强噪声引起的ABRⅤ波振幅增大现象

为研究噪声作用后听觉中枢诱发反应振幅变化,用豚鼠记录了器材怕作用前后皮层诱发反应（ACER）和脑干诱发反应（ABR）的振幅和潜伏期,比较了暴露噪声前后短声刺激系列强度中ACER和ABR最大振幅和潜伏期,110dBA宽带噪声作用30分钟后,听阈提高53dB,ACER最大振幅增大24%,1小时后仍为24%,2小时后增大28%,峰间潜伏期（P1-P2）比暴露前缩短,噪声作用后ABRV波最大振幅增大15%,1小时后为21%,2小时后为28%,潜伏期比暴露前缩短,AP、ABP、Ⅰ、Ⅲ。Ⅳ波最大振幅均经暴露前减小。结果表明,强噪声作用后ACER存在振幅增大,同时ABRV波也有振幅增大现象。     

低氧对雄性高原鼠兔性腺的影响

在人工模拟低氧环境下（低压舱模拟５０００ｍ和７０００ｍ海拔高度）,低氧暴露２４ｈ和７ｄ,观察低氧对受试动物性腺的影响。结果表明,急性低氧２４ｈ,高原鼠兔血浆雌二醇（Ｅ２）明显升高;低氧暴露７ｄ,高原鼠兔血浆Ｅ２仍维持一较高水平;５０００ｍ低氧暴露７ｄ,其睾丸指数无明显变化,７０００ｍ时却有所降低。同等条件下,大鼠睾丸指数明显增高;５０００ｍ和７０００ｍ低氧暴露７ｄ对高原鼠兔睾丸组织形态无明显影响,然而,大鼠曲细精管间隙增大,且曲细精管内各级细胞排列紊乱。低氧环境下,高原鼠兔雄体血浆Ｅ２增高,可能是其低氧适应的特征之一     

豚鼠耳蜗核内听觉诱发电位及其频域分析

用计算机叠加平均和脑干神经核团立体定位技术记录１０只豚鼠耳蜗核内听觉诱发电位（ＣＮ－ＡＥＰ）。对ＣＮ－ＡＥＰ时域波形中主波的潜伏期、振幅进行分析,并与豚鼠脑干听觉诱发电位（ＢＡＥＰ）时域波形进行比较,认为ＣＮ－ＡＥＰ是ＢＡＥＰⅡ波的主要成分。用自回归模型谱（ＡＲ谱）估计及数字滤波技术对ＣＮ－ＡＥＰ行频域分析,发现豚鼠ＣＮ－ＡＥＰ的频谱成分主要在１０００Ｈｚ以下,在ＡＲ谱图上有３个峰,Ｆ０、Ｆ１和Ｆ２,谱峰分别位于１８０、７１０、１２００Ｈｚ左右,略高于豚鼠ＢＡＥＰ的相应谱峰频率,其原因尚待进一步探讨。     

我国正常成人脑干听觉电反应各波潜伏期的测定

在10名正常被试者的20只耳,用不同强度的短声测定了脑干听觉电反应(BSR)的7个波的潜伏期(数值见表1),结果表明,各波的潜伏期都随刺激声强的减弱(80到0 dB)而延长,且呈直线函数关系,并且这种延长主要来自1波。由每个被试者两耳所诱发的 BSR 各波的潜伏期及其与刺激声强的变化关系都较为恒定和对称。V 波振幅较大,出现率较高,接近主观听觉阈值,是 BSR 中的主波,其潜伏期(声强80 dB 时为5.7±0.6毫秒)如明显超出此范围(6.3毫秒)或两侧不对称时,应考虑为异常。我们还在半数测试例中记录到Ⅷ波,关于它的生理意义,尚不清楚。     

