Mechanisms and Mitigation of Hearing Loss from Blast Injury

Studies have been performed aimed at an improved biomechanical understanding of blast injury with the goal of creating new technologies for the mitigation of auditory injury from blast. Fiber-optic pressure sensors were used to measure and correlate external auditory canal (EAC) and intracranial pre...

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1. Verfasser:	Easter, James R
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Sprache:	eng
Schlagworte:	ACOUSTIC TRAUMA Anatomy and Physiology AUDITORY HAZARD MODELS AUDITORY INJURIES BIOMECHANICS BLAST BLAST INJURIES BLAST WAVES EAC(EXTERNAL AUDITORY CANAL) EAR PROTECTORS ELECTROMECHANICAL DEVICES FIBER OPTICS FIBER-OPTIC PRESSURE SENSORS Fluid Mechanics HEARING HEARING PROTECTION Medicine and Medical Research OSSICULAR VELOCITY PRESSURE PRESSURE MEASUREMENT SHOCK TUBES SIMULATION TRAUMA WOUNDS AND INJURIES
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creator	Easter, James R
description	Studies have been performed aimed at an improved biomechanical understanding of blast injury with the goal of creating new technologies for the mitigation of auditory injury from blast. Fiber-optic pressure sensors were used to measure and correlate external auditory canal (EAC) and intracranial pressure profiles during blast events. A compact programmable bench top simulator system was used to recreate recorded blast pressure profiles and deliver simulated blast wave forms at high intensity to human temporal bones. Intra-cochlear pressures were measured during harmonic and impulse stimuli using off-the-shelf fiber-optic pressure probes. Intra-cochlear pressures and ossicular displacements were recorded simultaneously and compared with those predicted by an existing auditory injury model. Stapedial displacements as measured both by scanning and single axis LDV were found to exceed predicted values for extremely high pressure sand long durations characteristic of blast events. An electromechanical transducer was used to counteract ossicular movement resulting from harmonic and impulse stimuli, demonstrating feasibility of active mitigation of auditory injury from blast exposure. Future activities will be directed to improved auditory hazard models and development of active systems protective against blast injury. The original document contains color images.
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Fiber-optic pressure sensors were used to measure and correlate external auditory canal (EAC) and intracranial pressure profiles during blast events. A compact programmable bench top simulator system was used to recreate recorded blast pressure profiles and deliver simulated blast wave forms at high intensity to human temporal bones. Intra-cochlear pressures were measured during harmonic and impulse stimuli using off-the-shelf fiber-optic pressure probes. Intra-cochlear pressures and ossicular displacements were recorded simultaneously and compared with those predicted by an existing auditory injury model. Stapedial displacements as measured both by scanning and single axis LDV were found to exceed predicted values for extremely high pressure sand long durations characteristic of blast events. An electromechanical transducer was used to counteract ossicular movement resulting from harmonic and impulse stimuli, demonstrating feasibility of active mitigation of auditory injury from blast exposure. Future activities will be directed to improved auditory hazard models and development of active systems protective against blast injury. The original document contains color images.</description><language>eng</language><subject>ACOUSTIC TRAUMA ; Anatomy and Physiology ; AUDITORY HAZARD MODELS ; AUDITORY INJURIES ; BIOMECHANICS ; BLAST ; BLAST INJURIES ; BLAST WAVES ; EAC(EXTERNAL AUDITORY CANAL) ; EAR PROTECTORS ; ELECTROMECHANICAL DEVICES ; FIBER OPTICS ; FIBER-OPTIC PRESSURE SENSORS ; Fluid Mechanics ; HEARING ; HEARING PROTECTION ; Medicine and Medical Research ; OSSICULAR VELOCITY ; PRESSURE ; PRESSURE MEASUREMENT ; SHOCK TUBES ; SIMULATION ; TRAUMA ; WOUNDS AND INJURIES</subject><creationdate>2012</creationdate><rights>Approved for public release; distribution is unlimited.</rights><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><link.rule.ids>230,776,881,27544,27545</link.rule.ids><linktorsrc>$$Uhttps://apps.dtic.mil/sti/citations/ADA612598$$EView_record_in_DTIC$$FView_record_in_$$GDTIC$$Hfree_for_read</linktorsrc></links><search><creatorcontrib>Easter, James R</creatorcontrib><creatorcontrib>COCHLEAR BOULDER LLC CO</creatorcontrib><title>Mechanisms and Mitigation of Hearing Loss from Blast Injury</title><description>Studies have been performed aimed at an improved biomechanical understanding of blast injury with the goal of creating new technologies for the mitigation of auditory injury from blast. Fiber-optic pressure sensors were used to measure and correlate external auditory canal (EAC) and intracranial pressure profiles during blast events. A compact programmable bench top simulator system was used to recreate recorded blast pressure profiles and deliver simulated blast wave forms at high intensity to human temporal bones. Intra-cochlear pressures were measured during harmonic and impulse stimuli using off-the-shelf fiber-optic pressure probes. Intra-cochlear pressures and ossicular displacements were recorded simultaneously and compared with those predicted by an existing auditory injury model. Stapedial displacements as measured both by scanning and single axis LDV were found to exceed predicted values for extremely high pressure sand long durations characteristic of blast events. An electromechanical transducer was used to counteract ossicular movement resulting from harmonic and impulse stimuli, demonstrating feasibility of active mitigation of auditory injury from blast exposure. Future activities will be directed to improved auditory hazard models and development of active systems protective against blast injury. The original document contains color images.