Membrane currents evoked by afferent fiber stimulation in rat piriform cortex. I. Current source-density analysis

1. The membrane currents evoked by afferent fiber stimulation in the piriform cortex were derived by the use of current source-density (CSD) analysis in the rat under urethan anesthesia. The primary goals were to test hypotheses concerning the sequence of synaptic events evoked by afferent fiber stimulation and to derive data required for development and testing of the model presented in the companion paper. 2. In confirmation of previous studies, it was found that afferent fiber stimulation evokes a monosynaptic excitatory postsynaptic current (EPSC) in distal segments of pyramidal cell apical dendrites (layer Ia) followed by a strong disynaptic EPSC in adjacent middle segments (superficial layer Ib). 3. Given the central importance of the strong disynaptic EPSC in models for operation of the piriform cortex, the hypothesis that it is mediated by long association fibers from the anterior piriform cortex was tested by comparing its latency in response to stimulation at anterior and posterior locations. The results confirmed the hypothesis and ruled out a significant contribution from local connections in the posterior piriform cortex. 4. Intensification of pyramidal cell activity by spatially restricted disinhibition with picrotoxin confirmed the hypothesis that associational projections from the posterior piriform cortex can mediate a long-latency disynaptic EPSC in proximal dendritic segments (mid to deep layer Ib) in the anterior piriform cortex. 5. Analysis of the time course of the monosynaptic EPSC in different areas revealed that activation of the anterior piriform cortex from afferent fiber stimulation is fast and nearly synchronous throughout its extent as a result of the relatively high conduction velocities of afferent fibers in the lateral olfactory tract (LOT). By contrast, the posterior piriform cortex is sequentially activated by this EPSC as a consequence of the slow propagation velocity of afferent fiber collaterals that course across its surface. This activation is sufficiently slow that a large phase lag is present between rostral and caudal regions. 6. The time courses of the monosynaptic and principal disynaptic EPSCs changed in characteristically different ways with increasing distance from the LOT within the posterior piriform cortex. Simulations in the companion paper indicate that initiation and propagation patterns for activity in fiber systems rather than differences in synaptic conductance waveforms are responsible for these differences. 7. Although the laminar distribution of the active inward current component of the monosynaptic EPSC remained constant over time, the peak outward current associated with this EPSC shifted from the depth of proximal apical dendrites (layer Ib) to the depth of superficial pyramidal cell somata (layer II).(ABSTRACT TRUNCATED AT 400 WORDS)

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Analysis of synaptic events in the opossum piriform cortex with improved current source-density techniques

Journal of Neurophysiology ◽

10.1152/jn.1989.61.4.702 ◽

1989 ◽

Vol 61 (4) ◽

pp. 702-718 ◽

Cited By ~ 55

Author(s):

R. Rodriguez ◽

L. B. Haberly

Keyword(s):

Piriform Cortex ◽

Current Source ◽

Field Potential ◽

Pyramidal Cells ◽

Superficial Layer ◽

Current Source Density ◽

Membrane Currents ◽

Source Density ◽

Potential Component ◽

Association Fibers

1. The piriform cortex of the opossum was studied by current source-density (CSD) analysis of field potentials to determine the laminar and temporal distribution of synaptic currents evoked by lateral olfactory tract (LOT) stimulation. 2. Extracellular conductivity was measured as a function of depth at high resolution and incorporated into CSD computations. Inclusion of the conductivity term resulted in relatively subtle changes in the shapes of CSD profiles. Resolution and accuracy of CSD computations was further improved by use of a new smoothing approach and averaging of multiple potential profiles obtained at the same site. 3. The CSD depth profile resulting from LOT stimulation revealed six major synaptic events that were consistently present at anterior, middle, and posterior sites: one during the first (A1) peak of the initial surface negative dichrotic field potential component, three during the second (B1) peak, one during the surface positive field potential component (period 2), and one during the second surface negative component (period 3). In addition, CSD profiles were computed for the population spike generated by synchronous discharge of action potentials. Depths of the net inward and outward membrane currents underlying these events were correlated with the cortical lamination as determined histologically by placement of small dye marks. 4. In agreement with previous reports it is concluded that the large inward membrane current in layer Ia during the A1 wave underlies a monosynaptic EPSP evoked in distal apical dendritic segments of pyramidal cells by afferent fibers. This EPSP displays a marked paired shock facilitation. 5. Based on anatomic and physiological considerations it is concluded that the three spatially and temporally distinct inward membrane currents (sinks) that were observed in layers III, superficial Ib, and mid- to deep-Ib during the B1 wave, underlie disynaptic EPSPs resulting from direct synaptic interactions between pyramidal cells. It is postulated that the layer III sink is generated in basal dendrites largely via local axon collaterals, the superficial layer Ib sink in intermediate apical dendritic segments by association fibers originating in the anterior piriform cortex, and the deep Ib sink in proximal apical segments by association fibers originating largely in the posterior piriform cortex. 6. The latencies of the layer Ia and superficial layer Ib sinks (presumed mono- and large disynaptic EPSPs, respectively) increased from anterior to posterior. Amplitude of the superficial Ib sink relative to the Ia sink increased from anterior to posterior.(ABSTRACT TRUNCATED AT 400 WORDS)