血循环障碍在高原冻伤中的形态计量观测

本文对高原冻伤中血液循环障碍作形态计量,旨在探讨血循环障碍在冻伤过程中的变化及高原冻伤发病机理中所起的作用。实验选用Ｗｉｓｔａｒ雄性大鼠４０只,随机分为平原冻伤组、急性低氧冻伤组和低氧习服冻伤组。习服组动物于低压舱内模拟海拔６０００ｍ缺氧每日４ｈ,连续两周。其余动物常规饲养。习服期满次日习服组与低氧组一同进入舱内模拟海拔６０００ｍ低氧４ｈ,再行冷冻。冻后继续低氧４ｈ。冻后４８ｈ取材。对各组动物冻后４８ｈ冻肢皮下血管的病变作图象分析。结果发现,平原组血管淤滞、血栓绝对数及其百分比均为最低,习服组最高,低氧组居中。但低氧组与平原组的血栓／淤滞百分比无明显差别。骨骼肌坏死的面积百分比习服组显著高于低氧组与平原组,而后两组间无差别。血栓／淤滞百分比与骨骼肌坏死面积百分比之间的有高度相关关系。冻融是直接引起血管内皮损伤的原发因素,局部血液循环障碍是造成严重的继发损伤的主要原因。     

谷氨酸受体在噪声所致豚鼠螺旋神经节细胞损伤中的作用

本文旨在研究谷氨酸及其受体在噪声致豚鼠螺旋神经节细胞损伤中的作用。实验分为在体和离体两部分。（1）在体实验：豚鼠分为生理盐水（NS,10μL）组,NS（10μL）＋噪声组和犬尿喹啉酸（kynurenic acid,KYNA,5mmol／L,10μL）＋噪声组,每组15只。用微量注射器经完整圆窗膜表面给予NS或KYNA：暴露于白噪声110dBSPL,1h。在圆窗给药前及噪声暴露后测试听觉脑干诱发电位（auditory brainstem response,ABR）阈值及Ⅲ波幅值,听神经复合动作电位（compound action potential,CAP）阈值及N1波幅值和潜伏期,测试后取基底膜进行透射电镜观察。（2）离体实验：观察高浓度谷氨酸对急性分离的豚鼠螺旋神经节细胞的影响。结果显示,NS＋噪声组豚鼠ABR及CAP阈移显著高于KYNA＋噪声组,且Ⅲ波和NI波幅值明显降低,潜伏期明显延长。NS＋噪声组豚鼠毛细胞及传入神经末梢急性水肿和线粒体结构破坏：KYNA＋噪声组豚鼠的毛细胞和传入神经末梢无明显变化。离体胞外施加谷氨酸可引起螺旋神经节细胞逐渐出现水肿、变性,最后死亡。本实验提示,噪声暴露可引起豚鼠听功能损伤,毛细胞／传入神经突触的结构破坏和螺旋神经节细胞变性、死亡：这种损伤可能与噪声暴露引起谷氨酸的过度释放有关;谷氨酸通过其受体介导致使螺旋神经节细胞损伤,谷氨酸受体的广谱拮抗剂KYNA可减轻噪声对螺旋神经节细胞的损伤。     

橄榄桥脑小脑萎缩患者的脑干听觉诱发电位及其与桥脑体积的相关性

目的:观察橄榄桥脑小脑萎缩(OPCA)脑干听觉诱发电位各波、波间潜伏期的变化,并分析这些变化与桥脑体积/后颅窝体积比值(PV/PFV)的相关性。方法:利用丹麦KeypointEMG/EP电生理仪测定OPCA组、对照组脑干听觉诱发电位Ⅰ、Ⅲ、Ⅴ波潜伏期(PL),Ⅰ-Ⅲ、Ⅲ-Ⅴ、Ⅰ-Ⅴ峰间潜伏期(IPL)并采用1.5TMR3DVolumeRender-ing软件行桥脑体积(PV)、小脑体积(CV)、后颅窝体积(PFV)磁共振测量,算出PV/PFV、CV/PFV、PV/CV值。结果:与对照组相比,OPCA组Ⅲ波PL、Ⅰ-ⅢIPL明显延长(P<0.05),Ⅲ-ⅤIPL明显缩短(P<0.05);OPCA组PV/PFV值明显减少(P<0.01);Ⅲ-ⅤIPL与PV/PFV呈正相关(r=0.83,P<0.01)。结论:OPCA患者脑干听觉诱发电位Ⅲ波PL、Ⅰ-ⅢIPL延长,Ⅲ-ⅤIPL缩短,Ⅲ-ⅤIPL随着桥脑体积的变小而缩短。     

