RESUMEN
Introducción y objetivos: Ante posibles pérdidas de audición a causa de sobrecargas sonoras y la escasa referencia de procedimientos objetivos para su estudio, aportamos una técnica que suministra datos precisos sobre el perfil audiométrico y el factor reclutamiento. El objetivo del estudio es la determinación de la fatiga auditiva temporal a través de la respuesta microfónica coclear ante estímulos de sobrecarga de presión sonora y medida del tiempo de recuperación. Material y método: Instrumentación específica para el estudio de microfónicos cocleares, más un generador que nos proporciona estímulos sonoros de diversa intensidad y componente armónico. Utilizamos ratas Wistar. Medimos la respuesta microfónica normal y después el efecto que sobre ella ha ejercido la aportación de sobrecarga acústica. Resultados: Utilizando un tono puro a 60 dB obtenemos una respuesta microfónica. Fatigando de inmediato con 100 dB en la misma frecuencia, a los 15 min obtenemos una pérdida de 11 dB, a partir de los cuales el deterioro se lentifica y no supera los 15 dB. Mediante sonidos de banda compleja aleatoria o ruido blanco no se produce fatiga ni a niveles de 100 dB durante una hora de sobreestímulo. Conclusiones: No existe fatiga a nivel de los receptores sensoriales. El deterioro de la respuesta mediante intenso sobreestímulo posiblemente se deba a alteraciones bioquímicas de desensibilización por agotamiento. La fatiga auditiva en pruebas clínicas subjetivas afecta a tramos supracocleares. Las pruebas de fatiga auditiva encontradas no coinciden con las obtenidas subjetivamente en clínica ni en psicoacústica (AU)
Introduction and objectives: Given the relevance of possible hearing losses due to sound overloads and the short list of references of objective procedures for their study, we provide a technique that gives precise data about the audiometric profile and recruitment factor. Our objectives were to determine peripheral fatigue, through the cochlear microphonic response to sound pressure overload stimuli, as well as to measure recovery time, establishing parameters for differentiation with regard to current psychoacoustic and clinical studies. Material and method: We used specific instruments for the study of cochlear microphonic response, plus a function generator that provided us with stimuli of different intensities and harmonic components. In Wistar rats, we first measured the normal microphonic response and then the effect of auditory fatigue on it. Results: Using a 60 dB pure tone acoustic stimulation, we obtained a microphonic response at 20 dB. We then caused fatigue with 100 dB of the same frequency, reaching a loss of approximately 11 dB after 15 minutes; after that, the deterioration slowed and did not exceed 15 dB. By means of complex random tone maskers or white noise, no fatigue was caused to the sensory receptors, not even at levels of 100 dB and over an hour of overstimulation. Conclusions: No fatigue was observed in terms of sensory receptors. Deterioration of peripheral perception through intense overstimulation may be due to biochemical changes of desensitisation due to exhaustion. Auditory fatigue in subjective clinical trials presumably affects supracochlear sections. The auditory fatigue tests found are not in line with those obtained subjectively in clinical and psychoacoustic trials (AU)
Asunto(s)
Animales , Masculino , Femenino , Ratas , Fatiga Auditiva/fisiología , Fatiga Auditiva/efectos de la radiación , Audiometría/métodos , Enfermedades del Nervio Vestibulococlear/diagnóstico , Enfermedades del Nervio Vestibulococlear/veterinaria , Conducto Coclear/patología , Conducto Coclear , Conducto Coclear/efectos de la radiación , Electrodos , Técnicas BiosensiblesRESUMEN
INTRODUCTION AND OBJECTIVES: Given the relevance of possible hearing losses due to sound overloads and the short list of references of objective procedures for their study, we provide a technique that gives precise data about the audiometric profile and recruitment factor. Our objectives were to determine peripheral fatigue, through the cochlear microphonic response to sound pressure overload stimuli, as well as to measure recovery time, establishing parameters for differentiation with regard to current psychoacoustic and clinical studies. MATERIAL AND METHOD: We used specific instruments for the study of cochlear microphonic response, plus a function generator that provided us with stimuli of different intensities and harmonic components. In Wistar rats, we first measured the normal microphonic response and then the effect of auditory fatigue on it. RESULTS: Using a 60dB pure tone acoustic stimulation, we obtained a microphonic response at 20dB. We then caused fatigue with 100dB of the same frequency, reaching a loss of approximately 11dB after 15minutes; after that, the deterioration slowed and did not exceed 15dB. By means of complex random tone maskers or white noise, no fatigue was caused to the sensory receptors, not even at levels of 100dB and over an hour of overstimulation. CONCLUSIONS: No fatigue was observed in terms of sensory receptors. Deterioration of peripheral perception through intense overstimulation may be due to biochemical changes of desensitisation due to exhaustion. Auditory fatigue in subjective clinical trials presumably affects supracochlear sections. The auditory fatigue tests found are not in line with those obtained subjectively in clinical and psychoacoustic trials.
