Σάββατο 16 Δεκεμβρίου 2017

Treatment For Ringing In Ears

For tinnitus sufferers, the constant ringing in the ears can be life-altering. Buzzing, hissing, and other sounds that only they hear can play havoc with daily living, as well as keeping a job and other aspects of life that many people take for granted. However, despite the frustration that comes with this condition, the good news is that there are many types of treatment for ringing in ears. To learn more about how to alleviate the problems associated with tinnitus, here are some treatments you may want to try.

Avoid Triggers
For some individuals, certain foods and drinks may make tinnitus worse. As an easy treatment for ringing in ears, it may be best to avoid such triggers as:
–Salty foods
–Alcoholic drinks
–Aspirin
–Caffeinated drinks such as coffee, energy drinks, or tea
Since everyone is not affected by the same triggers, keeping a written log of any foods or drinks that bother you may provide clues as to how to feel better.

White-Noise Machine
A very popular treatment for ringing in ears, white-noise machines offer relief for many tinnitus sufferers. Able to simulate sounds of streams, oceans, rainfall, and other relaxing sounds, the machines can be purchased for as little as $50 and can easily be connected to computers and other mobile devices.

Exercise
Along with being good in many other ways, a regular exercise program can also help ease the problems associated with tinnitus. Some of the most popular exercises known to help tinnitus sufferers include yoga, tai-chi, and running. If you plan to try yoga or tai-chi, adding some soft background music may ease symptoms and improve your concentration.

Use Ear Protection
For many people, loud noise is a common cause of tinnitus. Because of this, it’s a good idea to always use ear protection in situations where you may be exposed to loud noises. For example, use ear plugs if you’re planning to attend a concert, or if you will be mowing grass, using power tools, or leaf blowers. And if you work in a noisy environment, use ear plugs as well. By protecting your hearing, it’s possible your tinnitus symptoms will ease or even disappear for a period of time.

No matter what type of treatment for ringing in ears you choose, it’s quite possible to have your tinnitus improve dramatically. By never giving up hope and always being willing to try new treatments, chances are good you will find one that works best for you.



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No effect of prolonged pulsed high frequency ultrasound imaging of the basilar membrane on cochlear function or hair cell survival found in an initial study

S03785955.gif

Publication date: Available online 16 December 2017
Source:Hearing Research
Author(s): Thomas G. Landry, Manohar L. Bance, Robert B. Adamson, Jeremy A. Brown
Miniature high frequency ultrasound devices show promise as tools for clinical middle ear and basal cochlea imaging and vibrometry. However, before clinical use it is important to verify that the ultrasound exposure does not damage the cochlea. In this initial study, electrophysiological responses of the cochlea were measured for a range of stimulus frequencies in both ears of anesthetized chinchillas, before and after exposing the organ of Corti region of one ear to pulsed focused ultrasound for 30 min. Measurements were again taken after an 11 day survival period. Cochlear tissue was examined with a confocal microscope for signs of damage to the cochlear hair cells. No significant change in response thresholds due to exposure was found, and no signs of ultrasound-induced tissue damage were observed, although one animal (out of ten) did have a region of extensive tissue damage in the exposed cochlea. However, after further analysis this was concluded to be not likely a result of the ultrasound exposure.



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No effect of prolonged pulsed high frequency ultrasound imaging of the basilar membrane on cochlear function or hair cell survival found in an initial study

Publication date: Available online 16 December 2017
Source:Hearing Research
Author(s): Thomas G. Landry, Manohar L. Bance, Robert B. Adamson, Jeremy A. Brown
Miniature high frequency ultrasound devices show promise as tools for clinical middle ear and basal cochlea imaging and vibrometry. However, before clinical use it is important to verify that the ultrasound exposure does not damage the cochlea. In this initial study, electrophysiological responses of the cochlea were measured for a range of stimulus frequencies in both ears of anesthetized chinchillas, before and after exposing the organ of Corti region of one ear to pulsed focused ultrasound for 30 min. Measurements were again taken after an 11 day survival period. Cochlear tissue was examined with a confocal microscope for signs of damage to the cochlear hair cells. No significant change in response thresholds due to exposure was found, and no signs of ultrasound-induced tissue damage were observed, although one animal (out of ten) did have a region of extensive tissue damage in the exposed cochlea. However, after further analysis this was concluded to be not likely a result of the ultrasound exposure.