低氧暴露下高原鼠兔血液中三种内源性气体分子含量的变化

内源性NO和CO以及H2S是目前发现的三种气体信号分子,在血管收缩调节和血管重构反应中发挥重要作用,影响肺血管收缩反应(HPV).本实验模拟5 000 m海拔高度,对高原鼠兔(Ochotona curzoniae)和SD大鼠进行不同时间的低氧处理,分别测定平均肺动脉压、右心指数和血液中内源性NO和CO以及H2S的浓度,以揭示三种气体分子在高原鼠兔低氧适应中的作用.研究结果显示:(1)随着低氧时间的增加,高原鼠兔肺动脉压没有出现显著性差异(P＞0.05),右心指数并未出现显著性变化(P＞0.05);SD大鼠肺动脉压在低氧7 d时出现极显著性增加(P＜0.01),并且随着低氧时间的增加肺动脉压持续升高,右心指数出现极显著性增加(P＜0.01);(2)高原鼠兔和SD大鼠血液中CO的水平在各处理间维持相对稳定(P＞0.05).高原鼠兔在低氧7 d时血液中NO浓度出现极显著性增加(P＜0.01),低氧21 d时NO浓度又恢复到正常水平(P＞0.05);SD大鼠在低氧1 d时血液中NO浓度出现显著性降低(P＜0.05),低氧7 d和21 d时NO浓度又恢复到正常水平(P＞0.05).高原鼠兔在低氧1 d时血液中H2S浓度无显著性差异(P＞0.05),低氧7d和21 dH2S浓度出现极显著性增加(P＜0.01);SD大鼠在低氧1 d时血液中H2S浓度出现极显著性增加(P＜0.01),低氧7 d、21 dH2S浓度与正常水平相比显著性降低(P＜0.05).结果表明,高原鼠兔提高血液中H2S的水平可能对其维持正常的肺动脉压和氧气传输具有重要作用.     

孤独症谱系障碍儿童听觉脑干反应特征分析

摘要 目的：探讨孤独症谱系障碍(autism spectrum disorder,ASD)儿童听觉脑干反应(auditory brainstem response,ABR)各波潜伏期和波间期特征与ASD行为表型间的关联。方法：对2019年7月-2020年12月来我科就诊的26例明确诊断的2~6岁ASD儿童的患儿进行声导抗,听性脑干反应,畸变产物耳声发射及多频稳态听觉诱发电位测试,以38例正常儿童为对照组,进行同样的测试,并对其测试结果进行统计分析。分析ASD儿童左右耳各波潜伏期,波间期特征及与ASD临床表型的关联。结果：ASD儿童左右耳Ⅰ,Ⅲ,Ⅴ波潜伏期分别为(1.42±0.09)ms,(3.67±0.09)ms,(5.65±0.13)ms;(1.45±0.11)ms,(3.69±0.08)ms,(5.62±0.15)ms。ASD组的右耳I,III波的潜伏期均值大于正常组 (P 值均＜0.05);ASD儿童两组间左耳III-V,右耳III-V,右耳I-V的波间期分别是(1.97±0.07)ms,(1.93±0.10)ms,(4.15±0.14)ms;ASD组的左耳III-V,右耳III-V,右耳I-V波间期均小于正常组(P 值均＜0.05);ASD组中小于等于3岁组与大于3岁组间ABR波间期差异不具有统计学意义。关联性分析发现,ASD儿童语言能力与右耳III波潜伏期,右耳最小阈值V波潜伏期负相关;社会行为能力与右耳I-III波间期负相关;社会生活能力与左耳最小阈值V波潜伏期负相关;而ABC评分与ASD儿童右耳III波潜伏期,左耳I-III波间期,右耳I-III波间期正相关。结论：ASD儿童存在异常的听觉脑干反应特征,且异常程度与 ASD 儿童语言,社会行为能力,社会生活能力的严重程度存在明显关联。     

