Macroscopic and Subcellular Factors Shaping Population Spikes

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Macroscopic and Subcellular Factors Shaping Population Spikes

P. Varona,¹ J. M. Ibarz,² L. López-Aguado,² and O. Herreras²

¹Departamento de Ingeniería Informática, Universidad Autónoma de Madrid, 28049 Madrid; and ²Departamento Investigación, Hospital Ramón y Cajal, 28034 Madrid, Spain

Varona, P., J. M. Ibarz, L. López-Aguado, and O. Herreras. Macroscopic and Subcellular Factors Shaping Population Spikes. J. Neurophysiol. 83: 2192-2208, 2000. Population spikes (PS) are built by the extracellular summation of action currents during synchronous action potential (AP)firing. In the hippocampal CA1, active dendritic invasion of APsensures mixed contribution of somatic and dendritic currents toany extracellular location. We investigated the macroscopic andsubcellular factors shaping the antidromic PS by fitting its spatiotemporalmap with a multineuronal CA1 model in a volume conductor. Decreasedsummation by temporal scatter of APs reduced less than expectedthe PS peak in the stratum pyramidale (st. pyr.) but stronglyincreased the relative contribution of far dendritic currents.Increasing the number of firing cells also augmented the relativedendritic contribution to the somatic PS, an effect caused bythe different waveform of somatic and dendritic unitary transmembranecurrents (I_m). Those from somata are short-lasting and spiky,having smaller temporal summation than those from dendrites, whichare smoother and longer. The different shape of compartmentalI_ms is imposed by the fitting of backpropagating APs, which arelarge and fast at the soma and smaller and longer in dendrites.The maximum sodium conductance (_Na) strongly affects the unitaryAPs at the soma, but barely the PS at the stratum pyramidale (st.pyr.). This occurred because somatic I_m saturated at low _Nadue to the strong reduction of driving force during somatic APs,limiting the current contribution to the extracellular space.On the contrary, _Na effectively defined the PS amplitude inthe st. radiatum. The relative contribution of dendritic currentsto the st. pyr. increases during the time span of the PS, from~30-40% at the peak up to 100% at its end, a pattern resultantfrom the timing of active inward currents along the somatodendriticaxis, which delay during backpropagation. Extreme changes imposedon dendritic currents caused only moderate effects on the st.pyr. due to reciprocal shunting of active soma and dendrites thatpartially counterbalance the net amount of instant current. Theamplitude of the PS follows an inverse relation to the internalresistance (R_i), which turned out to be a most critical factor.Low R_i facilitated the spread of APs into dendrites and acceleratedtheir speed, increasing temporal overlapping of inward currentsalong the somatodendritic axis and yielding the best PS reproductions.Model reconstruction of field potentials is a powerful tool tounderstand the interactions between different levels of complexity.The potential use of this approach to restrain the variabilityof some experimental measurements isdiscussed.

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