听觉声损伤与耳蜗鼓阶淋巴氧分压的关系

本实验运用极谱式氧电极研究了噪声暴露对耳蜗鼓阶淋巴氧分压（ＳＴＰＯ２）的影响以及ＳＴＰＯ２的变化与听觉电生理、毛细胞损伤之间的关系。结果表明：（１）８５ｄＢＳＰＬ以上声刺激时ＳＴＰＯ２迅速降低;８５ｄＢＳＰＬ窄带噪声暴露时ＳＴＰ０２与血压一同缓慢增高;低于８５ｄＢＳＰＬ的声刺激则未能引起ＳＴＰ０２和血压的改变。（２）ＳＴＰＯ２降低约２０％即伴随明显的听损伤;ＳＴＰＯ２的变化程度与声暴露量（ｒ＝０．９７,Ｐ＜０．０５）、听力损失（ｒ＝０．８２,Ｐ＜０．０５）呈相关;与耳蜗病理改变也有一定关系,但与血压无明显相关性（ｒ＝０．２１,Ｐ＞０．２）。（３）声暴露时,吸入碳氧混合气对听力损失具有部分保护作用。     

强噪声暴露后听觉脑干电反应及皮层电反应的变化

为了观察噪声作用豚鼠后,在暂时性或移和永久性阈移期间,听觉末梢和听觉各级中枢电反庆的变化规律,我们进行了６２ｄ的测定。听神经电反应振幅减小２９％（Ｐ＜０．０５）,耳蜗核电反应振幅减小２８％（Ｐ＜０．０５）,上橄榄核电反应反而增加２１％（Ｐ＜０．０５）,中脑下丘的电反应振幅进而增大３７％（Ｐ＜０．０５）,听觉皮层电反应振幅却意外地增加１３１％（Ｐ＜０．００１）。这说明强噪声（１２５ｄＢ １５０ｍｉｎ     

诱发性耳声发射的掩蔽

３４例听觉正常受试者（共４８耳）进行疏波短声诱发性耳声发射（ＥＯＡＥ）掩蔽实验,项目包括同侧同时掩蔽、同侧后掩蔽和对倒后掩蔽。同时掩蔽的掩蔽声是稳态白噪声,后掩蔽的掩蔽声是宽带噪声。同侧同时掩蔽强度达３０ｄＢＳＬ时,未观察到对ＥＯＡＥ的掩蔽效应,但对主观听觉感受有掩蔽作用,表明ＥＯＡＥ的客观属性反映听觉行为有其局限性、同侧及对侧后掩蔽出现掩蔽效应时的掩蔽强度分别为３０和５０ｄＢＳＬ,掩蔽阈约分别为５９和６８ｄＢＳＬ。耳蜗的机械特性－非线性或耳蜗内存在的某种功能性的反馈调节系统可能是同侧后掩蔽的作用机理。下行的对侧橄榄耳蜗内侧束对外毛细胞主动收缩的抑制性作用,可有效解释对倒后掩蔽的ＥＯＡＥ变化。     

白噪声对听觉脑干电反应(ABR)和耳蜗电图(ECochG)的影响

本文通过20例听力正常人和10例听力正常豚鼠研究了白噪声对耳蜗电图(ECochG)和听觉脑干电反应(ABR)的干涉作用。实验结果表明,白噪声比短声(信号)的声强级低30dB(SL)以上时,ECochG和ABR的振幅仅轻微减小。白噪声与短声的声强级相等时,ECochG与ABR的振幅和出现率会明显受到干涉而减小,甚至完全消失。但是,此时的耳蜗微音器电位(CM)并未观察到有明显的变化。这意味着白噪声对ECochG和ABR的干涉作用主要与围绕毛细胞基底部的突触产生的抑制密切相关。由于白噪声对ABR各波的干涉有些差异,所以认为这种抑制,可能既包括脑中抑制也包括侧方抑制。     

提高外淋巴钙浓度对耳蜗电位的影响

本实验以人工外淋巴灌流方式,提高豚鼠耳蜗外淋巴液钙离子浓度（［Ｃａ２＋］ＰＬ）,观察蜗内直流电位（ＥＰ）和耳蜗电图（ＥＣｏｃｈＧ）的变化,ＥＣｏｃｈＧ包括听神经复合动作电位（ＣＡＰ）、耳蜗微音电位（ＣＭ）。结果可见：高钙灌流明显抑制ＣＡＰ幅值,延长同一声强下（９０ｄＢＳＰＬ）Ｎ１－峰潜伏期,但不改变ＣＭ的幅值及总和ＥＰ（Ｇ－ＥＰ）。高钙灌流降低了ＥＰ对噪声的给－撤声反应（ＥＰ－ＯＮ,ＥＰ－ＯＦＦ）和缺氧所得到的最大负ＥＰ（Ｎ－ＥＰ）绝对值。本文分析了外淋巴高钙影响耳蜗电位的可能机制。     

