代谢型输入的动态平衡导致背角神经元切换功能状态。

Dynamic balance of metabotropic inputs causes dorsal horn neurons to switch functional states.

作者信息

Derjean Dominique, Bertrand Sandrine, Le Masson Gwendal, Landry Marc, Morisset Valérie, Nagy Frédéric

机构信息

INSERM E0358, Physiopathologie des Réseaux Neuronaux Médullaires, Institut François Magendie, Université Bordeaux 2, Bordeaux, France.

出版信息

Nat Neurosci. 2003 Mar;6(3):274-81. doi: 10.1038/nn1016.

DOI:10.1038/nn1016

PMID:12592405

Abstract

Sensory relay structures in the spinal cord dorsal horn are now thought to be active processing structures that function before supraspinal sensory integration. Dorsal horn neurons directly receive nociceptive (pain) signals from the periphery, express a high degree of functional plasticity and are involved in long-term sensitization and chronic pain. We show here that deep dorsal horn neurons (DHNs) in Wistar rats can switch their intrinsic firing properties from tonic to plateau or endogenous bursting patterns, depending upon the balance of control by metabotropic glutamate (mGlu) and GABA(B) receptors. We further show that this modulation acts on at least one common target, the inwardly rectifying potassium channel (Kir3). Finally, we found that these firing modes correspond to specific functional states of information transfer in which dorsal horn neurons can faithfully transmit, greatly enhance or block the transfer of nociceptive information.

摘要

脊髓背角中的感觉中继结构现在被认为是活跃的处理结构，在脊髓上感觉整合之前发挥作用。背角神经元直接从外周接收伤害性（疼痛）信号，表现出高度的功能可塑性，并参与长期致敏和慢性疼痛。我们在此表明，Wistar大鼠的深层背角神经元（DHNs）可以根据代谢型谷氨酸（mGlu）和GABA(B)受体的控制平衡，将其内在放电特性从紧张型转换为平台型或内源性爆发型模式。我们进一步表明，这种调节作用于至少一个共同靶点，即内向整流钾通道（Kir3）。最后，我们发现这些放电模式对应于信息传递的特定功能状态，其中背角神经元可以忠实地传递、极大地增强或阻断伤害性信息的传递。

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代谢型输入的动态平衡导致背角神经元切换功能状态。

Dynamic balance of metabotropic inputs causes dorsal horn neurons to switch functional states.

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