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No effect of prolonged pulsed high frequency ultrasound imaging of the basilar membrane on cochlear function or hair cell survival found in an initial study

S03785955.gif

Publication date: Available online 16 December 2017
Source:Hearing Research
Author(s): Thomas G. Landry, Manohar L. Bance, Robert B. Adamson, Jeremy A. Brown
Miniature high frequency ultrasound devices show promise as tools for clinical middle ear and basal cochlea imaging and vibrometry. However, before clinical use it is important to verify that the ultrasound exposure does not damage the cochlea. In this initial study, electrophysiological responses of the cochlea were measured for a range of stimulus frequencies in both ears of anesthetized chinchillas, before and after exposing the organ of Corti region of one ear to pulsed focused ultrasound for 30 min. Measurements were again taken after an 11 day survival period. Cochlear tissue was examined with a confocal microscope for signs of damage to the cochlear hair cells. No significant change in response thresholds due to exposure was found, and no signs of ultrasound-induced tissue damage were observed, although one animal (out of ten) did have a region of extensive tissue damage in the exposed cochlea. However, after further analysis this was concluded to be not likely a result of the ultrasound exposure.



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No effect of prolonged pulsed high frequency ultrasound imaging of the basilar membrane on cochlear function or hair cell survival found in an initial study

Publication date: Available online 16 December 2017
Source:Hearing Research
Author(s): Thomas G. Landry, Manohar L. Bance, Robert B. Adamson, Jeremy A. Brown
Miniature high frequency ultrasound devices show promise as tools for clinical middle ear and basal cochlea imaging and vibrometry. However, before clinical use it is important to verify that the ultrasound exposure does not damage the cochlea. In this initial study, electrophysiological responses of the cochlea were measured for a range of stimulus frequencies in both ears of anesthetized chinchillas, before and after exposing the organ of Corti region of one ear to pulsed focused ultrasound for 30 min. Measurements were again taken after an 11 day survival period. Cochlear tissue was examined with a confocal microscope for signs of damage to the cochlear hair cells. No significant change in response thresholds due to exposure was found, and no signs of ultrasound-induced tissue damage were observed, although one animal (out of ten) did have a region of extensive tissue damage in the exposed cochlea. However, after further analysis this was concluded to be not likely a result of the ultrasound exposure.



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No effect of prolonged pulsed high frequency ultrasound imaging of the basilar membrane on cochlear function or hair cell survival found in an initial study

S03785955.gif

Publication date: Available online 16 December 2017
Source:Hearing Research
Author(s): Thomas G. Landry, Manohar L. Bance, Robert B. Adamson, Jeremy A. Brown
Miniature high frequency ultrasound devices show promise as tools for clinical middle ear and basal cochlea imaging and vibrometry. However, before clinical use it is important to verify that the ultrasound exposure does not damage the cochlea. In this initial study, electrophysiological responses of the cochlea were measured for a range of stimulus frequencies in both ears of anesthetized chinchillas, before and after exposing the organ of Corti region of one ear to pulsed focused ultrasound for 30 min. Measurements were again taken after an 11 day survival period. Cochlear tissue was examined with a confocal microscope for signs of damage to the cochlear hair cells. No significant change in response thresholds due to exposure was found, and no signs of ultrasound-induced tissue damage were observed, although one animal (out of ten) did have a region of extensive tissue damage in the exposed cochlea. However, after further analysis this was concluded to be not likely a result of the ultrasound exposure.



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Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Related Articles

Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Int J Audiol. 2017 Dec 14;:1-8

Authors: Mackey AR, Hodgetts WE, Small SA

Abstract
OBJECTIVE: Although it is understood that bone-conduction (BC) hearing is different between infants and adults, few studies have attempted to explain why these differences exist. The main objective in this study was to better understand how properties of the developing skull contribute to the maturation of BC sensitivity through an indirect measurement of BC attenuation across the skull.
DESIGN: Estimation of transcranial and forehead attenuation of pure-tone BC stimuli was conducted using sound pressure in the ear canal for a transducer placed on the skull ipsi- and contralateral to the probe ear and at the forehead.
STUDY SAMPLE: Seventy-six individuals participated in the study, including 59 infants and children (1 month-7 years) and 17 adults.
RESULTS: BC attenuation was greatest for young infants, and decreased throughout maturation. Attenuation from the forehead to the ipsilateral temporal bone was also greater compared to the transcranial measures for infants and children older than 10 months.
CONCLUSIONS: These results provide evidence that physical maturation of the skull contributes to infant-adult differences in BC attenuation. Clinicians may consider these results, in combination with previous studies using physiological measures, when fitting infants and young children with bone-anchored hearing systems.