脓毒血症大鼠心肌II型磷脂酶A_2活性变化及其调控

观察了脓毒血症大鼠心肌ＩＩ型ＰＬＡ２ 活性、蛋白质含量及其ｍ ＲＮＡ 的变化。结果发现, 脓毒血症早期与晚期心肌ＩＩ型ＰＬＡ２ 活性较对照组分别降低２５ ．０ ％ （Ｐ ＜ ０ ．０５）及增高４７．６ ％ （Ｐ ＜ ０ ．０１）,ＩＩ型ＰＬＡ２ 蛋白质含量分别降低２７．０％ 及增高４８ ．０ ％（ 均Ｐ ＜ ０ ．０１）; 心肌ＩＩ型ＰＬＡ２ ｍ ＲＮＡ合成率与含量呈现类似的双相变化, 在脓毒血症早、晚期ｍＲＮＡ 合成率分别降低４５．０％ 和升高７０．０ ％ （均Ｐ ＜ ０ ．０１）,ｍＲＮＡ含量分别降低３４．１ ％ 和增加１５７ ．０％ （均Ｐ＜ ０ ．０１） 。脓毒血症早、晚期心脏ＩＩ型ＰＬＡ２ ｍ ＲＮＡ半衰期无显著变化（Ｐ ＞ ０．０５） 。实验结果表明大鼠脓毒血症发生过程中心肌ＩＩ型ＰＬＡ２ 活性呈现出先下降后升高的变化, 这一变化受其ｍＲＮＡ 转录水平的调节。     

天花粉蛋白Glu160在N-糖苷酶活性中的作用

用浸泡法得到了（Ｅ１６０Ａ）天花粉蛋白（ｔｒｉｃｈｏｓａｎｔｈｉｎ, ＴＣＳ）,（Ｅ１６０Ｄ）ＴＣＳ与Ａｄｅ 和（Ｅ１６０Ａ）ＴＣＳ与ＦＭＰ复合物的晶体．在Ｍａｒ Ｒｅｓｅａｒｃｈ 面探测器系统上分别收集了０．２０ ｎｍ ,０．１９ｎｍ 和０．２０５ ｎｍ 分辨率的Ｘ 射线衍射数据,数据处理用Ｍａｒ Ｓｃａｌｅ 程序系统完成．用同晶差值Ｆｏｕｒｉｅｒ法解析了（Ｅ１６０Ａ）ＴＣＳ－Ａｄｅ,（Ｅ１６０Ｄ）ＴＣＳ－Ａｄｅ 和（Ｅ１６０Ａ）ＴＣＳ－ＦＭＰ的晶体结构,结构修正利用Ｘ－ＰＬＯＲ程序,修正结果,晶体学Ｒ因子分别为０．１６６,０．１７６,０．１７９．键长和键角的ＲＭＳ偏差分别为０．００１０ ｎｍ 和２．５０３°,０．００１３ ｎｍ 和２．６６５°,０．００１２ ｎｍ 和２．６７６°．在这三个结构中均未见到Ｇｌｕ１８９侧链方向的改变．Ａｄｅ 或ＦＭＰ仍结合在Ｎ－糖苷酶活性口袋之中,它夹在Ｔｙｒ７０和Ｔｙｒ１１１两个侧链环之间,与Ｔｙｒ７０环近乎平行．这一结果表明：ＴＣＳ中的Ｇｌｕ１６０分别突变成Ａｌａ 和Ａｓｐ,仍能与ＡＭＰ发生Ｎ－糖苷酶反应,但是活性降低了一些．可见Ｇｌｕ１６０对ＴＣＳ与ＡＭＰ的作用是重要的,但不是必要的．     

