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通过对回声定位蝙蝠帕氏叶鼻蝠(Pteronotus parnelli parnelli)前扣带回皮层进行微刺激所展示的声音频率地形图。

Topographic representation of vocal frequency demonstrated by microstimulation of anterior cingulate cortex in the echolocating bat, Pteronotus parnelli parnelli.

作者信息

Gooler D M, O'Neill W E

出版信息

J Comp Physiol A. 1987 Aug;161(2):283-94. doi: 10.1007/BF00615248.

DOI:10.1007/BF00615248
PMID:3625577
Abstract
  1. A midline region of brain dorsal and anterior to the corpus callosum, presumably anterior cingulate cortex, has been explored for its role in the production of vocalization in the mustached bat, Pteronotus p. parnelli. 2. Vocalizations elicited by microstimulation were virtually indistinguishable from natural biosonar sounds. The spectral content, relative intensity of harmonic components, and durations of emitted pulses are comparable to spontaneous emissions. 3. The frequencies of elicited vocalizations were within the range typically used by the mustached bat during Doppler-shift compensation. The frequency of the second-harmonic constant-frequency component (CF2) covered the range from 57-62 kHz, but was most commonly emitted at frequencies of 59-61 kHz. 4. An increase in the frequency of vocalizations over a number of consecutive pulses towards a steady-state plateau is evident in both spontaneous vocalizations and emissions elicited by microstimulation just above threshold. Increasing the stimulus intensity caused the frequency of emissions to approach the steady state more rapidly. 5. The anterior cingulate cortex appears to be organized topographically for increasing frequency of elicited biosonar sounds along a rostrocaudal axis. The area from which biosonar emissions were elicited was overrepresented for a 2 kHz band of frequencies just below the bats' CF2 resting frequency. Audible vocalizations with a complex spectrum resembling social cries can also be elicited by microstimulation, but only in an area that is adjacent and posterior to the biosonar region. 6. Some examples of both elicited and spontaneous vocalizations contained a relative intensity pattern of the harmonic components which deviated from the typical pattern. This suggests that mustached bats are capable of actively altering the spectrum of their pulses to subserve different tasks in echolocation.
摘要
  1. 对大脑中位于胼胝体背侧和前方的中线区域(推测为前扣带回皮质)在髯蝠(Pteronotus p. parnelli)发声产生过程中的作用进行了研究。2. 微刺激引发的发声与自然生物声纳声音几乎无法区分。其频谱内容、谐波成分的相对强度以及发出脉冲的持续时间与自发发射相当。3. 引发的发声频率在髯蝠进行多普勒频移补偿时通常使用的范围内。二次谐波恒频成分(CF2)的频率范围为57 - 62千赫兹,但最常以59 - 61千赫兹的频率发出。4. 在自发发声以及刚好高于阈值的微刺激引发的发射中,连续多个脉冲的发声频率朝着稳态平台增加是明显的。增加刺激强度会使发射频率更快地接近稳态。5. 前扣带回皮质似乎在沿头尾轴方向上呈拓扑组织,以增加引发的生物声纳声音的频率。引发生物声纳发射的区域在低于蝙蝠CF2静息频率2千赫兹的频率带中占比过高。通过微刺激也能引发频谱复杂、类似社交叫声的可听发声,但仅在与生物声纳区域相邻且靠后的区域。6. 引发的和自发的发声的一些例子包含谐波成分的相对强度模式,该模式偏离了典型模式。这表明髯蝠能够主动改变其脉冲频谱以服务于回声定位中的不同任务。

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