Armuntas Baginskas scite author profile

The membrane potential changes following action potentials in thin unmyelinated cortical axons with en passant boutons may be important for synaptic release and conduction abilities of such axons. In the lack of intra-axonal recording techniques we have used extracellular excitability testing as an indirect measure of the after-potentials. We recorded from individual CA3 soma in hippocampal slices and activated the axon with a range of stimulus intensities. When conditioning and test stimuli were given to the same site the excitability changes were partly masked by local effects of the stimulating electrode at intervals < 5 ms. Therefore, we elicited the conditioning action potential from one axonal branch and tested the excitability of another branch. We found that a single action potential reduced the axonal excitability for 15 ms followed by an increased excitability for ∼200 ms at 24• C. Using field recordings of axonal action potentials we show that raising the temperature to 34• C reduced the magnitude and duration of the initial depression. However, the duration of the increased excitability was very similar (time constant 135 ± 20 ms) at 24 and 34• C, and with 2.0 and 0.5 mM Ca 2+ in the bath. At stimulus rates > 1 Hz, a condition that activates a hyperpolarization-activated current (I h ) in these axons, the decay was faster than at lower stimulation rates. This effect was reduced by the I h blocker ZD7288. These data suggest that the decay time course of the action potential-induced hyperexcitability is determined by the membrane time constant.

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The H‐current secures action potential transmission at high frequencies in rat cerebellar parallel fibers

Baginskas

Palani

Chiu

et al. 2008

Eur J of Neuroscience

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Most axons in the mammalian brain are unmyelinated and thin with pre-synaptic specializations (boutons) along their entire paths. The parallel fibers in the cerebellum are examples of such axons. Unlike most thin axons they have only one branch point. The granule cell soma, where they originate, can fire bursts of action potentials with spike intervals of about 2 ms. An important question is whether the axons are able to propagate spikes with similarly short intervals. By using extracellular single-unit and population-recording methods we showed that parallel fibers faithfully conduct spikes at high frequencies over long distances. However, when adding 20 microm ZD7288 or 1 mm Cs(+), or reducing the temperature from 35 to 24 degrees C, the action potentials often failed even when successfully initiated. Ba(2+)(1 mm), which blocks Kir channels, did not reproduce these effects. The conduction velocity was reduced by ZD7288 but not by Ba(2+). This suggests that the parallel fibers have an H-current that is active at rest and that is important for their frequency-following properties. Interestingly, failures occurred only when the action potential had to traverse the axonal branch point, suggesting that the branch point is the weakest point in these axons.

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Electrotonic measurements by electric field-induced polarization in neurons: theory and experimental estimation

Svirskis¹,

Baginskas²,

Hounsgaard³

et al. 1997

Biophysical Journal

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We present a theory for estimation of the dendritic electrotonic length constant and the membrane time constant from the transmembrane potential (TMP) induced by an applied electric field. The theory is adapted to morphologically defined neurons with homogeneous passive electric properties. Frequency characteristics and transients at the onset and offset of the DC field are considered. Two relations are useful for estimating the electrotonic parameters: 1) steady-state polarization versus the dendritic electrotonic length constant; 2) membrane time constant versus length constant. These relations are monotonic and may provide a unique estimate of the electrotonic parameters for 3D-reconstructed neurons. Equivalent tip-to-tip electrotonic length of the dendritic tree was estimated by measuring the equalization time of the field-induced TMP. For 11 turtle spinal motoneurons, the electrotonic length from tip to tip of the dendrites was in the range of 1-2.5 lambda, whereas classical estimation using injection of current pulses gave an average dendrite length of 0.9-1.1 lambda. For seven ventral horn interneurons, the estimates were 0.7-2.6 lambda and 0.6-0.9 lambda, respectively. The measurements of the field-induced polarization promise to be a useful addition to the conventional methods using microelectrode stimulation.

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Bursts and hyperexcitability in non-myelinated axons of the rat hippocampus

2010

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Action potentials recorded from bundles of very thin, gray matter axons in rat cerebellar slices using a grease-gap method

Palani

Pekala

Baginskas

et al. 2012

Journal of Neuroscience Methods

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