyne interferometer. The vibration was made in response to tones applied to the ear canalat at selected locations such as the reticular lamina (Hensen cells and outer hair cells), and the basilar membrane adjacent to the outer Hensen cell edge. Vibration measurements were made before and after intravenous injections of cisplatin (16 mg/kg). RESULTS: The drug effect took place approximately 35 minutes after administering cisplatin. The vibration amplitude changes produced by cisplatin were not reversible with time. At the level of the reticular lamina, cisplatin reduced the vibration amplitude at almost all frequencies. However, these effects were small. In contrast to the reticular lamina response, at the basilar membrane, the vibration amplitude increased following cisplatin application. CONCLUSION: These experiments show that damage to the hair cells in the apical turn of the cochlea leads to an increase in the basilar membrane vibration. These observations support the concept of negative Feedback in the apical turn of the cochlea.
Animals ; Basilar Membrane ; Cisplatin* ; Cochlea* ; Ear ; Ear, Inner ; Exercise ; Guinea Pigs* ; Guinea* ; Hair ; Injections, Intravenous ; Vibration

The main objective of this study is to provide an overview of the basic mechanisms of blast induced hearing loss and review pharmacological treatments or interventions that can reduce or inhibit blast induced hearing loss. The mechanisms of blast induced hearing loss have been studied in experimental animal models mimicking features of damage or injury seen in human. Blast induced hearing loss is characterized by perforation and rupture of the tympanic membrane, ossicular damage, basilar membrane damage, inner and outer hair cell loss, rupture of round window, changes in chemical components of cochlear fluid, vasospasm, ischemia, oxidative stress, excitotoxicity, hematoma, and hemorrhage in both animals and humans. These histopathological consequences of blast exposure can induce hearing loss, tinnitus, dizziness, and headache. The pharmacological approaches to block or inhibit some of the auditory pathological consequences caused by blast exposure have been developed with antioxidant drugs such as 2,4-disulfonyl alpha-phenyl tertiary butyl nitrone (HXY-059, now called HPN-07) and N-acetylcysteine (NAC). A combination of antioxidant drugs (HPN-07 and NAC) was administered to reduce blast induced cochlear damage and hearing loss. The combination of the antioxidant drugs can prevent or treat blast induced hearing loss by reducing damage to the mechanical and neural component of the auditory system. Although information of the underlying mechanisms and treatment of blast induced hearing loss are provided, further and deep research should be achieved due to the limited and controversial knowledge.
Acetylcysteine ; Animals ; Basilar Membrane ; Blast Injuries ; Dizziness ; Hair ; Headache ; Hearing ; Hearing Loss ; Hematoma ; Hemorrhage ; Humans ; Ischemia ; Models, Animal ; Oxidative Stress ; Rupture ; Tinnitus ; Tympanic Membrane

The main objective of this study is to provide an overview of the basic mechanisms of blast induced hearing loss and review pharmacological treatments or interventions that can reduce or inhibit blast induced hearing loss. The mechanisms of blast induced hearing loss have been studied in experimental animal models mimicking features of damage or injury seen in human. Blast induced hearing loss is characterized by perforation and rupture of the tympanic membrane, ossicular damage, basilar membrane damage, inner and outer hair cell loss, rupture of round window, changes in chemical components of cochlear fluid, vasospasm, ischemia, oxidative stress, excitotoxicity, hematoma, and hemorrhage in both animals and humans. These histopathological consequences of blast exposure can induce hearing loss, tinnitus, dizziness, and headache. The pharmacological approaches to block or inhibit some of the auditory pathological consequences caused by blast exposure have been developed with antioxidant drugs such as 2,4-disulfonyl alpha-phenyl tertiary butyl nitrone (HXY-059, now called HPN-07) and N-acetylcysteine (NAC). A combination of antioxidant drugs (HPN-07 and NAC) was administered to reduce blast induced cochlear damage and hearing loss. The combination of the antioxidant drugs can prevent or treat blast induced hearing loss by reducing damage to the mechanical and neural component of the auditory system. Although information of the underlying mechanisms and treatment of blast induced hearing loss are provided, further and deep research should be achieved due to the limited and controversial knowledge.
Acetylcysteine ; Animals ; Basilar Membrane ; Blast Injuries ; Dizziness ; Hair ; Headache ; Hearing ; Hearing Loss ; Hematoma ; Hemorrhage ; Humans ; Ischemia ; Models, Animal ; Oxidative Stress ; Rupture ; Tinnitus ; Tympanic Membrane

