期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

大鼠耳蜗背核神经元第一动作电位延时的特性

The Characteristics of the First Spike Latency in the Rat Dorsal Cochlear Nucleus
下载PDF
导出
摘要 目的:探讨大鼠耳蜗背核神经元第一动作电位延时的特性。方法:采用在体细胞外记录方法,通过给予单耳不同频率和声强的短纯音刺激,记录成年SD大鼠耳蜗背核神经元反应,并分别以动作电位发放数(spike counts,SC)和第一动作电位延时(first spike latency,FSL)为评价指标,分析比较它们对同一刺激的反应稳定性。结果:共记录到21个单单位(single-unit)神经元反应。这些神经元均以burst spikes这种多放电率的形式发放。以发放数为评价指标,这些神经元分别表现出单调(76%)、饱和(19%)和非单调(5%)三种声强反应。而第一动作电位延时展示出同一规律的FSL-声强反应曲线:FSL随着声强的增大而缩短。SC-频率曲线呈现多形性,而FSL-频率曲线呈"V"字型。结论:在大鼠耳蜗背核神经元,相比发放数,第一动作电位延时对同一刺激的反应稳定性更好。 Objective: To evaluate the characteristics of the first spike latency in the rat dorsal cochlear nucleus.Methods: Using extracellular recording methods,we recorded the dorsal cochlear nucleus on adult SD rats by giving unilateral ear at different frequencies and intensities stimulation.Both Spike counts(SC) and First spike latency(FSL) were evaluated,then comparing their stability to the same stimuli.Results: A number of 21 single-unit neurons were recorded.SC-amplitude functions are classified as the monotonic(76%),saturated(19%) and non-monotonic(5%).While FSL show the same regular FSL-Amplitude functions:FSL reduced monotonically with the increace of amplitude.SC-Frequency curves show pleomorphism,while FSL-Frequency function display the shape of "V".Conclusion: Compared with spike counts(SC),First spike latency(FSL) can display the response of acoustic stimulation better in the rat dorsal cochlear nucleus.
作者 刘萍 熊铁根 傅鸣宇 肖中举
机构地区 广州南方医科大学生理学教研室 广州市三九脑科医院神经内科
出处 《数理医药学杂志》 2011年第1期28-32,共5页 Journal of Mathematical Medicine
基金 国家自然科学基金项目(30670665 30730039 30570571)
关键词 第一动作电位延时 发放数 在体细胞外记录 耳蜗背核 first spike latency spike counts extracelluar recording dorsal cochlear nucleus
分类号 R339.16 [医药卫生—人体生理学]
  • 相关文献

参考文献18

  • 1Heil, P. First spike latency of auditory neurons revisited. Review. Curr. Opin. Neurobiol. 2004. 14(4)461-467.
  • 2VanRullen R, Guyonneau R, Thorpe, S. J. Spike times make sense. Trends. Neurosci. 2005,28 (1) : 1-4.
  • 3Tan X, Wang X, Yang W, et al. First spike latency and spike count as functions of tone amplitude and frequency in the inferior colliculus of mice. Hear Res, 2008,235(1- 2)90-104.
  • 4Paul G. Finlayson,James A. Kaltenbach. Alterations in the sponta neous discharge patterns of single units in the dorsal cochlear nucleus following intense sound exposure. Hearing Res, 2009, 256- 1044117.
  • 5Eggermont, J. J,Mossop,J. E. Azimuth coding in primary auditory cortex of the cat. I. Spike synchrony versus spike count represen tation . J Neurophysiology. 1998,80(4) 2133-2150.
  • 6Furukawa,S,Middlebrooks,J. C. Cortical representation of audito ry space: information-bearing features of spike patterns. J. Neurophysiol,2002,87(4)1749-1762.
  • 7Aikin, L. Rate-level functions of neurons in the inferior colliculus of cats measured with the use of free-field sound stimuli. J. Neurophysiol, 1991,65 - 383-392.
  • 8Suga, N. Amplitude spectrum representation in the Doppler-shifted CF processing area.of the auditory cortex of the mustache, bat. Science. 1977,196 (4285) : 64-67.
  • 9Sutter,M. L. Schreiner,C. E. Topography of intensity tuning in cat primary auditory cortex: single--neuron versus multiple-neuron recordings. J. Neurophysiol. 1995,73(1) : 190-204.
  • 10S. E. Shore,S. Koehler. Dorsal cochlear neucleus responses to so matosensory stimulation are enhanced after noise-induced hearing loss. Eur J Neurosci,2008, 27(1) : 155-168.

二级参考文献66

  • 1Aitkin,L.M.,Blake,D.W.,Fryman,S.& Bock,G.R.Responses of neurons in the rabbit inferior colliculus II.Influence of binaural tonal stimuli.Brain Res,1972,47:91-101.
  • 2Aitkin,L.M.,Webster,W.R.,Veale,J.L.& Crosby,D.C.Inferior colliculus.I.Comparison of response properties of neurons in central,pericentral and external nuclei of adult cat.J.Neurophysiol,1975,38:1196-1207.
  • 3Astl,J.,Popelár,J.,Kvasnak,E.& Syka,J.Comparison of response properties of neurons in the inferior colliculus of guinea pigs under different anesthetics.Audiology,1996,35:335-345.
  • 4Batra,R.,Kuwada,S.& Stanford,T.R.Temporal coding of envelopes and their interaural delays in the inferior colliculus of the unanesthetized rabbit.J.Neurophysiol,1989,61:257-268.
  • 5Batra,R.,Kuwada,S.& Stanford,T.R.High‐frequency neurons in the inferior colliculus that are sensitive to interaural delays of amplitude‐modulated tones:Evidence for dual binaural influences.J.Neurophysiol,1993,70:64-80.
  • 6Blatchley,B.J.& Brugge,J.F.Sensitivity to binaural intensity and phase difference cues in kitten inferior colliculus.J.Neurophysiol,1990,64:582-597.
  • 7Carlile,S.The physical and psychophysical basis of sound localization.In:Carlile,S,ed..Virtual Auditory Space:Generation and Applications.Landes,Austin,1996:27-78.
  • 8Heil,P.Auditory cortical onset responses revisited.I.First spike timing.J.Neurophysiol,1997,77 (5):2616-2642.
  • 9Heil,P.,Neubauer,H.Temporal integration of sound pressure determines thresholds of auditory-nerve fibers.J.Neurosci,2001,21(18):7404-7415.
  • 10Heil,P.,Neubauer,H.A unifying basis of auditory thresholds based on temporal summation.Proc.Natl.Acad.Sci.USA,3002,100(10):6151-6156.

共引文献4

数理医药学杂志
2011年 第1期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部