在前面介绍模型的基础上,本文考虑温度对神经元动作电位变化的影响。
Base on the model we have introduced previously, we consider the effect of temperature to neuronal action potential.
频率和强度是声音的两个重要参数,通常以听觉神经元动作电位发放频次编码这两个参数。
Frequency and intensity are two of the important parameters of sounds. Many researchers use spike rate of auditory neurons to represent the two parameters generally.
这套系统包括神经元动作仿真系统、神经元动作电位传导仿真系统、神经元自激振荡仿真系统。
This whole system includes the neurons action simulation system, neurons action potential conduction simulation system, and neurons self-excited oscillation simulation system.
动作电位以不衰减的方式长距离传播,使神经元实现其生物电信息的长距离传播功能。
The action potential can propagate over long distance without weakening, and makes the neuron realize the long distance transmission of neural information.
这些诱导的神经细胞表达多种神经元特异性蛋白,产生动作电位,形成功能性突触。
These induced neuronal (in) cells express multiple neuron-specific proteins, generate action potentials and form functional synapses.
本文的研究结果可直接扩展到大规模的神经元网络,研究动作电位的传导与作用规律。
The result of this thesis can be used in the large neuron networks to analyse the essence of action potential conducting and process.
神经元是神经系统的基本单元,动作电位是神经系统传递外界刺激并传达中枢神经系统所做出的反应的电信号。
Neuron is the basic unit of the nervous system, and the action potential is used to passed on external stimulating signal and communicate the response signal of the central nervous system.
这种信号是种动作电位,和我们大脑神经元用于交换信息的信号是同一种信号。
The signals that you are seeing here are action potential, are the same signals that the neurons of my brain, of our brain, use to exchange information.
目的分析培养神经元网络对不同时间间隔电脉冲刺激动作电位发放的影响。
Objective to analyze the activities of cultured neuronal network in response to electric pulses stimuli with different intervals.
以往对神经元电生理基本性质的研究中,发现了神经元产生动作电位具有多种不同排列组合的时间模式,也称为放电模式。
In the past study of basic electrophysiological properties of neurons it is found that action potentials have many types of timing pattern, which is also termed as firing pattern.
我们与其他人的研究至此得出了结论:神经胶细胞藉著侦测由激发轴突释放或是从突触渗漏的AT P,而能知道神经元产生了动作电位。
To THIS POINT, work by us and others had led to the conclusion that a glial cell senses neuronal action potentials by detecting ATP that is either released by a firing axon or leaked from the synapse.
这些结果表明具有各种时间结构的动作电位序列会在初级传入纤维与脊髓背角神经元之间进行突触传递。
These results indicate that spike trains with various temporal structures will be synaptically transmitted between primary afferent fiber and spinal dorsal horn neuron.
结果从螺旋神经元记录到动作电位,螺旋神经元具有不一致的放电特征。
Results the action potential was recorded from the spiral ganglion neurons. The neurons had non-uniform firing characteristics.
结果发现,多串电刺激后,大鼠海马CA 1神经元爆发式放电数量明显增加,且动作电位个数大于3的爆发式放电数目也明显增多。
The results revealed that the bursting number were increased after several strain stimuli. And the bursting number of action potentials more than 3 were increased also.
考虑到来自不同神经元的动作电位在时域或频域特征上的相似性,引入小波分析在时频域上对动作电位进行特征描述。
To deal with the similarity of spike temporal profile and frequency feature, a method was proposed to represent spike feature using wavelet analysis technique.
考虑到来自不同神经元的动作电位在时域或频域特征上的相似性,引入小波分析在时频域上对动作电位进行特征描述。
To deal with the similarity of spike temporal profile and frequency feature, a method was proposed to represent spike feature using wavelet analysis technique.
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