Asunto(s)
Fatiga Auditiva/fisiología , Potenciales Microfónicos de la Cóclea , Estimulación Acústica , Animales , Audiometría de Tonos Puros , Diseño de Equipo , Células Ciliadas Auditivas Externas/fisiología , Ruido/efectos adversos , Ratas , Ratas WistarRESUMEN
Introducción y objetivo: Empleando la instrumentación adecuada, venimos constatando que los microfónicos cocleares (MC) evocados adelantan o retrasan su aparición en función de la presión sonora que los genera. Esta variación en el tiempo es del orden de microsegundos. No hemos encontrado referencia alguna de este comportamiento, razón por la cual damos conocer el hallazgo. Material y método: Se emplea instrumentación específica para el estudio de los MC. El método se basa en el desplazamiento de fase de los MC en función de la intensidad del estímulo. Resultados: Se constata la latencia en los MC y se observa que la misma disminuye a medida que se incrementa la intensidad del estímulo. Conclusiones: Desde el estímulo sonoro a la traducción en potencial bioeléctrico encontramos un periodo de tiempo en microsegundos, menor a mayor potencia. Esto sugiere que traducción mecano-eléctrica no es un simple proceso de naturaleza mecánica (AU)
Introduction and objective: By using appropriate instrumentation, we have found that cochlear microphonics (CM) advance or delay their appearance, depending on the sound pressure that generates them. This time variation is on the order of microseconds. We have not found any reference to this behaviour, which is why we make the finding known. Material and method: We used the standard instrumentation specified for the study of CM. The method was based on the phase shift function of the CM according to the intensity of the stimulus. Results: Latency was observed in CM, and we determined that latency time diminishes as the intensity of the stimulus increases. Conclusions: From the sound stimulus to the bioelectric potential transduction, there is a time period of microseconds, the shorter the more powerful the stimulus. This suggests that electromechanical transduction is not a simple mechanical process (AU)
Asunto(s)
Humanos , Potenciales Microfónicos de la Cóclea , Células Ciliadas Auditivas/fisiología , Mecanotransducción Celular/fisiología , Tiempo de Reacción/fisiología , Oído Interno/fisiologíaRESUMEN
INTRODUCTION AND OBJECTIVE: By using appropriate instrumentation, we have found that cochlear microphonics (CM) advance or delay their appearance, depending on the sound pressure that generates them. This time variation is on the order of microseconds. We have not found any reference to this behaviour, which is why we make the finding known. MATERIAL AND METHOD: We used the standard instrumentation specified for the study of CM. The method was based on the phase shift function of the CM according to the intensity of the stimulus. RESULTS: Latency was observed in CM, and we determined that latency time diminishes as the intensity of the stimulus increases. CONCLUSIONS: From the sound stimulus to the bioelectric potential transduction, there is a time period of microseconds, the shorter the more powerful the stimulus. This suggests that electromechanical transduction is not a simple mechanical process.