不同时程弱前掩蔽声对小鼠下丘神经元声反应的选择性抑制

自由声场条件下,以强度为神经元最小阈值阈上5dB,时程分别为40、60、80和100ms的纯音作为前掩蔽声,观察和记录了不同时程弱前掩蔽声对小鼠（Musmusculus Km）下丘神经元发放和声强处理的影响。实验记录到154个神经元,对其中的104个神经元做了不同时程掩蔽声影响的测试。结果发现：掩蔽声对神经元放电率的抑制作用在时间上表现为前抑制（41％）、后抑制（9％）和全抑制（50％）三种类型。改变掩蔽声时程时,大部分神经元（72％）的抑制类型不发生改变,但少部分神经元（28％）随掩蔽声时程的增加,大量的后抑制类型转变为前抑制或全抑制类型。此外,超过一半的神经元（58．06％）其强度．放电率函数曲线随掩蔽声时程的改变而发生转变,主要表现为单调型向饱和型转变及饱和型向非单调型转变,这种转变并不随掩蔽声时程增加表现出规律性的变化。结果表明,前掩蔽作用于下丘神经元声反应的时间域和强度域时具有不均衡性,推测不同时程弱前掩蔽声激活的抑制性输入能分化性调制下丘神经元声反应特性。     

小鼠下丘神经元声反应的性别差异

采用自由声场的纯音短声刺激研究昆明小鼠下丘神经元听反应特征的性别差异。结果表明,①下丘神经元放电形式雌性以相位型为主,雄性以持续紧张型为主,且持续紧张型出现率存在明显的性差(P<005);②最佳频率分布雌雄都主要集中在10～20kHz,而潜伏期分布雌性较雄性集中;③最小阈值分布雌性主要集中于40～63dBSPL,而雄性无明显的集中区;④神经元最大发放雌性明显高于雄性(P<001);⑤脉冲发放函数和潜伏期函数的类型雌雄相同,但非单调型潜伏期函数出现率雄性明显高于雌性(P<001);⑥小鼠下丘神经元频率调谐曲线被分成五类,各类出现率在雌雄间无明显差异,但宽阔型频率调谐曲线百分率雌性明显高于雄性(P<005),且雌性频率调谐曲线高频边反转斜率明显高于雄性(P<005)。因此提示,雌雄小鼠下丘神经元声反应特征存在一定的差异。     

昆明小鼠下丘神经元对调频声的反应

尽管昆明小鼠下丘神经元对纯音的反应已有深入研究,但其对调频声的反应情况却未见报道。本研究在自由声场条件下,采用单单位细胞外记录方法,观察了昆明小鼠下丘神经元对调频声刺激的反应情况。根据神经元对调频声及纯音反应的阈值差异,所记录的99个下丘神经元可分为三种类型:对调频声刺激反应的阈值低于纯音的为Ⅰ型(57/99,57.6%),二者阈值相当的为Ⅱ型(12/99,12.1%),而纯音阈值低于调频声的为Ⅲ型(30/99,30.3%)。与Ⅲ型神经元相比,Ⅰ型神经元具有较低的CF和Q20dB(P<0.05和P<0.001)和较高的RB20dB(P<0.05)。通过分析下丘神经元对上、下扫时发放数的差异,发现有36个(36/99,36.4%)神经元表现出方向选择性,其中22个(22/99,22.2%)为上扫敏感,其余14个(14/99,14.2%)为下扫敏感,且上扫敏感性神经元比下扫敏感性神经元在Ⅰ、Ⅱ和Ⅲ型神经元中有更广的分布范围。通过比较发现,Ⅰ型神经元和方向选择性神经元的特征频率都非常集中地分布在10kHz-20kHz范围内(77.2%和83.3%)。此外,对其中24个神经元采取了不同调制速度的调频声刺激,大多数(15/24,62.5%)神经元对快调频声反应最为敏感,并且随着调制速度的升高,方向选择性神经元的比例有下降趋势(45.8%vs41.7%vs33.3%)。上述结果提示,昆明小鼠下丘神经元能有效处理调频声刺激,且具有方向选择性的调频声在昆明小鼠的声通讯中占有重要地位。     