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Converging Inputs to the Entorhinal Cortex From the Piriform Cortex and Medial Septum: Facilitation and Current Source Density Analysis

Journal of Neurophysiology ◽

10.1152/jn.1997.78.5.2602 ◽

1997 ◽

Vol 78 (5) ◽

pp. 2602-2615 ◽

Cited By ~ 19

Author(s):

C. Andrew Chapman ◽

Ronald J. Racine

Keyword(s):

Entorhinal Cortex ◽

Piriform Cortex ◽

Current Source ◽

Field Potential ◽

Medial Septum ◽

Current Source Density ◽

Short Term ◽

Source Density ◽

Potential Component ◽

Stimulation Of

Chapman, C. Andrew and Ronald J. Racine. Converging inputs to the entorhinal cortex from the piriform cortex and medial septum: facilitation and current source density analysis. J. Neurophysiol. 78: 2602–2615, 1997. The entorhinal cortex receives sensory inputs from the piriform cortex and modulatory inputs from the medial septum. To examine short-term synaptic facilitation effects in these pathways, current source density (CSD) analysis was used first to localize the entorhinal cortex membrane currents, which generate field potentials evoked by stimulation of these afferents. Field potentials were recorded at 50-μm intervals through the medial entorhinal cortex in urethan-anesthetized rats and the one-dimensional CSD was calculated. Piriform cortex stimulation evoked a surface-negative, deep-positive field potential component in the entorhinal cortex with mean onset and peak latencies of 10.4 and 18.4 ms. The component followed brief 100-Hz stimulation, consistent with a monosynaptic response. CSD analysis linked the component to a current sink, which often began in layer I before peaking in layer II. A later, surface-positive field potential component peaked at latencies near 45 ms and was associated with a current source in layer II. Medial septal stimulation evoked positive and negative field potential components which peaked at latencies near 7 and 16 ms, respectively. A weaker and more prolonged surface-negative, deep-positive component peaked at latencies near 25 ms. The early components were generated by currents in the hippocampal formation, and the late surface-negative component was generated by currents in layers II to IV of the entorhinal cortex. Short-term facilitation effects in conscious animals were examined using electrodes chronically implanted near layer II of the entorhinal cortex. Paired-pulse stimulation of the piriform cortex at interpulse intervals of 30 and 40 ms caused the largest facilitation (248%) of responses evoked by the second pulse. Responses evoked by medial septal stimulation also were facilitated maximally (59%) by a piriform cortex conditioning pulse delivered 30–40 ms earlier. Paired pulse stimulation of the medial septum caused the largest facilitation (149%) at intervals of 70 ms, but piriform cortex evoked responses were facilitated maximally (46%) by a septal conditioning pulse 100–200 ms earlier. Frequency potentiation effects were maximal during 12- to 18-Hz stimulation of either the piriform cortex or medial septum. Occlusion tests suggested that piriform cortex and medial septal efferents activate the same neurons. The CSD analysis results show that evoked field potential methods can be used effectively in chronically prepared animals to examine synaptic responses in the converging inputs from the piriform cortex and medial septum to the entorhinal cortex. The short-term potentiation phenomena observed here suggest that low-frequency activity in these pathways during endogenous oscillatory states may enhance entorhinal cortex responsivity to olfactory inputs.