川芎嗪抗链霉素耳毒性作用及其对豚鼠耳蜗外毛细胞钾通道的影响

本文旨在研究川芎嗪（tetramethylpyrazine,TMP）拮抗链霉素耳毒性作用及其对豚鼠耳蜗外毛细胞K^＋通道的影响,探讨TMP拈抗链霉素耳毒性的离子通道机制。60只豚鼠随机分为6组,应用听觉脑干反应（auditory brainstem response,ABR）技术检测豚鼠ABR听阈,观测TMP的抗链霉素耳毒作用;并采用全细胞膜片钳技术观察TMP对耳蜗外毛细胞Ca^2＋敏感艮电流的影响。结果显示,TMP明显降低链霉素导致的豚鼠ABR听阈升高,提示TMP具有抗链霉素耳毒性作用;TMP能明显增大豚鼠耳蜗外毛细胞Ca^2＋敏感艮电流,并呈浓度依赖关系。结果提示,TMP通过增大艮通道电导而拮抗链霉素耳毒性作用。     

Photobiomodulation using low‐level 808 nm diode laser rescues cochlear synaptopathy after acoustic overexposure in rat

A certain degree of noise can cause hearing problems without a permanent change in the hearing threshold, which is called hidden hearing loss and results from partial loss of auditory synapses. Photobiomodulation (PBM) enhances neural growth and connections in the peripheral nervous systems. In this study, we assessed whether PBM could rescue cochlear synaptopathy after acoustic overexposure in rat. PBM was performed for 7 days after noise exposure. The auditory brainstem responses (ABRs) were acquired before and after noise exposure using a tone and a paired‐click stimulus. Auditory response to paired click sound with short time interval was performed to evaluate auditory temporal processing ability. In the result, hearing threshold recovered 2 weeks after noise exposure in both groups. Peak wave 1 amplitude of the ABR and ABR recovery threshold did not recover in the noise only group, whereas it fully recovered in the noise + PBM group. The number of synaptic ribbons was significantly different in the control and noise only groups, while there was no difference between the control and noise + PBM group. These results indicate that PBM rescued peak wave 1 amplitude and maintained the auditory temporal processing ability resulting from a loss of synaptic ribbons after acoustic overexposure.     

模拟高海拔低氧对人体睡眠的影响

在模拟不同海拔高度的低氧条件暴露下,我们记录和测定了6名对象的睡眠生理各项指标。结果如下:在急性低氧暴露下所有对象均出现了睡眠障碍,主要是在夜间规定睡眠时间中觉醒期和觉醒次数增加,深睡眠期和快眼动期减少,睡眠各期的呼吸频率和心率增加。随着低氧暴露时间的延长和多次空气潜水后,各睡眠生理指标有向海平对照值水平发展的趋势。4500m以上的低氧暴露下,所有对象在睡眠中都有周期性呼吸现象出现,并影响体内的缺氧。     

缺氧条件下冻伤对大鼠微循环液血灌流量的影响

本文采用体重２００±２０ｇ健康雄性Ｗｉｓｔａｒ大鼠,随机分为平原冻伤（ＦＮ）组,急性缺氧冻伤（ＦＡＨ）组和缺氧习服缺氧冻伤（ＦＨＡＣ）组,实验观察了大鼠右后肢重度冻伤前后各组大鼠双后肢皮肤微循环灌流量的改变,结果表明,平原冻伤使大鼠以后肢微循环灌流量明显减少,提示局部重度冻伤对微循环的影响不只局限于冻区也涉及到对侧肢体,冻冻前ＦＡＨ组大鼠微循环灌流量已明显低于ＦＮ组,表明生缺氧时血容量进行代偿性的     

Effects of atropine and propranolol on the respiratory, circulatory, and ECG responses to high altitude in man

In order to analyze the respiratory, cardiovascular, and ECG responses to acute hypoxic hypoxia, three experimental series were carried out in a randomized manner on 11 healthy, unacclimatized volunteers at rest during standardized stepwise exposure to 6000 m (PAO2 35.2 +/- 2.9 mmHg/4.7 +/- 0.4 kPa) in a low-pressure chamber a) without (control), b) with propranolol, and c) with atropine combined with propranolol. The results show that hypoxic hyperventilation and alveolar gases are not affected by activation of the sympatho-adrenal axis or by parasympathetic withdrawal. Sympathetic activity, however, increases heart rate, stroke volume (pulse pressure), estimated cardiac output and systolic blood pressure, whereas decreased parasympathetic activity increases heart rate and estimated cardiac output, but lowers stroke volume. The fall in peripheral resistance, observed during progressive hypoxia in all three groups, is thought to be due to hypoxia-induced depression of the vasomotor center. At altitude catecholamine secretion and vagal withdrawal synergistically account in the ECG for the R-R shortening, the relative Q-T lengthening, the elevation of the P wave and the ST-T flattening. Probable direct hypoxic effects on the heart are the increase in P-Q duration and the minor but still significant depression of the T wave. It is concluded that at altitude increased sympatho-adrenal and decreased parasympathetic activity is without effect on hypoxic hyperventilation, but accounts for most of the cardiovascular and ECG changes. Diminution of sympathetic activity and imminent vagotonia arising after acute ascent to 6000 m probably reflect hypoxia of the central nervous system.     