普氏蹄蝠下丘谐波主频神经元的时程选择性

为探讨下丘(Inferior colliculus,IC)回声定位信号主频范围内的神经元的时程选择性,在自由声场刺激条件下,我们在4 只普氏蹄蝠的IC 采用不同时程的声刺激,研究了神经元的时程选择性。通过在体细胞外记录,共获得56 个声敏感下丘神经元,其记录深度、最佳频率和最小阈值的范围分别为1547 - 3967 (2878. 9 ±629.1)μm,20 -68 (49.0 ± 11. 1)kHz 和36.5 -95. 5 (59. 8 ±13. 0)dB SPL。根据所记录到的下丘神经元对不同时程的声刺激的反应,即对不同时程的选择性(Duration selectivity),将其分为6 种类型:短通型(Short-pass,SP,n = 11/56)、带通型(Band-pass,BP,n = 1/56)、长通型(Long-pass,LP,n = 5 /56)、反带通型(Band-reject,BR,n = 3 /56)、多峰型(Multi-peak,MP,n =6 /56)和全通型(All-pass,AP,n =30 /56)或非时程选择型(Nonduration-selective,NDS)。通过比较普氏蹄蝠下丘谐波主频内和主频外神经元的时程选择性,我们发现处于回声定位信号主频范围内神经元(n =32)比主频外神经元(n = 24)具有更短的最佳时程和更高的时程选择性。结果提示,在普氏蹄蝠回声定位过程中谐波主频内神经元较谐波主频外神经元发挥了更为重要的作用。     

弱噪声对下丘神经元声强敏感性的动态调制

为探讨复杂听环境下行为相关声信号提取的可能机制,研究了弱噪声对下丘(IC)神经元强度．放电率函数(RIF)的影响。实验在9只昆明小鼠(Musmusculus Km)上进行,在自由声场刺激条件下,分别记录短纯音刺激以及同步输出短纯音阂下5dB包络白噪声刺激时IC神经元的RIF,共获112个IC神经元,测量了其中44个神经元在加入噪声前(W／O)后(w)的RIF。以加入噪声前后RIF的声强动力学范围(DR)、斜率、以及不同声刺激强度的放电率抑制百分比变化为指标,比较分析发现：弱噪声对神经元发放率的影响呈三种类型,即抑制(39／44,88．6％)、易化(2／44,4．6％)和无影响(3／44,6．8％),但只有抑制性影响有显著性意义(P＜0．001,n=39);弱噪声对阂反应的抑制效应最强,并随纯音强度的增加而逐步减弱(P＜0．01301,n=39);此外,弱噪声的抑制作用还使大部分神经元的(31／39,79．5％)DR变窄(P＜0．01,,l=31)、RIF的斜率增加(P＜0．01,n=31)。上述结果提示,弱噪声参与下丘神经元声强敏感性的动态调制过程。这一观察为人们深入了解自然听环境中声信号提取的中枢机制提供了新认识。     

下丘神经元声信号处理过程中的频谱整合

自由声场条件下,采用特定双声刺激、双电极同步记录方法研究了下丘神经元的频谱整合作用。实验在6只大棕蝠(Eptesicus fuscus)上进行,共获得22对频谱整合相关的配对神经元。结果显示：(1)81．8％(36／44)的配对神经元产生相互抑制性频谱整合,18．2％(8/44)为相互易化性频谱整合;(2)频谱整合的范围主要在20～30kHz之间,其中约一半(45．5％,20/44)的配对神经元其最佳频率差小于2kHz,但也可见最佳频率差大于10kHz的配对神经元(13．6％,6/44)产生频谱整合;(3)下丘神经元的频率及强度选择性受频谱整合作用的调制。推测等频层内及等频层之间的下丘神经元在声信号处理过程中存在相互作用机制,以利于对复杂声信号的加工。     

