Kim Hojeong, Major Lora A, Jones Kelvin E
Department of Biomedical Engineering, University of Alberta, Edmonton, AB T6G 2V2, Canada.
J Comput Neurosci. 2009 Dec;27(3):321-36. doi: 10.1007/s10827-009-0145-7. Epub 2009 Apr 22.
Spinal motor neurons have voltage gated ion channels localized in their dendrites that generate plateau potentials. The physical separation of ion channels for spiking from plateau generating channels can result in nonlinear bistable firing patterns. The physical separation and geometry of the dendrites results in asymmetric coupling between dendrites and soma that has not been addressed in reduced models of nonlinear phenomena in motor neurons. We measured voltage attenuation properties of six anatomically reconstructed and type-identified cat spinal motor neurons to characterize asymmetric coupling between the dendrites and soma. We showed that the voltage attenuation at any distance from the soma was direction-dependent and could be described as a function of the input resistance at the soma. An analytical solution for the lumped cable parameters in a two-compartment model was derived based on this finding. This is the first two-compartment modeling approach that directly derived lumped cable parameters from the geometrical and passive electrical properties of anatomically reconstructed neurons.
脊髓运动神经元在其树突中具有电压门控离子通道,这些通道可产生平台电位。用于产生动作电位的离子通道与产生平台电位的通道在物理上的分离可导致非线性双稳态放电模式。树突的物理分离和几何形状导致树突与胞体之间的不对称耦合,而在运动神经元非线性现象的简化模型中尚未涉及这一点。我们测量了六个经解剖重建和类型鉴定的猫脊髓运动神经元的电压衰减特性,以表征树突与胞体之间的不对称耦合。我们发现,在距胞体任何距离处的电压衰减都与方向有关,并且可以描述为胞体输入电阻的函数。基于这一发现,推导了两室模型中集总电缆参数的解析解。这是第一种直接从经解剖重建的神经元的几何和被动电学特性中推导集总电缆参数的两室建模方法。