Stafstrom C E, Schwindt P C, Crill W E
J Neurophysiol. 1984 Aug;52(2):264-77. doi: 10.1152/jn.1984.52.2.264.
Input-output relations of large neurons from layer V of cat sensorimotor cortex were studied in an in vitro slice preparation using steps and ramps of intracellularly injected current. Depolarization attained during the interspike interval (ISI) was compared to the voltage levels required to activate a previously described (29) persistent sodium current (INaP). INaP was studied using a single-electrode voltage clamp in the same cells tested for firing behavior. Following an injected current step, firing rate declined smoothly to a steady level with a time course that was approximately exponential in most cells (tau, 9-43 ms). In most cells, the relation between firing rate and injected current (f-I relation) consisted of two linear segments, both for adapted, steady firing and for early intervals during adaptation. The slope of the steeper, initial (or sole) linear segment of the f-I curve averaged 26.2 Hz/nA during steady firing and was steeper when plotted for early interspike intervals. The variation of the depolarization at which spike initiation occurred (firing level) and the membrane potential between rhythmic spikes was examined during adaptation and steady firing. In most cells, firing level rose rapidly during a rhythmic train to a steady value. The steady firing level attained remained unchanged over a wide range of steady firing rates. Nevertheless, the mean depolarization during the interspike interval (V) increased approximately linearly with steady firing rate. Even at the slowest firing rates, V is sufficient to activate INaP. The use of injected current ramps demonstrated that neocortical cells were sensitive to rate of change of stimulus current (dI/dt) as well as its amplitude (I). The use of ramps followed by steady currents demonstrated that the repetitive response lagged behind changes in stimulus parameters and did not reach a steady state even during slow ramps; i.e., the response depended on time as well as on I and dI/dt. Instantaneous firing rate during the ramp increased linearly with time for a wide range of ramp slopes (dI/dt). The instantaneous firing rate of early interspike intervals was also linearly related to ramp slope for small ramp slopes. In spite of these linear relationships, quantitative analysis indicated that firing rate during ramp stimulation cannot, in general, be described by a simple linear combination of separate amplitude- and rate-dependent terms. The repetitive firing properties of the in vitro neurons are compared to those of in vivo neocortical neurons and other cell types.(ABSTRACT TRUNCATED AT 400 WORDS)
利用细胞内注入电流的阶跃和斜坡,在体外脑片标本中研究了猫感觉运动皮层V层大神经元的输入-输出关系。将峰间期(ISI)期间达到的去极化与激活先前描述的(29)持续性钠电流(INaP)所需的电压水平进行比较。在测试放电行为的相同细胞中,使用单电极电压钳研究INaP。注入电流阶跃后,放电频率平滑下降至稳定水平,在大多数细胞中,其时程近似指数形式(时间常数τ为9 - 43毫秒)。在大多数细胞中,放电频率与注入电流的关系(f-I关系)在适应后的稳定放电以及适应早期阶段均由两个线性部分组成。f-I曲线较陡的初始(或唯一)线性部分的斜率在稳定放电期间平均为26.2 Hz/nA,在早期峰间期绘制时更陡。在适应和稳定放电期间,检查了峰起始时的去极化变化(放电水平)以及节律性峰之间的膜电位。在大多数细胞中,在节律性串刺激期间放电水平迅速上升至稳定值。在很宽的稳定放电频率范围内,达到的稳定放电水平保持不变。然而,峰间期的平均去极化(V)随稳定放电频率近似线性增加。即使在最慢的放电频率下,V也足以激活INaP。注入电流斜坡的使用表明,新皮层细胞对刺激电流的变化率(dI/dt)及其幅度(I)均敏感。使用斜坡后接稳定电流表明,重复反应滞后于刺激参数的变化,即使在缓慢斜坡期间也未达到稳态;即,反应既取决于时间也取决于I和dI/dt。在很宽的斜坡斜率(dI/dt)范围内,斜坡期间的瞬时放电频率随时间线性增加。对于小斜坡斜率,早期峰间期的瞬时放电频率也与斜坡斜率线性相关。尽管存在这些线性关系,但定量分析表明,斜坡刺激期间的放电频率通常不能用单独的幅度和频率相关项的简单线性组合来描述。将体外神经元的重复放电特性与体内新皮层神经元和其他细胞类型的特性进行了比较。(摘要截短至400字)