脓毒血症大鼠心肌Ⅱ型磷脂酶A2活性变化及其调控

观察了脓毒血症大鼠心肌ＩＩ型ＰＬＡ２活性,蛋白质含量及其ｍＲＮＡ的变化,结果发现,脓毒血症早期为晚期心肌ＩＩ型ＰＬＡ２活性较对照组分别降低２５．０％（Ｐ〈０．０５）及增高４７．６％（Ｐ〈０．０１）,ＩＩ型ＰＬＡ２蛋白质含量分别降低了２７．０％及增高４８．０％（均Ｐ〈０．０１）,心肌ＩＩ型ＰＬＡ２ｍＲＮＡ合成率与含量呈现类似的双相变化,在脓毒血症早,晚期ｍＲＮＡ合成率分别降低４５．０％和升高７０．０     

强声对豚鼠动作电位（N_1）潜伏期的影响及永久性阈移（PTS）早期预测指标分析

用慢性面神经管长期置入电极方法,测试了不同时间,不同强度的白噪声或２．８３ＫＨｚ强纯音暴露下清醒豚鼠的ＡＰ（Ｎ１）潜伏期。结果发现,暴露后对短声及各频率短纯音反应的ＡＰ（Ｎ１）潜伏期均出现统计学意义的延长者,可作为预测永久性阈移（ＰＴＳ）的一项较理想的指标。     

正常足月儿畸变产物耳声发射(DPOAEs)特性分析

研究提出正常足月儿畸变产物耳声发射（ＤＰＯＡＥｓ） 特性分析如下：１ ． ＤＰＯＡＥｓ 反应强度曲线,ＤＰ 图显示两个反应峰（ｆ２ ＝ １ ．６ 和５ ．０ ｋＨｚ） 和一个反应谷（ｆ２ ＝ ３ ．１ ～４ ．０ ｋＨｚ） ;２． ＤＰＯＡＥ 本底噪声及其特性,ｆ２ ＝ １．０ ｋＨｚ 其测试频率点（２ｆ１ －ｆ２） 本底噪声最高（Ｐ＜ ０ ．０５） ,ｆ２ ＝ ３ ．１ ,４．０ 和５ ．０ｋＨｚ ,测试频率点（２ｆ１ －ｆ２） 本底噪声较低（Ｐ＜ ０．０５） ;除ｆ２ ＝ ４．０ ｋＨｚ 外,ＤＰＯＡＥ 本底噪声与其反应强度均未呈现直线相关特性;３ ． ＤＰＯＡＥ ＳＮＲ 特性,ｆ２ ＝ １．０ ｋＨｚ 其ＳＮＲ 最小（Ｐ＝ ０．０００） ,ｆ２ ＝２ ．０ ｋＨｚ 其ＳＮＲ 最大（Ｐ０ ．００３） ;４． ＤＰＯＡＥ ＳＮＲ 和ＴＥＯＡＥ ＳＮＲ 相关特性,除１．０ ｋＨｚ 频段外,其余频段其二者间均有着非常显著的直线相关特性。     

The auditory evoked potentials of the brain stem in the guinea pig

The examination of the standard waves' amplitude and latency of the brain stem auditory evoked response (BAEP) was performed in 20 guinea pigs (males and females, weighing 250 to 300 g). According with the relative loudness of stimuli (90, 70, 50, 30, 10 dB SPL), the latency of BAEP waves was larger (t1 = 0.2 msec), but the conductance time between P1 to P5 was constant (3.1 to 3.6 msec). The highest wave of BAEP was P2 with an amplitude: 90 dB SPL, U = 6.5 +/- 1.2 microV; 70 dB SPL, U = 4.3 +/- 1.0 microV; 50 dB SPL, U = 3.5 +/- 0.6 microV; 30 dB SPL, U = 2.0 +/- 0.4 microV.     

催产素对内耳外毛细胞功能的调控作用

采用耳蜗外淋巴液灌流催产素(OXT),记录由鼓阶电极引导的听神经复合动作电位(CAP)及耳蜗微音电位(CM)的输入—输出(I/O)函数。发现OXT可在90dB(SPL)以下各声强提高短纯音诱发的CM振幅以及短声诱发的CAP振幅,而当声强高于90dB时CM变化不明显。但在用含氯化筒箭毒(dTC)的外淋巴液灌流以阻断橄榄耳蜗束胆碱能传出控制后,OXT不再引起CM改变,而对CAP的作用在低声强段(<60dB)依然存在。这些结果提示OXT可能调节传出神经对内耳的控制,并可能对外毛细胞(OHC)的运动能力有直接影响。     

