Melzer Peter, Champney Gregory C, Maguire Mark J, Ebner Ford F
Department of Psychology, Vanderbilt University, 301 Wilson Hall, 111 21st Ave. S, Nashville, TN 37203, USA.
Exp Brain Res. 2006 Jul;172(3):370-86. doi: 10.1007/s00221-005-0334-1. Epub 2006 Feb 3.
We recorded responses to frequencies of whisker stimulation from 479 neurons in primary (S1) and secondary (S2) somatic sensory cortex of 26 urethane-anesthetized rats. Five whiskers on the right side of the snout were deflected with air puffs at seven frequencies between 1 and 18/s. In left S1 (barrels and septa) and S2, subsets of neurons (5%) responded to whisker stimulation across the entire range of frequencies with > or = 1 electrical discharges/ten stimuli (full responders). In contrast, 60% of the recorded cells responded above threshold only at stimulus frequencies below 6/s and 35% remained subthreshold at all frequencies tested. Thus, the full responders are unique in that they were always responsive and appeared particularly suited to facilitate a dynamic, broadband processing of stimulus frequency. Full responders were most responsive at 1 stimulus/s, and showed greatest synchrony with whisker motion at 18 stimuli/s. The barrel cells responded with the greatest temporal accuracy between 3 and 15 stimuli/s. The septum cells responded less accurately, but maintained their accuracy at all frequencies. Only septum cells continued to increase their discharge rate with increasing stimulus frequency. The S2 cells discharged with lowest temporal accuracy modulated only by stimulus frequencies < or = 6/s and exhibited the steepest decrease in discharge/stimulus with increasing stimulus frequency. Our observations suggest that full responders in the septa are well suited to encode high frequencies of whisker stimulation in timing and rate of discharge. The barrel cells, in contrast, showed the strongest temporal coding at stimulus frequencies in the middle range, and S2 cells were most sensitive to differences in low frequencies. The ubiquitous decline in discharge/stimulus in S1 and S2 may explain the decrease in blood flow observed at increasing stimulus frequency with functional imaging.
我们记录了26只经乌拉坦麻醉的大鼠初级躯体感觉皮层(S1)和次级躯体感觉皮层(S2)中479个神经元对不同频率触须刺激的反应。用气流以1至18次/秒之间的7种频率吹拂口鼻右侧的5根触须。在左侧S1(桶状区和隔区)和S2中,有一部分神经元(5%)在整个频率范围内对触须刺激有反应,每十次刺激产生≥1次放电(完全反应者)。相比之下,60%的记录细胞仅在刺激频率低于6次/秒时反应阈值以上,35%的细胞在所有测试频率下均低于阈值。因此,完全反应者的独特之处在于它们始终有反应,似乎特别适合于促进对刺激频率的动态宽带处理。完全反应者在1次/秒的刺激频率下反应最强烈,在18次/秒的刺激频率下与触须运动同步性最强。桶状细胞在3至15次/秒的刺激频率之间反应的时间准确性最高。隔区细胞反应准确性较低,但在所有频率下都能保持其准确性。只有隔区细胞随着刺激频率增加继续提高其放电率。S2细胞放电的时间准确性最低,仅受≤6次/秒的刺激频率调节,并且随着刺激频率增加,每次刺激的放电量下降最为明显。我们的观察结果表明,隔区中的完全反应者非常适合在放电时间和放电率方面对高频触须刺激进行编码。相比之下,桶状细胞在中等范围的刺激频率下表现出最强的时间编码,而S2细胞对低频差异最敏感。S1和S2中每次刺激放电量普遍下降,这可能解释了功能成像中随着刺激频率增加观察到的血流量减少现象。