The detrimental effects of potassium bromate and thioglycolate on auditory brainstem response of guinea pigs

Potassium bromate (KBrO3) is known to be an oxidizing agent that is used not only as a food additive, mainly in the bread-making process, but also as a neutralizer in thioglycolate containing hair curling set. Although it has been shown that bromate poisoning could cause severe and irreversible sensorineural hearing loss as well as renal failure, the action mechanism of bromate-induced otoneurotoxicity especially its combination with thioglycolate remains to be studied. In this study, we attempted to investigate the toxic effects of KBrO3 in combination with or without thioglycolate on the auditory brainstem response (ABR) system in the guinea-pigs which was claimed to be very susceptible to the xenobiotics. In a preliminary test, we have found that after consecutive 2 weeks administration, KBrO3 caused a significant prolongation of wave I-III and the interwave latencies of ABR as well as significantly elevated the threshold of hearing, suggesting that the conduction velocity of the peripheral auditory nerve was delayed. By contrast, the absolute latency of wave IV/V and the interwave latency of wave III-V were not significantly prolonged, suggesting that KBrO3 had no effect on the brainstem. This oto-neurotoxic effect of KBrO3 was markedly enhanced by combining with thioglycolate. Our data also indicated that KBrO3 combined with thioglycolate but not KBrO3 alone prominantly caused a decrease of body weight. However, enzymatic activities (including Na+/K+-ATPase and Ca2+-ATPase) and the level of nitric oxide (NO) was significantly affected in the brainstem. Based on these findings, we tentatively conclude that whether KBrO3 alone or KBrO3 combined with thioglycolate induced oto-neurotoxicity majorly through the peripheral auditory nerve rather than via the central brainstem intoxication.     

Effects of high altitude and water deprivation on arginine vasopressin release in men

High-altitude exposure changes the distribution of body water and electrolytes. Arginine vasopressin (AVP) may influence these alterations. The purpose of this study was to examine the effect of a 24-h water deprivation trial (WDT) on AVP release after differing altitude exposures. Seven healthy males (age 22 +/- 1 yr, height 176 +/- 2 cm, mass 75.3 +/- 1.8 kg) completed three WDTs: at sea level (SL), after acute altitude exposure (2 days) to 4,300 m (AA), and after prolonged altitude exposure (20 days) to 4,300 m (PA). Body mass, standing and supine blood pressures, plasma osmolality (Posm), and plasma AVP (PAVP) were measured at 0, 12, 16, and 24 h of each WDT. Urine volume was measured at each void throughout testing. Baseline Posm increased from SL to altitude (SL 291.7 +/- 0.8 mosmol/kgH2O, AA 299.6 +/- 2.2 mosmol/kgH2O, PA 302.3 +/- 1.5 mosmol/kgH2O, P < 0.05); however, baseline PAVP measurements were similar. Despite similar Posm values, the maximal PAVP response during the WDT (at 16 h) was greater at altitude than at SL (SL 1.7 +/- 0.5 pg/ml, AA 6.4 +/- 0.7 pg/ml, PA 8.7 +/- 0.9 pg/ml, P < 0.05). In conclusion, hypoxia appeared to alter AVP regulation by raising the osmotic threshold and increasing AVP responsiveness above that threshold.     