Retransmission of echo-like signals: methods and results of studies on nocturnal moths (Insecta)

Studies of capability to echolocate in nocturnal moths using the method of echo-signal retransmission are described in detail. During retransmission the insect was presented not with the echo from some real object but with electronically generated echo-like signal which appears following the certain delay after insect's own acoustic signal. In that way the artificial echo from non-existent obstacle is produced. In the current study the delay was set to 0.5 ms that corresponds to a distance of about 8 cm from obstacle. At the same time there was no any single movement of any object near the flying insect therefore the activities of sensory systems other than auditory did not cause systematical influence on results obtained. Noctuid moths (Noctuidae, Lepidoptera) are acoustically active insects. They are capable of producing ultrasonic clicks during flight. The most typical response of a moth to the retransmission of echo-like stimuli is an activation of own clicks emission that is often accompanied with rise in click amplitude. Using the activation of emission as a criterion of moth's response to the echo-like stimulation we measured echolocational thresholds in three species: Amphipyra pyramidea (36 dB SPL), Enargia paleacea (31 dB SPL) and Blepharita satura (26 dB SPL). The ability to echolocate was also demonstrated in 20 species of subfamilies Catocalinae, Amphipyrinae, Cuculliinae, Hadeninae, Noctuinae, Heliothinae.     

Characteristics of auditory brainstem responses in ground squirrels

Summary Auditory brainstem responses (ABRs) were characterized at 37 °C in ground squirrels (Citellus lateralis) which were implanted with recording screws to record ABRs, and a thermistor to record brain temperature. After two weeks ground squirrels were reanesthetized and tone pips and clicks were delivered through a TDH-49 headphone.Recorded ABRs were found to vary in a predictable manner as a function of stimulus frequency and intensity. At intensities above 50 dB SPL, ABRs could be recorded over the range tested (2–32 kHz). An 8 kHz tone pip was the best frequency for recording ABRs at the lowest stimulus intensities. Latencies decreased as stimulus frequencies increased from 4 kHz to 32 kHz.     

Two measures of temporal resolution in brown-headed cowbirds (<Emphasis Type="Italic">Molothrus ater</Emphasis>)

Studies of auditory temporal resolution in birds have traditionally examined processing capabilities by assessing behavioral discrimination of sounds varying in temporal structure. Here, temporal resolution of the brown-headed cowbird (Molothrus ater) was measured using two auditory evoked potential (AEP)-based methods: auditory brainstem responses (ABRs) to paired clicks and envelope following responses (EFRs) to amplitude-modulated tones. The basic patterns observed in cowbirds were similar to those found in other songbird species, suggesting similar temporal processing capabilities. The amplitude of the ABR to the second click was less than that of the first click at inter-click intervals less than 10 ms, and decreased to 30% at an interval of 1 ms. EFR amplitude was generally greatest at modulation frequencies from 335 to 635 Hz and decreased at higher and lower modulation frequencies. Compared to data from terrestrial mammals these results support recent behavioral findings of enhanced temporal resolution in birds. General agreement between these AEP results and behaviorally based studies suggests that AEPs can provide a useful assessment of temporal resolution in wild bird species.     

KILLER WHALE (ORCINUS ORCA) AUDITORY EVOKED POTENTIALS TO RHYTHMIC CLICKS

Temporal auditory mechanisms were measured in killer whales ( Orcinus orca ) by recording auditory evoked potentials (AEPs) to clicks. Clicks were presented at rates from 10/sec to 1,600/sec. At low rates, clicks evoked an AEP similar to the auditory brainstem response (ABR) of other odontocetes; however, peak latencies of the main waves were 3–3.7 msec longer than in bottlenose dolphins. Fourier analysis of the ABR showed a prominent peak at 300–400 Hz and a smaller one at 800–1,200 Hz. High-rate click presentation (more than 100/sec) evoked a rate-following response (RFR). The RFR amplitude depended little on rate up to 400/sec, decreased at higher rates and became undetectable at 1,120/sec. Fourier analysis showed that RFR fundamental amplitude dependence on frequency closely resembled the ABR spectrum. The fundamental could follow clicks to around 1,000/sec, although higher harmonics of lower rates could arise at frequencies as high as 1,200 Hz. Both RFR fundamental phase dependence on frequency and the response lag after a click train indicated an RFR group delay of around 7.5 msec. This corresponds to the latency of ABR waves PIII-NIV, which indicates the RFR originates as a rhythmic, overlapping ABR sequence. The data suggest the killer whale auditory system can follow high click rates, an ability that may have been selected for as a function of high-frequency hearing and the use of rapid clicks in echolocation.     

