Intrinsic performance limits of noncontacting fiber lever displacement measuring systems are quantitatively described. Generalized relationships linking displacement detection limit, frequency response, dynamic range, linearity, and working distance to fiber diameter, illumination irradiance and coupling angle, photodetector characteristics, and reflection and transmission losses were obtained by analysis and confirmed by measurement. Both procedures showed performance limits to be functions of the square root of the flux density coupled into the target-illuminating fiber(s) by the electroluminescent source. Displacement detection and bandwidth limits achievable with tungsten or LED sources were in the 2 x 10(-11) to 2 x 10(-12) [equation] and MHz, range respectively. A basis for optimizing levers for different applications and determination of intrinsic performance limits is provided.
Two‐day (Group A), eight‐day (Group B), and eight‐month (Group C) old guinea pigs were exposed to 30 continuous hours of white noise at 119–120 db SPL. One month later pathology of the organ of Corti was evaluated and quantitated by use of the surface preparation technique. Percent cell damage was determined for outer hair, inner hair, outer pillar, and inner pillar cells at each of the four turns of the cochlea and for the cochlea as a whole. Comparisons of pathology of each cell type were made between groups. Mean percent outer hair cell damage per cochlea (± 1 S.E.) was 23.72 ± 3.69 for Group A, 36.98 ± 5.76 for Group B, and 7.24 ± 1.75 for Group C. There was no significant difference in outer hair cell damage between Groups A and B. Outer hair cells of Group A were significantly more damaged than those of Group C when damage in the cochlea as a whole was considered due to significantly greater damage in Group A at three and one half turns; likewise, outer hair cells of Group B were significantly more damaged than those of Group C when damage in the cochlea as a whole was considered due to significantly greater damage in Group B at two and one half and at three and one half turns. A similar effect was observed in terms of pathology of inner hair cells and pillar cells: there was a trend toward increased damage in animals of Groups A and B compared with C. Group C showed no outer or inner pillar cell damage, and only one of six animals had alterations in inner hair cells. In contrast, outer and inner pillar cells were damaged in Groups A and B, and four of six animals of Group A and six of eight of Group B showed inner hair cell damage. Recent electrophysiological and audiometric studies are discussed which, with the results of the present study, indicate greater susceptibility of young cochleas when compared with older cochleas, to noise‐induced physiological and pathological alterations. It would seem medically prudent to take special precautions to avoid exposing newborns to excessive noise.
Pregnant guinea pigs were exposed to loom room noise at 115 dB A for 7.5 hr/day for various periods during the last one-third of pregnancy. When the hearing of their offspring was tested by auditory brain stem-evoked response techniques at 6-dB intervals, peak IV latencies of exposed pups were found to be significantly longer than those of otherwise similar control pups. The latency differences corresponded to a 5-dB increase in stimulus at medium stimulus levels and 10-12 dB near threshold. The results indicate that it is possible for noise-induced loss to occur in utero in mammals whose auditory maturation process is complete, or nearly so, before birth.
Different noise exposure paradigms were studied to determine their teratogenic and embryo-fetotoxic potential in the CF-1 mouse. Female mice were exposed from days 1-6 or from days 6-15 of gestation to one of three noise exposure paradigms which differed widely in level, spectral, and temporal characteristics. Paradigms for noise exposure were chosen to represent semi-continuous exposure to extremely high-intensity noise (jet engine noise at 126 dBA, from noon to midnight); to represent startling type noise composed of alarm bells, jet engine noise, or narrow band warning devices at 110 dBA, with pseudorandom onset and duration of each controlled by a microprocessor (exposure time of 18% over each 24 hour period); and finally to represent very high frequency noise (18-20 kHz tones, derived from a device commercially marketed for repelling rodents, with exposure from noon to midnight). On day 18 of gestation the females were sacrificed, their reproduction status determined, and the concepti were examined for toxicity and for external, visceral, and skeletal alterations. Maternal plasma corticosterone levels were measured at different periods of gestation. Significantly decreased pregnancy rate was noted in all groups exposed to noise except in the group exposed to the very high frequency noise from days 6-15 of gestation. Significant embryolethal effects occurred in the group exposed to the extremely high intensity jet noise paradigm, from days 1-6 of gestation, and significant fetolethal effects occurred in the group exposed to the very high frequency noise paradigm from days 6-15 of gestation. No significant noise-related changes were noted in the incidence of structural alterations or in the concentration of plasma corticosterone.
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