Chomiak T, Hu B
Division of Experimental Neurosciences, Department of Clinical Neurosciences, Hotchkiss Brain Institute, University of Calgary, Calgary, Alberta, Canada.
J Physiol. 2007 Mar 1;579(Pt 2):403-12. doi: 10.1113/jphysiol.2006.124057. Epub 2006 Dec 14.
Antidromic cortical excitation has been implicated as a contributing mechanism for high-frequency deep brain stimulation (DBS). Here, we examined the reliability of antidromic responses of type 2 corticofugal fibres in rat over a stimulation frequency range compatible to the DBS used in humans. We activated antidromically individual layer V neurones by stimulating their two subcortical axonal branches. We found that antidromic cortical excitation is not as reliable as generally assumed. Whereas the fast conducting branches of a type 2 axon in the highly myelinated brainstem region follow high-frequency stimulation, the slower conducting fibres in the poorly myelinated thalamic region function as low-pass filters. These fibres fail to transmit consecutive antidromic spikes at the beginning of high-frequency stimulation, but are able to maintain a steady low-frequency (6-12 Hz) spike output during the stimulation. In addition, antidromic responses evoked from both branches are rarely present in cortical neurones with a more hyperpolarized membrane potential. Our data indicate that axon-mediated antidromic excitation in the cortex is strongly influenced by the myelo-architecture of the stimulation site and the excitability of individual cortical neurones.
逆行性皮质兴奋被认为是高频深部脑刺激(DBS)的一种促成机制。在此,我们研究了大鼠2型皮质传出纤维在与人类所用DBS兼容的刺激频率范围内逆行反应的可靠性。我们通过刺激单个V层神经元的两个皮质下轴突分支来逆向激活它们。我们发现,逆行性皮质兴奋并不像通常所认为的那样可靠。虽然2型轴突在高度髓鞘化的脑干区域的快速传导分支能跟随高频刺激,但在髓鞘化程度较差的丘脑区域的较慢传导纤维起到低通滤波器的作用。这些纤维在高频刺激开始时无法传递连续的逆行冲动,但在刺激期间能够维持稳定的低频(6 - 12赫兹)冲动输出。此外,在膜电位更超极化的皮质神经元中,很少出现从两个分支诱发的逆行反应。我们的数据表明,皮质中轴突介导的逆行兴奋受到刺激部位的髓鞘结构和单个皮质神经元兴奋性的强烈影响。