弱噪声对小鼠下丘神经元频率调谐的影响

为探讨弱噪声对小鼠 (MusmusculusKm)中脑下丘 (inferiorcolliculus ,IC)神经元声信号提取的影响 ,采用单位胞外记录方法 ,研究了加入弱白噪声 (强度相当于纯音阈强度下 5dB)前后神经元频率调谐曲线的变化。实验共记录到 10 4个下丘神经元 ,测量了 32个神经元的频率调谐曲线。结果显示 :①弱噪声条件下神经元的频率调谐曲线表现出 3种类型 ,即锐化 (34 4 % ,11/ 32 )、拓宽 (18 8% ,6 / 32 )和不受影响 (4 6 9% ,15 / 32 ) ,其中锐化呈现有意义的变化 ;②频率调谐受弱噪声锐化的神经元 ,其Q10 、Q3 0 平均分别增大 (34 4 2±17 0 4 ) % (P =0 0 2 6 ,n =11)和 (4 6 34± 2 2 88) % (P =0 0 0 9,n =7) ,且Q3 0 变化率大于Q10 ;③弱噪声对调谐曲线的高、低频边锐化度不一 ,神经元低频边的反转斜率基本不变 [由 0 16± 0 0 8变为 0 16± 0 0 7kHz/dB (P =0 94 7,n =7) ],而高频边明显下降 [由 0 5 2± 0 2 5下降为 0 2 6± 0 13kHz/dB ,平均减小 (4 3 81±2 4 0 6 ) % ,(P =0 0 4 6 ,n =7) ]。上述结果表明 ,弱噪声可锐化小鼠IC神经元频率调谐 ,并强化神经元的声信号高频分析能力     

小鼠下丘听觉神经元的方位角灵敏度

声源定位是听觉系统的主要功能之一。下丘作为听觉中脑的重要组成部分,在声源定位的过程中起到非常重要的作用。应用胞外记录方法研究小鼠下丘神经元对自由声场内不同方位声刺激的调谐特性。实验记录了100个下丘神经元,根据神经脉冲发放数与声源方位角关系曲线、最佳方位角(best azimuth, BA)位置和优势方位角范围(preferred azimuth range, PAR),可将其分为4类:对侧极大型神经元占79%,PAR为52.3°;双峰型神经元占14% ,PAR为68.0°;全向型神经元占5%,PAR为169.6°;同侧极大型神经元占2%,PAR为66.5°。实验结果说明,小鼠下丘神经元对方位角有很好的表达,对声源方位有选择性,并表明声音的方位信息在下丘进行了加工整合。本文还就下丘神经元方位编码的机制进行了探讨。     

恒频-调频蝙蝠下丘神经元的恢复周期决定声脉冲跟随率

为探究恒频-调频蝙蝠下丘神经元恢复周期特点及其对声脉冲跟随率的影响,实验采用模拟的大蹄蝠(Hipposideros armiger)自然状态下的恒频-调频发声信号为声刺激,在5只听力正常的大蹄蝠上记录了下丘神经元的声反应和恢复周期(n = 93)．结果发现,根据神经元恢复率达50%时的双声刺激间隔(inter pulse interval,IPI),可将其分为长时恢复型(long recovery,LR;47.4%)、中等时间恢复型(moderate recovery,MR;35.1%)和短时恢复型(short recovery,SR;17.5%)．每种类型依据其恢复率随IPI增加而呈现的不同变化又可进一步分为单IPI反应区神经元,多IPI反应区神经元,以及单调IPI反应神经元．LR,MR和SR型神经元恢复率达50%时的平均IPI分别为(64.0 ± 24.8),(19.6 ± 5.8)和(7.1 ± 2.4) ms (P < 0.001),相对应的平均理论每秒声脉冲数分别为(18.2 ± 7.0),(55.4 ± 15.7)和(171.3 ± 102.9) Hz (P < 0.001)．结果提示,单IPI和多IPI反应区神经元具有特殊IPI反应特性,能对蝙蝠捕食和巡航期间所处的时相做出准确判断,而单调IPI反应神经元对IPI变化的敏感性较强,但时相判断性较差．另外LR,MR和SR型神经元恢复周期和理论脉冲跟随率的平均结果均能与这种蝙蝠回声定位期间3个时相的发声行为相匹配,且神经元恢复周期参与决定声脉冲跟随率,满足了蝙蝠巡航、捕食的行为学需要．     

电刺激蝙蝠小脑对下丘神经元听反应的影响

实验在34只长翼蝠(Miniopterus schrebersi)上进行.使用玻璃微电极在中脑下丘中央核记录听神经元电反应.电刺激点分别位于小脑蚓部、半球和绒球小结叶共观察了515个对超声刺激产生反应的下丘听神经元.当电刺激小脑时,有171个(占33.2%)神经元听反应受到影响.其中126个(占24.5%)表现为抑制,45个(8.7%)表现为易化.抑制效应表现为神经元所反应放电频数降低和反应潜伏期延长.易化效应则相反.抑制与易化潜伏期一般都在6毫秒以上.抑制效应与电刺激强度、声刺激强度以及声刺激和电刺激的时间间隔有关.抑制和易化性影响都是双侧性的.     