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Membrane currents evoked by afferent fiber stimulation in rat piriform cortex. II. Analysis with a system model

Journal of Neurophysiology ◽

10.1152/jn.1993.69.1.261 ◽

1993 ◽

Vol 69 (1) ◽

pp. 261-281 ◽

Cited By ~ 17

Author(s):

K. L. Ketchum ◽

L. B. Haberly

Keyword(s):

Conduction Velocity ◽

Time Course ◽

Wide Spectrum ◽

Piriform Cortex ◽

Current Source ◽

Afferent Fiber ◽

Membrane Currents ◽

System Model ◽

Arrival Times ◽

Fiber Stimulation

1. The detailed visualization of membrane currents over time and depth provided by current source-density (CSD) analysis was used as the basis for development of a system model that reproduces the response of piriform cortex to afferent fiber stimulation. This model has allowed the testing and substantial revision of previous hypotheses concerning the sequence of neuronal events underlying this response, has enabled net membrane currents visualized by CSD analysis to be separated into active and passive components, and has generated predictions for important axonal and synaptic parameters as well as for the behavior of piriform cortex as a system. 2. The model was developed in three steps. Activity in excitatory fiber systems was first represented with continuous distributions. The “population conductances” due to the activation of excitatory fiber systems were then computed from the distribution of action-potential arrival times and the conductance waveform for excitatory synapses. Finally, these temporally dispersed excitatory conductances and locally mediated inhibitory conductances were introduced at appropriate locations on a compartmentalized cable that simulated the passive response of the pyramidal cell population. 3. After the simulation of membrane currents at one site, all parameters in the model were fixed so that it could be used to predict the variation in the time course of membrane currents at additional recording sites; comparison with the results of CSD analysis at these sites provided the primary validation of the model. Additional validation included the simulation of membrane potentials derived by intracellular recording, including the effects of manipulating somatic potential with current injection. 4. Several conclusions have emerged from the mathematical description of activity in fiber systems. Propagation of activity in both afferent and association (corticocortical) fiber systems is “dispersive” as a result of a wide spectrum of axon conduction velocities. The characteristically different time courses of afferent and association fiber-mediated responses are largely determined by the focal, shock-evoked origin of the volley in afferent fibers as opposed to the spatially distributed disynaptic origin of activity in association fibers. Conduction velocity distributions for afferent and association fiber systems are skewed and can be approximated with lognormal distributions. 5. General solutions, which relate an arbitrary conduction velocity distribution to arrival time and spatial distributions of action potentials, were used to generate specific solutions describing the effects of dispersive propagation.(ABSTRACT TRUNCATED AT 400 WORDS)

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Current-Source Density Analysis in the Rat Olfactory Bulb: Laminar Distribution of Kainate/AMPA- and NMDA-Receptor-Mediated Currents

Journal of Neurophysiology ◽

10.1152/jn.1999.81.1.15 ◽

1999 ◽

Vol 81 (1) ◽

pp. 15-28 ◽

Cited By ~ 37

Author(s):

Vassiliki Aroniadou-Anderjaska ◽

Matthew Ennis ◽

Michael T. Shipley

Keyword(s):