Heat shock response and mammal adaptation to high elevation (hypoxia)

The mammal’s high elevation (hypoxia) adaptation was studied by using the immunological and the molecular biological methods to understand the significance of Hsp (hypoxia) adaptation in the organic high elevation, through the mammal heat shock response. (1) From high elevation to low elevation (natural hypoxia): Westem blot and conventional RT-PCR and real-time fluorescence quota PCR were adopted. Expression difference of heat shock protein of 70 (Hsp70) and natural expression of brain tissue of Hsp70 gene was determined in the cardiac muscle tissue among the different elevation mammals (yak). (2)From low elevation to high elevation (hypoxia induction): The mammals (domestic rabbits) from the low elevation were sent directly to the areas with different high elevations like 2300, 3300 and 5000 m above sea level to be raised for a period of 3 weeks before being slaughtered and the genetic inductive expression of the brain tissue of Hsp70 was determined with RT-PCR. The result indicated that all of the mammals at different elevations possessed their heat shock response gene. Hsp70 of the high elevation mammal rose abruptly under stress and might be induced to come into being by high elevation (hypoxia). The speedy synthesis of Hsp70 in the process of heat shock response is suitable to maintain the cells’ normal physiological functions under stress. The Hsp70 has its threshold value. The altitude of 5000 m above sea level is the best condition for the heat shock response, and it starts to reduce when the altitude is over 6000 m above sea level. The Hsp70 production quantity and the cell hypoxia bearing capacity have their direct ratio.     

Heat shock response and mammal adaptation to high elevation (hypoxia)

The mammal's high elevation(hypoxia) adaptation was studied by using the immu-nological and the molecular biological methods to understand the significance of Hsp(hypoxia) ad-aptation in the organic high elevation,through the mammal heat shock response.(1) From high ele-vation to low elevation(natural hypoxia) :Western blot and conventional RT-PCR and real-time fluo-rescence quota PCR were adopted.Expression difference of heat shock protein of 70(Hsp70) and natural expression of brain tissue of Hsp70 gene was determined in the cardiac muscle tissue among the different elevation mammals(yak) .(2) From low elevation to high elevation(hypoxia induction) :The mammals(domestic rabbits) from the low elevation were sent directly to the areas with different high elevations like 2300,3300 and 5000 m above sea level to be raised for a period of 3 weeks be-fore being slaughtered and the genetic inductive expression of the brain tissue of Hsp70 was deter-mined with RT-PCR.The result indicated that all of the mammals at different elevations possessed their heat shock response gene.Hsp70 of the high elevation mammal rose abruptly under stress and might be induced to come into being by high elevation(hypoxia) .The speedy synthesis of Hsp70 in the process of heat shock response is suitable to maintain the cells' normal physiological functions under stress.The Hsp70 has its threshold value.The altitude of 5000 m above sea level is the best condition for the heat shock response,and it starts to reduce when the altitude is over 6000 m above sea level.The Hsp70 production quantity and the cell hypoxia bearing capacity have their direct ratio.     

Appetite at "high altitude" [Operation Everest III (Comex-'97)]: a simulated ascent of Mount Everest.

We hypothesized that progressive loss of body mass during high-altitude sojourns is largely caused by decreased food intake, possibly due to hypobaric hypoxia. Therefore we assessed the effect of long-term hypobaric hypoxia per se on appetite in eight men who were exposed to a 31-day simulated stay at several altitudes up to the peak of Mt. Everest (8,848 m). Palatable food was provided ad libitum, and stresses such as cold exposure and exercise were avoided. At each altitude, body mass, energy, and macronutrient intake were measured; attitude toward eating and appetite profiles during and between meals were assessed by using questionnaires. Body mass reduction of an average of 5 +/- 2 kg was mainly due to a reduction in energy intake of 4.2 +/- 2 MJ/day (P < 0.01). At 5,000- and 6,000-m altitudes, subjects had hardly any acute mountain sickness symptoms and meal size reductions (P < 0.01) were related to a more rapid increase in satiety (P < 0.01). Meal frequency was increased from 4 +/- 1 to 7 +/- 1 eating occasions per day (P < 0. 01). At 7,000 m, when acute mountain sickness symptoms were present, uncoupling between hunger and desire to eat occurred and prevented a food intake necessary to meet energy balance requirements. On recovery, body mass was restored up to 63% after 4 days; this suggests physiological fluid retention with the return to sea level. We conclude that exposure to hypobaric hypoxia per se appears to be associated with a change in the attitude toward eating and with a decreased appetite and food intake.