抑制性频谱整合对大棕蝠下丘神经元声强敏感性的影响

自由声场条件下 ,采用特定双声刺激方法研究了不同频率通道之间的非线性整合对下丘神经元声强敏感性的调制作用。实验在 1 2只麻醉与镇定的大棕蝠 (Eptesicusfuscus)上进行 ,双电极同步记录 2个配对神经元的声反应动作电位。主要结果如下 :1 )所获 1 1 0个 (5 5对 )配对神经元中 ,85 5 %表现为抑制性频谱整合作用 ,其余 1 4 5 %为易化性频谱整合 ;2 )阈上 1 0dB (SPL)放电率抑制百分比与神经元最佳频率 (BF)及记录深度呈负相关 ;3)抑制效率随声刺激强度升高而逐步下降 ;4 )当掩蔽声分别位于神经元兴奋性频率调谐曲线(FTC)内 (MSin) /外 (MSout)时 ,其抑制效率存在差异。前者的放电率抑制百分比及声反应动力学范围(DR)下降百分比均显著高于后者 ;5 )抑制性频谱整合导致 3类DR改变 :6 1 6 %为下降、 1 0 9%增加、另有2 7 5 %变化小于 1 0 %。本结果进一步支持如下设想 :下丘不同频率通道之间的抑制性频谱整合参与了对强度编码的主动神经调制活动     

On the ability of neurons in the barn owl's inferior colliculus to sense brief appearances of interaural time difference

Summary This paper investigates the ability of neurons in the barn owl's (Tyto alba) inferior colliculus to sense brief appearances of interaural time difference (ITD), the main cue for azimuthal sound localization in this species. In the experiments, ITD-tuning was measured during presentation of a mask-probe-mask sequence. The probe consisted of a noise having a constant ITD, while the mask consisted of binaurally uncorrelated noise. Collicular neurons discriminated between the probe and masking noise by showing rapid changes from untuned to tuned and back to untuned responses.The curve describing the relation between probe duration and the degree of ITD-tuning resembled a leaky-integration process with a time constant of about 2 ms. Many neurons were ITD-tuned when probe duration was below 1 ms. These extremely short effective probe durations are interpreted as evidence for neuronal convergence within the pathway computing ITD. The minimal probe duration necessary for ITD-tuning was independent of the bandwidth of the neurons' frequency tuning and also of the best frequency of a neuron. Many narrowly tuned neurons having different best frequencies converge to form a broad-band neuron. To yield the short effective probe durations the convergence must occur in strong temporal synchronism.Abbreviations ICc central nucleus of the inferior colliculus; - ICx external nucleus of the inferior colliculus; - ITD interaural time difference - LP Likelihood parameter     

Processing of spectral localization-informative changes in sound signals by neurons of inferior colliculus and auditory cortex of the house mouse Mus musculus

Comparative analysis was performed of sensitivity of three populations of neurons of the inferior colliculus central nucleus and of neurons of the auditory cortex A1 and AAF fields of the house mouse Mus musculus to series of signals of wideband noise with spectral notch shifting along the frequency axis and to series of the band noise signals with shifting band. Sensitivity to spectral notches in noise was estimated from a change of impulse activity depending on notch location on the frequency axis (modulation coefficients were determined as the normalized difference between the maximal and minimal spike number in neuronal responses to all noises with notch exposed in the series). It was shown that the highest modulation coefficient values and accordingly the highest frequency-dependent sensitivity to spectral notches in the noise were peculiar to inhibition-dependent inferior colliculus neurons. Statistical analysis confirmed that distribution of modulation coefficients for the group of the inhibition-dependent neurons differed statistically significantly from the distribution for groups of primary-like and V-shaped inferior colliculus neurons as well as of cortical neurons (U-test, p < 0.0001). The lowest sensitivity to spectral notches was revealed in the V-shaped inferior colliculus neurons and cortical neurons; in these groups, distribution of modulation coefficients did not differed statistically significantly (p > 0.3). Thus, although a part of cortical neurons does have the frequency-dependent selectivity to spectral localizationally informative changes in sound signals, its formation needs participation of the inferior colliculus and its inhibition-dependent neurons. Selectivity to direction of the shift of spectral changes in noise signals in neurons of the inferior colliculus and auditory cortex was similar and was manifested mainly as shift along the frequency axis of dependences of the spike number in the neuronal responses and latent periods on central frequency of notch in noise (the noise band).     