PMID: 29241372 [PubMed - as supplied by publisher]



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Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Related Articles

Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Int J Audiol. 2017 Dec 14;:1-8

Authors: Mackey AR, Hodgetts WE, Small SA

Abstract
OBJECTIVE: Although it is understood that bone-conduction (BC) hearing is different between infants and adults, few studies have attempted to explain why these differences exist. The main objective in this study was to better understand how properties of the developing skull contribute to the maturation of BC sensitivity through an indirect measurement of BC attenuation across the skull.
DESIGN: Estimation of transcranial and forehead attenuation of pure-tone BC stimuli was conducted using sound pressure in the ear canal for a transducer placed on the skull ipsi- and contralateral to the probe ear and at the forehead.
STUDY SAMPLE: Seventy-six individuals participated in the study, including 59 infants and children (1 month-7 years) and 17 adults.
RESULTS: BC attenuation was greatest for young infants, and decreased throughout maturation. Attenuation from the forehead to the ipsilateral temporal bone was also greater compared to the transcranial measures for infants and children older than 10 months.
CONCLUSIONS: These results provide evidence that physical maturation of the skull contributes to infant-adult differences in BC attenuation. Clinicians may consider these results, in combination with previous studies using physiological measures, when fitting infants and young children with bone-anchored hearing systems.

PMID: 29241372 [PubMed - as supplied by publisher]



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via IFTTT

Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Related Articles

Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Int J Audiol. 2017 Dec 14;:1-8

Authors: Mackey AR, Hodgetts WE, Small SA

Abstract
OBJECTIVE: Although it is understood that bone-conduction (BC) hearing is different between infants and adults, few studies have attempted to explain why these differences exist. The main objective in this study was to better understand how properties of the developing skull contribute to the maturation of BC sensitivity through an indirect measurement of BC attenuation across the skull.
DESIGN: Estimation of transcranial and forehead attenuation of pure-tone BC stimuli was conducted using sound pressure in the ear canal for a transducer placed on the skull ipsi- and contralateral to the probe ear and at the forehead.
STUDY SAMPLE: Seventy-six individuals participated in the study, including 59 infants and children (1 month-7 years) and 17 adults.
RESULTS: BC attenuation was greatest for young infants, and decreased throughout maturation. Attenuation from the forehead to the ipsilateral temporal bone was also greater compared to the transcranial measures for infants and children older than 10 months.
CONCLUSIONS: These results provide evidence that physical maturation of the skull contributes to infant-adult differences in BC attenuation. Clinicians may consider these results, in combination with previous studies using physiological measures, when fitting infants and young children with bone-anchored hearing systems.

PMID: 29241372 [PubMed - as supplied by publisher]



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via IFTTT

Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Related Articles

Maturation of bone-conduction transcranial and forehead attenuation using a measure of sound pressure in the ear canal.

Int J Audiol. 2017 Dec 14;:1-8

Authors: Mackey AR, Hodgetts WE, Small SA

Abstract
OBJECTIVE: Although it is understood that bone-conduction (BC) hearing is different between infants and adults, few studies have attempted to explain why these differences exist. The main objective in this study was to better understand how properties of the developing skull contribute to the maturation of BC sensitivity through an indirect measurement of BC attenuation across the skull.
DESIGN: Estimation of transcranial and forehead attenuation of pure-tone BC stimuli was conducted using sound pressure in the ear canal for a transducer placed on the skull ipsi- and contralateral to the probe ear and at the forehead.
STUDY SAMPLE: Seventy-six individuals participated in the study, including 59 infants and children (1 month-7 years) and 17 adults.
RESULTS: BC attenuation was greatest for young infants, and decreased throughout maturation. Attenuation from the forehead to the ipsilateral temporal bone was also greater compared to the transcranial measures for infants and children older than 10 months.
CONCLUSIONS: These results provide evidence that physical maturation of the skull contributes to infant-adult differences in BC attenuation. Clinicians may consider these results, in combination with previous studies using physiological measures, when fitting infants and young children with bone-anchored hearing systems.

PMID: 29241372 [PubMed - as supplied by publisher]



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