大鼠初级体感皮层后肢代表区的神经回路和时间可塑性:脑片多电极阵列的再研究。
Neural circuits and temporal plasticity in hindlimb representation of rat primary somatosensory cortex: revisited by multi-electrode array on brain slices.
机构信息
Institute for Biomedical Sciences of Pain, Capital Medical University, Beijing 100069, China.
出版信息
Neurosci Bull. 2010 Jun;26(3):175-87. doi: 10.1007/s12264-010-0308-6.
OBJECTIVE
The well-established planar multi-electrode array recording technique was used to investigate neural circuits and temporal plasticity in the hindlimb representation of the rat primary somatosensory cortex (S1 area).
METHODS
Freshly dissociated acute brain slices of rats were subject to constant perfusion with oxygenated artificial cerebrospinal fluid (95% O(2) and 5% CO(2)), and were mounted on a Med64 probe (64 electrodes, 8x8 array) for simultaneous multi-site electrophysiological recordings. Current sources and sinks across all the 64 electrodes were transformed into two-dimensional current source density images by bilinear interpolation at each point of the 64 electrodes.
RESULTS
The local intracortical connection, which is involved in mediation of downward information flow across layers II-VI, was identified by electrical stimulation (ES) at layers II-III. The thalamocortical connection, which is mainly involved in mediation of upward information flow across layers II-IV, was also characterized by ES at layer IV. The thalamocortical afferent projections were likely to make more synaptic contacts with S1 neurons than the intracortical connections did. Moreover, the S1 area was shown to be more easily activated and more intensively innervated by the thalamocortical afferent projections than by the intracortical connections. Finally, bursting conditioning stimulus (CS) applied within layer IV of the S1 area could successfully induce long-term potentiation (LTP) in 5 of the 6 slices (83.3%), while the same CS application at layers II-III induced no LTP in any of the 6 tested slices.
CONCLUSION
The rat hindlimb representation of S1 area is likely to have at least 2 patterns of neural circuits on brain slices: one is the intracortical circuit (ICC) formed by interlaminar connections from layers II-III, and the other is the thalamocortical circuit (TCC) mediated by afferent connections from layer IV. Besides, ICC of the S1 area is spatially limited, with less plasticity, while TCC is spatially extensive and exhibits a better plasticity in response to somatosensory afferent stimulation. The present data provide a useful experimental model for further studying microcircuit properties in S1 cortex at the network level in vitro.
目的
采用成熟的平面多电极阵列记录技术,研究大鼠初级体感皮层(S1 区)后肢代表区的神经回路和时变可塑性。
方法
新鲜分离的急性脑片在含氧人工脑脊液(95% O2 和 5% CO2)中持续灌流,并置于 Med64 探头(64 个电极,8x8 阵列)上进行同时多部位电生理记录。通过在 64 个电极的每个点进行双线性插值,将所有 64 个电极的电流源和电流汇转换为二维电流源密度图像。
结果
通过在 II-III 层进行电刺激(ES),确定了涉及 II-VI 层之间下行信息流中介的皮层内局部连接。通过在 IV 层进行 ES,还确定了主要涉及 II-IV 层之间上行信息流中介的丘脑皮质连接。丘脑皮质传入投射与 S1 神经元形成的突触接触可能比皮层内连接更多。此外,S1 区比皮层内连接更容易被丘脑皮质传入投射激活和密集支配。最后,在 S1 区 IV 层施加爆发条件刺激(CS)可在 6 个切片中的 5 个(83.3%)中成功诱导长时程增强(LTP),而在 6 个测试切片中的任何一个中,相同的 CS 应用在 II-III 层均未诱导 LTP。
结论
在脑片上,大鼠 S1 区后肢代表区可能至少有 2 种神经回路模式:一种是由 II-III 层之间的层间连接形成的皮层内回路(ICC),另一种是由 IV 层传入连接介导的丘脑皮质回路(TCC)。此外,S1 区的 ICC 空间有限,可塑性较小,而 TCC 空间广泛,对体感传入刺激的反应具有更好的可塑性。本研究为进一步在体外研究 S1 皮层网络水平的微回路特性提供了一个有用的实验模型。
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