Hearing sensation levels of emitted biosonar clicks in an echolocating Atlantic bottlenose dolphin

Emitted biosonar clicks and auditory evoked potential (AEP) responses triggered by the clicks were synchronously recorded during echolocation in an Atlantic bottlenose dolphin (Tursiops truncatus) trained to wear suction-cup EEG electrodes and to detect targets by echolocation. Three targets with target strengths of -34, -28, and -22 dB were used at distances of 2 to 6.5 m for each target. The AEP responses were sorted according to the corresponding emitted click source levels in 5-dB bins and averaged within each bin to extract biosonar click-related AEPs from noise. The AEP amplitudes were measured peak-to-peak and plotted as a function of click source levels for each target type, distance, and target-present or target-absent condition. Hearing sensation levels of the biosonar clicks were evaluated by comparing the functions of the biosonar click-related AEP amplitude-versus-click source level to a function of external (in free field) click-related AEP amplitude-versus-click sound pressure level. The results indicated that the dolphin's hearing sensation levels to her own biosonar clicks were equal to that of external clicks with sound pressure levels 16 to 36 dB lower than the biosonar click source levels, varying with target type, distance, and condition. These data may be assumed to indicate that the bottlenose dolphin possesses effective protection mechanisms to isolate the self-produced intense biosonar beam from the animal's ears during echolocation.     

Long latency auditory evoked potentials: intensity, inter-stimulus interval, and habituation

Experiment 1 elicited the P1, N1, P2, and N2 components of the long latency auditory evoked potential (AEP) using a 1000 Hz tone presented at 30, 50, or 70 dB SPL and 1-, 3-, or 5-second inter-stimulus intervals to assess the relative effects of the combination of these variables on component amplitude and latency. Four blocks of 16 tone presentations each were recorded from each subject to determine if changes in the AEP would occur because of short-term habituation. Both stimulus factors interacted significantly in a systematic fashion for the amplitude measures, with increases in latency also associated with increases in intensity and inter-stimulus interval. Only minor changes across the four trial blocks for either the amplitude or latency measures were observed over the various stimulus presentation conditions. Experiment 2 employed the same tone stimulus presented at 50 dB SPL and a 3-second inter-stimulus interval. Eight blocks of 64 trials were recorded from each subject on each day for four days to investigate long-term habituation effects. No substantial changes in any of the component amplitudes or latencies were obtained across the 32 trial blocks. It was concluded that intensity and inter-stimulus interval interact to determine AEP amplitude as well as latency values and that the constituent components do not change appreciably with repeated stimulus presentations, even after several days.     

噪声刺激后豚鼠耳蜗抗氧化能力的变化和α-硫辛酸对声损伤的保护作用

实验探讨了声刺激后豚鼠血清总抗氧化能力(total antioxidant capacity,TAC)和耳蜗组织一氧化氮(nitricoxide,NO)含量的变化及α-硫辛酸的抗氧化和对声损伤的保护作用。将豚鼠(350-400 g)随机分为无噪声对照组(n=20)、噪声+生理盐水组(n=20)和噪声+α-硫辛酸组(n=20)。噪声刺激(4.kHz倍频程,115 dB SPL 5 h)结束后立即测试脑于诱发电位(auditory brainstem responses,ABRs),取血清测TAC,制备耳蜗组织匀浆测NO的水平。所得结果如下:(1)无噪声对照组,动物听阈无明显变化;噪声刺激后生理盐水组,听阈上升的幅度明显高于α-硫辛酸组(P<0.05)。(2)噪声+生理盐水组,TAlC明显低于无噪声对照组(P<0.05);噪声+α-硫辛酸组同噪声+生理盐水组相比,TAC明显升高(P<0.05),同无噪声对照组相比,无显著性差异(P>0.05)。(3)噪声+生理盐水组,NO含量高于无噪声对照组(P<0.05);噪声+α-硫辛酸组同噪声+生理盐水组相比,NO含量明显减少(P<0.05),同无噪声对照组相比,差异无显著性(P>0.05)。上述结果提示,噪声刺激后血清TAC降低,耳蜗组织内NO含量增加;α-硫辛酸可通过抗氧化机制对噪声性听力损伤(noise induced hearing loss,NIHL)发挥保护作用。