The relationship between O-chain expression and colonisation ability of Helicobacter pylori in a mouse model

The influence of lipopolysaccharide (LPS) O-polysaccharide chain production on the colonisation ability of Helicobacter pylori in four mouse models (NMRI, C57BL/6, CBA/Ca, and BALB/cA mice) was studied. H. pylori strains that produced smooth-form LPS (S-LPS) detectable in silver-stained electrophoretic gels colonised mice. In contrast, a laboratory-passaged strain G50 and the culture collection strain CCUG 17874 did not colonise mice; the former strain produced low amounts of O-chains only detectable in immunoblotting but not in silver-stained gels, whereas the latter produced rough-form LPS (R-LPS) without O-chains. Furthermore, a galE isogenic mutant, which produced R-LPS, did not colonise mice. However, after repeated broth culture, strains G50 and CCUG 17874 produced S-LPS detectable in silver-stained gels and were capable of colonising mice. Consistent with the production of O-chains, all colonising strains produced Lewis (Le) antigens, Le(x) and/or Le(y). Except for low expression of Le(y) by non-colonising G50, reflecting low production of O-chains, all other non-colonising strains and the galE mutant lacked expression of Le antigens consistent with their production of R-LPS. Lectin typing of strains supported these findings, and also showed that lectin types did not differ before and after colonisation. The low level of O-chain production and Le antigen expression by the non-colonising G50 may not be sufficient to aid colonisation. Examination of protein profiles of H. pylori strains before inoculation showed that protein expression was not significantly different between colonising and non-colonising strains. These results show that S-LPS production with O-chain expression is required by H. pylori for colonisation in a number of mouse models and that care should be taken with inoculating H. pylori strains that loss of O-chains does not occur during subculturing.     

Spatial tuning of neurons in the inferior colliculus of the big brown bat: effects of sound level, stimulus type and multiple sound sources

We examined factors that affect spatial receptive fields of single units in the central nucleus of the inferior colliculus of Eptesicus fuscus. Pure tones, frequency- or amplitude-modulated sounds, or noise bursts were presented in the free-field, and responses were recorded extracellularly. For 58 neurons that were tested over a 30 dB range of sound levels, 7 (12%) exhibited a change of less than 10° in the center point and medial border of their receptive field. For 28 neurons that were tested with more than one stimulus type, 5 (18%) exhibited a change of less than 10° in the center point and medial border of their receptive field.The azimuthal response ranges of 19 neurons were measured in the presence of a continuous broadband noise presented from a second loudspeaker set at different fixed azimuthal positions. For 3 neurons driven by a contralateral stimulus only, the effect of the noise was simple masking. For 11 neurons driven by sound at either side, 8 were unaffected by the noise and 1 showed a simple masking effect. For the remaining 2, as well as for 5 neurons that were excited by contralateral sound and inhibited by ipsilateral sound, the peak of the azimuthal response range shifted toward the direction of the noise.Abbreviations E/E excitation at either ear - I/E inhibition at the ipsilateral ear, excitation at the contralateral ear - O/E no effect from the ipsilateral ear, excitation at the contralateral ear - FM downward frequency modulation - FM upward frequency modulation - IC inferior colliculus - ICC central nucleus of the inferior colliculus - ILD interaural level difference - ITD interaural time difference - PT pure tone - SAM sinusoidally amplitude modulated sounds - SFM sinusoidally frequency modulated sounds     

Encoding repetition rate and duration in the inferior colliculus of the big brown bat,Eptesicus fuscus