</description><subject>ACOUSTIC TRAUMA</subject><subject>Anatomy and Physiology</subject><subject>AUDITORY HAZARD MODELS</subject><subject>AUDITORY INJURIES</subject><subject>BIOMECHANICS</subject><subject>BLAST</subject><subject>BLAST INJURIES</subject><subject>BLAST WAVES</subject><subject>EAC(EXTERNAL AUDITORY CANAL)</subject><subject>EAR PROTECTORS</subject><subject>ELECTROMECHANICAL DEVICES</subject><subject>FIBER OPTICS</subject><subject>FIBER-OPTIC PRESSURE SENSORS</subject><subject>Fluid Mechanics</subject><subject>HEARING</subject><subject>HEARING PROTECTION</subject><subject>Medicine and Medical Research</subject><subject>OSSICULAR VELOCITY</subject><subject>PRESSURE</subject><subject>PRESSURE MEASUREMENT</subject><subject>SHOCK TUBES</subject><subject>SIMULATION</subject><subject>TRAUMA</subject><subject>WOUNDS AND INJURIES</subject><fulltext>true</fulltext><rsrctype>report</rsrctype><creationdate>2012</creationdate><recordtype>report</recordtype><sourceid>1RU</sourceid><recordid>eNrjZLD2TU3OSMzLLM4tVkjMS1HwzSzJTE8syczPU8hPU_BITSzKzEtX8MkvLlZIK8rPVXDKSSwuUfDMyyotquRhYE1LzClO5YXS3Awybq4hzh66KSWZyfHFJZl5qSXxji6OZoZGppYWxgSkAZz4LAs</recordid><startdate>201210</startdate><enddate>201210</enddate><creator>Easter, James R</creator><scope>1RU</scope><scope>BHM</scope></search><sort><creationdate>201210</creationdate><title>Mechanisms and Mitigation of Hearing Loss from Blast Injury</title><author>Easter, James R</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-dtic_stinet_ADA6125983</frbrgroupid><rsrctype>reports</rsrctype><prefilter>reports</prefilter><language>eng</language><creationdate>2012</creationdate><topic>ACOUSTIC TRAUMA</topic><topic>Anatomy and Physiology</topic><topic>AUDITORY HAZARD MODELS</topic><topic>AUDITORY INJURIES</topic><topic>BIOMECHANICS</topic><topic>BLAST</topic><topic>BLAST INJURIES</topic><topic>BLAST WAVES</topic><topic>EAC(EXTERNAL AUDITORY CANAL)</topic><topic>EAR PROTECTORS</topic><topic>ELECTROMECHANICAL DEVICES</topic><topic>FIBER OPTICS</topic><topic>FIBER-OPTIC PRESSURE SENSORS</topic><topic>Fluid Mechanics</topic><topic>HEARING</topic><topic>HEARING PROTECTION</topic><topic>Medicine and Medical Research</topic><topic>OSSICULAR VELOCITY</topic><topic>PRESSURE</topic><topic>PRESSURE MEASUREMENT</topic><topic>SHOCK TUBES</topic><topic>SIMULATION</topic><topic>TRAUMA</topic><topic>WOUNDS AND INJURIES</topic><toplevel>online_resources</toplevel><creatorcontrib>Easter, James R</creatorcontrib><creatorcontrib>COCHLEAR BOULDER LLC CO</creatorcontrib><collection>DTIC Technical Reports</collection><collection>DTIC STINET</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Easter, James R</au><aucorp>COCHLEAR BOULDER LLC CO</aucorp><format>book</format><genre>unknown</genre><ristype>RPRT</ristype><btitle>Mechanisms and Mitigation of Hearing Loss from Blast Injury</btitle><date>2012-10</date><risdate>2012</risdate><abstract>Studies have been performed aimed at an improved biomechanical understanding of blast injury with the goal of creating new technologies for the mitigation of auditory injury from blast. Fiber-optic pressure sensors were used to measure and correlate external auditory canal (EAC) and intracranial pressure profiles during blast events. A compact programmable bench top simulator system was used to recreate recorded blast pressure profiles and deliver simulated blast wave forms at high intensity to human temporal bones. Intra-cochlear pressures were measured during harmonic and impulse stimuli using off-the-shelf fiber-optic pressure probes. Intra-cochlear pressures and ossicular displacements were recorded simultaneously and compared with those predicted by an existing auditory injury model. Stapedial displacements as measured both by scanning and single axis LDV were found to exceed predicted values for extremely high pressure sand long durations characteristic of blast events. An electromechanical transducer was used to counteract ossicular movement resulting from harmonic and impulse stimuli, demonstrating feasibility of active mitigation of auditory injury from blast exposure. Future activities will be directed to improved auditory hazard models and development of active systems protective against blast injury. The original document contains color images.</abstract><oa>free_for_read</oa></addata></record>
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subjects	ACOUSTIC TRAUMA Anatomy and Physiology AUDITORY HAZARD MODELS AUDITORY INJURIES BIOMECHANICS BLAST BLAST INJURIES BLAST WAVES EAC(EXTERNAL AUDITORY CANAL) EAR PROTECTORS ELECTROMECHANICAL DEVICES FIBER OPTICS FIBER-OPTIC PRESSURE SENSORS Fluid Mechanics HEARING HEARING PROTECTION Medicine and Medical Research OSSICULAR VELOCITY PRESSURE PRESSURE MEASUREMENT SHOCK TUBES SIMULATION TRAUMA WOUNDS AND INJURIES
title	Mechanisms and Mitigation of Hearing Loss from Blast Injury
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