BACKGROUND AND OBJECTIVES: Inner hair cells (IHCs) of the organ of Corti change the external sound stimulus into the electrical signal and transmit this signal to the auditory cortex through afferent nerve fibers. Outer hair cells (OHCs) control the sound transmission function of IHC. OHCs respond with a somatic shape change to alterations in their membrane potential and this electromotile response is believed to provide mechanical feedback to the basilar membrane. Efferent nerve fibers which arise from the superior olivary nucleus in the midbrain and transmit to OHCs through medial olivocochlear bundle use acetylcholine (ACh) as a neurotransmitter. The cholinergic response of OHCs' alpha-9 nicotinic ACh receptor increase the Ca2+ influx, which control OHCs' electromotility by changing a membrane potential. In this research, the effect of ACh on the K+ current in OHC of guinea pig was studied, and the change of OHC length by ACh was studied. MATERIALS AND METHODS: Using the extracted OHC from a guinea pig potassium currents induced by ACh were recorded using the whole-cell patch clamp technique. The change of OHC length when ACh was applied was observed. RESULTS: 1) ACh increases voltage-dependent K+ current in OHC. 2) In the condition, which Ca2+-dependent K+ current is blocked by removing Ca2+ from intra-cellular fluid, ACh has no effect on K+ current in OHC. 3) ACh increases OHC length. CONCLUSION: These experimental results show that ACh from the medial olivocochlear efferent system regulates mobility of OHC, increases the Ca2+-dependent K+ currents in OHC.
Acetylcholine* ; Animals ; Auditory Cortex ; Basilar Membrane ; Calcium ; Guinea Pigs ; Hair* ; Membrane Potentials ; Mesencephalon ; Nerve Fibers ; Neurotransmitter Agents ; Olivary Nucleus ; Organ of Corti ; Potassium Channels ; Potassium*

BACKGROUND AND OBJECTIVES: Endolymphatic hydrops has been considered as an important histologic substrate of Meniere's disease. A permanent displacement of basilar membrane (BM) by increased endolymphatic pressure has been thought to be an explanation for hearing change. Direct observation of histological sections of temporal bones, however, suggested that stereocilia and tectorial membrane decoupling is more associated with pressure induced by mechanical deformation of the organ of Corti rather than with the displacement of BM. METERIALS AND METHOD: 26 cochleae from 13 female pigmented ginea pigs were harvested. One cochlea per each animal was injected with artificial perilymph. The other one was used as control. After fixation, followed by embedding and mid-modiolar sectionning, specimens were observed with a microscope. Morphometric parameters of each row and turn of the organ of Corti were measured and quantified. RESULTS: The average area and height of the organ of Corti were significantly smaller in the apical turn of the experimental group (p<0.05). The lengths of outer hair cell and Deiters cell in the apical turn were also significantly reduced in the experimental group (p<0.05). The angle between the outer hair cell and Deiters cell was smaller in the apex and in the 3rd turn of the experimental group (p<0.05). CONCLUSION: Results show that compression and deformation of the organ of Corti, especially in the apical turn, is a prominent feature in the acute endolymphatic hydrops model. We suggest that the deformation of organ of Corti is the primary cause of hydrops that induce the decoupling of tectorial membrane and stereocilia rather than the displacement of BM.
Animals ; Basilar Membrane ; Cochlea ; Edema ; Endolymphatic Hydrops* ; Female ; Guinea Pigs ; Hair ; Hearing ; Humans ; Meniere Disease ; Organ of Corti* ; Perilymph ; Stereocilia ; Swine ; Tectorial Membrane ; Temporal Bone