Ono Kentaro, Kudoh Masaharu, Shibuki Katsuei
Department of Neurophysiology, Brain Research Institute, Niigata University, 1 Asahi-machi, Niigata 951-8585, Japan.
Eur J Neurosci. 2006 Mar;23(6):1623-32. doi: 10.1111/j.1460-9568.2006.04695.x.
We investigated the roles of the auditory cortex in sound discrimination learning in Wistar rats. Absolute pitch or relative pitch can be used as discrimination cues in sound frequency discrimination. To clarify this, rats were trained to discriminate between rewarded (S+) and unrewarded (S-) test stimuli (S+ frequency>S- frequency). After learning was acquired by rats, performance was tested in a new test in which S+ frequency was constant but S+ frequency<S- frequency, or S+ frequency>S- frequency but both frequencies were increased. If the discrimination cue of the first test was preserved in the new test, performance following change of testing procedures was expected to remain high. The measured performance suggested that rats used relative pitch in half octave discrimination (difference between S+ and S- frequencies, 0.5 octave), and absolute pitch in octave discrimination (difference between S+ and S- frequencies, 1.0 octave). Bilateral lesions in the auditory cortex had almost no effect on performance before procedure change. Furthermore, performance following procedure change was not affected by lesions in the auditory cortex when the discrimination cue was preserved. However, performance was impaired by lesions in the auditory cortex when a new discrimination cue was used following procedure change. Lesions in the auditory cortex also impaired multimodal discrimination between sound and sound plus light. The present findings suggest that the auditory cortex plays a role as a sensory interface of the higher cortices required for flexible learning and multimodal discrimination.
我们研究了听觉皮层在Wistar大鼠声音辨别学习中的作用。在声音频率辨别中,绝对音高或相对音高可作为辨别线索。为了阐明这一点,训练大鼠区分有奖励(S+)和无奖励(S-)的测试刺激(S+频率>S-频率)。大鼠习得后,在新测试中进行表现测试,其中S+频率恒定但S+频率<S-频率,或者S+频率>S-频率但两个频率都增加。如果第一个测试的辨别线索在新测试中得以保留,那么测试程序改变后的表现预计仍会很高。测量的表现表明,大鼠在半音程辨别(S+和S-频率之差为0.5个八度)中使用相对音高,在全音程辨别(S+和S-频率之差为1.0个八度)中使用绝对音高。听觉皮层的双侧损伤在程序改变前对表现几乎没有影响。此外,当辨别线索得以保留时,程序改变后的表现不受听觉皮层损伤的影响。然而,当程序改变后使用新的辨别线索时,听觉皮层损伤会损害表现。听觉皮层损伤还会损害声音与声音加光之间的多模态辨别。目前的研究结果表明,听觉皮层作为灵活学习和多模态辨别所需的高级皮层的感觉接口发挥作用。