1. Encoding of temporal stimulus parameters by inferior collicular (IC) neurons of Eptesicus fuscus was studied by recording their responses to a wide range of repetition rates (RRs) and durations at several stimulus intensities under free field stimulus conditions. 2. The response properties of 424 IC neurons recorded were similar to those reported in previous studies of this species. 3. IC neurons were classified as low-pass, band-pass, and high-pass according to their preference for RRs and/or durations characteristic of, respectively, search, approach, or terminal phases of echolocation. These neurons selectively process stimuli characteristic of the various phases of hunting. 4. Best RRs and best durations were not correlated with either the BFs or recording depths This suggests that each isofrequency lamina is capable of processing RRs and durations of all hunting phases. 5. Responses of one half of IC neurons studied were correlated with the stimulus duty cycle. These neurons may preferentially process terminal phase information when the bat's pulse emission duty cycle increases. 6. While the stimulus RR affected the dynamic range and overall profile of the intensity rate function, only little effect was observed with different stimulus durations.     

Frequency tuning, latencies, and responses to frequency-modulated sweeps in the inferior colliculus of the echolocating bat, Eptesicus fuscus

Neurons in the inferior colliculus (IC) of the awake big brown bat, Eptesicus fuscus, were examined for joint frequency and latency response properties which could register the timing of the bat's frequency-modulated (FM) biosonar echoes. Best frequencies (BFs) range from 10 kHz to 100 kHz with 50% tuning widths mostly from 1 kHz to 8 kHz. Neurons respond with one discharge per 2-ms tone burst or FM stimulus at a characteristic latency in the range of 3–45 ms, with latency variability (SD) of 50 μs to 4–6 ms or more. BF distribution is related to biosonar signal structure. As observed previously, on a linear frequency scale BFs appear biased to lower frequencies, with 20–40 kHz overrepresented. However, on a hyperbolic frequency (linear period) scale BFs appear more uniformly distributed, with little overrepresentation. The cumulative proportion of BFs in FM₁ and FM₂ bands reconstructs a scaled version of the spectrogram of FM broadcasts. Correcting FM latencies for absolute BF latencies and BF time-in-sweep reveals a subset of IC cells which respond dynamically to the timing of their BFs in FM sweeps. Behaviorally, Eptesicus perceives echo delay and phase with microsecond or even submicrosecond accuracy and resolution, but even with use of phase-locked FM and tone-burst stimuli the cell-by-cell precision of IC time-frequency registration seems inadequate by itself to account for the temporal acuity exhibited by the bat. Accepted: 21 June 1997     

Sensitivity to interaural time difference and representation of azimuth in central nucleus of inferior colliculus in the barn owl

Standard electrophysiology and virtual auditory stimuli were used to investigate the influence of interaural time difference on the azimuthal tuning of neurons in the core and the lateral shell of the central nucleus of the inferior colliculus of the barn owl. The responses of the neurons to virtual azimuthal stimuli depended in a periodic way on azimuth. Fixation of the interaural time difference, while leaving all other spatial cues unchanged, caused a loss of periodicity and a broadening of azimuthal tuning. This effect was studied in more detail in neurons of the core. The azimuthal range tested and the frequency selectivity of the neurons were additional parameters influencing the changes induced by fixating the interaural time difference. The addition of an interaural time difference to the virtual stimuli resulted in a shift of the tuning curves that correlated with the interaural time difference added. In this condition, tuning strength did not change. These results suggest that interaural time difference is an important determinant of azimuthal tuning in all neurons of the core and lateral shell of the central nucleus of the inferior colliculus, and is the only determinant in many of the neurons from the core.     

The survival of mouse oocytes shows little or no correlation with the vitrification or freezing of the external medium,but the ability of the medium to vitrify is affected by its solute concentration and by the cooling rate

As survival of mouse oocytes subjected to vitrification depends far more on the warming rate than on the cooling rate, we wished to determine whether the lack of correlation between survival and cooling rate was mirrored by a lack of correlation between cooling rate and vitrification of the medium (EAFS), and between survival and the vitrification of the medium. The morphological and functional survival of the oocytes showed little or no relation to whether or not the EAFS medium vitrified or froze. We studied if the droplet size and the elapsed time (between placing the droplet on the Cryotop and the start of cooling) affects the result through modification of the cooling rate and solute concentration. Dehydration was rapid; consequently, the time between the placing the droplets into a Cryotop and cooling must be held to a minimum. The size of the EAFS droplet that is being cooled does not seem to affect vitrification. Finally, the degree to which samples of EAFS vitrify is firmly dependent on both its solute concentration and the cooling rate.