Nmda Receptor ◽

Olfactory Bulb ◽

Granule Cell ◽

Granule Cells ◽

Current Source ◽

Field Potential ◽

Current Source Density ◽

Source Density ◽

Tufted Cells ◽

Apical Dendrites

Aroniadou-Anderjaska, Vassiliki, Matthew Ennis, and Michael T. Shipley. Current-source density analysis in the rat olfactory bulb: laminar distribution of kainate/AMPA- and NMDA-receptor-mediated currents. J. Neurophysiol. 81: 15–28, 1999. The one-dimensional current-source density method was used to analyze laminar field potential profiles evoked in rat olfactory bulb slices by stimulation in the olfactory nerve (ON) layer or mitral cell layer (MCL) and to identify the field potential generators and the characteristics of synaptic activity in this network. Single pulses to the ON evoked a prolonged (≥400 ms) sink (S1ON) in the glomerular layer (GL) with corresponding sources in the external plexiform layer (EPL) and MCL and a relatively brief sink (S2ON) in the EPL, reversing in the internal plexiform and granule cell layers. These sink/source distributions suggested that S1ON and S2ON were generated in the apical dendrites of mitral/tufted cells and granule cells, respectively. The kainate/AMPA-receptor antagonist CNQX (10 μM) reduced the early phase of S1ON, blocked S2ON, and revealed a low amplitude, prolonged sink at the location of S2ON in the EPL. Reduction of Mg2+, in CNQX, enhanced both the CNQX-resistant component of S1ON and the EPL sink. This EPL sink reversed below the MCL, suggesting it was produced in granule cells. The NMDA-receptor antagonist APV (50 μM) reversibly blocked the CNQX-resistant field potentials in all layers. Single pulses were applied to the MCL to antidromically depolarize the dendrites of mitral/tufted cells. In addition to synaptic currents of granule cells, a low-amplitude, prolonged sink (S1mcl) was evoked in the GL. Corresponding sources were in the EPL, suggesting that S1mcl was generated in the glomerular dendritic tufts of mitral/tufted cells. Both S1mcl and the granule cell currents were nearly blocked by CNQX (10 μM) but enhanced by subsequent reduction of Mg2+; these currents were blocked by APV. S1mcl also was enhanced by γ-aminobutyric acid-A-receptor antagonists applied to standard medium; this enhancement was reduced by APV. ON activation produces prolonged excitation in the apical dendrites of mitral/tufted cells, via kainate/AMPA and NMDA receptors, providing the opportunity for modulation and integration of sensory information at the first level of synaptic processing in the olfactory system. Granule cells respond to input from the lateral dendrites of mitral/tufted cells via both kainate/AMPA and NMDA receptors; however, in physiological concentrations of extracellular Mg2+, NMDA-receptor activation does not contribute significantly to the granule cell responses. The glomerular sink evoked by antidromic depolarization of mitral/tufted cell dendrites suggests that glutamate released from the apical dendrites of mitral/tufted cells may excite the same or neighboring mitral/tufted cell dendrites.

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Principal neuronal organization in the frog optic tectum revealed by a current source density analysis

Visual Neuroscience ◽

10.1017/s0952523800011408 ◽

1997 ◽

Vol 14 (2) ◽

pp. 263-275 ◽

Cited By ~ 13

Author(s):

Hideki Nakagawa ◽

Hiromi Miyazaki ◽

Nobuyoshi Matsumoto

Keyword(s):

Optic Tectum ◽

Ganglion Cells ◽

Current Source ◽

Afferent Fiber ◽

Optic Tract ◽

Current Source Density ◽

Spatiotemporal Pattern ◽

Source Density ◽

Optic Fibers ◽

A Current

AbstractIn the frog optic tectum, the spatiotemporal pattern of neuronal activity evoked by electrical stimulation of the optic tract was examined by means of a current source density (CSD) analysis. The CSD depth profile was highly reproducible in different experiments. In all seven CSD profiles, three current sinks A, B, and D were observed in the retinorecipient layers. Four out of the seven profiles show additional two sinks C and E below the retinorecipient layers. Very small and short lasting sinks related to afferent fiber activities precede sinks A and B by about 1 ms, which could be accounted for by monosynaptic delay, in the corresponding depth region. The earliest prominent sink A at the bottom of the retinorecipient layers reflects only excitatory monosynaptic activities derived from R3 and/or R4 retinal ganglion cells. The second prominent sink B in the superficial retinorecipient layer is composed partly of excitatory monosynaptic activity from medium-sized myelinated optic fibers. It may involve excitatory monosynaptic activity from unmyelinated optic fibers and further polysynaptic activity. The fourth prominent sink D in the intermediate retinorecipient layer partially reflects excitatory monosynaptic activity derived from unmyelinated optic fibers. It may also involve further polysynaptic activity. In contrast with these three sinks, the third prominent sink C and fifth sink E exclusively reflect intratectal polysynaptic activity that has not been reported in any previous CSD studies in the frog optic tectum. These sinks almost overlap spatially in the tectal layer. We also measured the intratectal resistance changes and computed inhomogeneous CSD depth profiles to show that the results from homogeneous CSD computation assuming constant conductivity are valid for our present study. Finally, we compared the present results with previously reported CSD studies on the frog optic tectum and discuss consistencies and discrepancies among these experiments.

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