Synaptic Responses to Whisker Deflections in Rat Barrel Cortex as a Function of Cortical Layer and Stimulus Intensity

Wilent, W. Bryan; Contreras, Diego

doi:10.1523/jneurosci.5782-03.2004

Cited by 127 publications

(141 citation statements)

References 56 publications

(83 reference statements)

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“…Similar to what is reported in other intracellular studies performed in this system (Moore and Nelson, 1998;Brecht and Sakmann, 2002;Higley and Contreras, 2003;Wilent and Contreras, 2004), a small number of spikes per stimulus (0.28 spikes per stimulus) was evoked by the PD at the resting V m (Ϫ72 Ϯ 5 mV). Therefore, we measured the spike responses while cells were slightly depolarized (7-12 mV above rest; average V m ϭ Ϫ63 Ϯ 3 mV) with square current pulses (ϩ0.1 to ϩ0.3 nA) of 0.6 s duration and starting 0.2 s before each whisker deflection.…”

Section: Direction Sensitivity and Direction Tuning Of Rat Barrel Corsupporting

confidence: 88%

“…Other factors determining the rate of rise of the synaptic response include concomitant inhibitory input (Wehr and Zador, 2003;Wilent and Contreras, 2004), the degree of synchronization of the excitatory input, and the location of synapses on the somatodendritic membrane. Inhibitory input may simply add linearly to the excitatory input and decrease the slope of the synaptic response, or it may shunt excitatory input by increasing membrane conductance without necessarily causing hyperpolarization (Borg-Graham et al, 1998;Hirsch et al, 1998).…”

Section: Discussionmentioning

confidence: 99%

“…Inhibitory input may simply add linearly to the excitatory input and decrease the slope of the synaptic response, or it may shunt excitatory input by increasing membrane conductance without necessarily causing hyperpolarization (Borg-Graham et al, 1998;Hirsch et al, 1998). The degree of synchronization of thalamocortical input has been shown previously to play a key role for the encoding of velocity/acceleration in layer 4 of barrel cortex (Pinto et al, 2000(Pinto et al, , 2003, which results in an increase in dV m /dt of the synaptic response (Wilent and Contreras, 2004). A similar role for thalamocortical input synchronization in the encoding of direction has been suggested by the increase in the amplitude of local field potentials recorded in thalamic barreloids to preferred versus nonpreferred directions (Temereanca and Simons, 2003) and by the dependence of angular tuning on deflection velocity (Lee and Simons, 2004).…”

Section: Discussionmentioning

confidence: 99%

“…Before recording, whiskers were trimmed to a length of ϳ12 mm. Individual whiskers were deflected mechanically using ceramic piezoelectric bimorphs (Simons, 1983;Wilent and Contreras, 2004). Once a stable recording was obtained, the cell was depolarized moderately to facilitate whisker-evoked suprathreshold responses.…”

Section: Methodsmentioning

confidence: 99%

See 3 more Smart Citations

Stimulus-Dependent Changes in Spike Threshold Enhance Feature Selectivity in Rat Barrel Cortex Neurons

Wilent¹,

Contreras²

2005

J. Neurosci.

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108

136

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Feature selectivity is a fundamental property of sensory cortex neurons, yet the mechanisms underlying its genesis are not fully understood. Using intracellular recordings in vivo from layers 2-6 of rat barrel cortex, we studied the selectivity of neurons to the angular direction of whisker deflection. The spike output and the underlying synaptic response decreased exponentially in magnitude as the direction of deflection diverged from the preferred. However, the spike output was more sharply tuned for direction than the underlying synaptic response amplitude. This difference in selectivity was attributable to the rectification imposed by the spike threshold on the input-output function of cells. As in the visual system, spike threshold was not constant and showed trial-to-trial variability. However, here we show that the mean spike threshold was direction dependent and increased as the direction diverged from the preferred. Spike threshold was also related to the rate of rise of the synaptic response, which was direction dependent and steepest for the preferred direction. To assess the impact of the direction-dependent changes in spike threshold on direction selectivity, we applied a fixed threshold to the synaptic responses and calculated a predicted spike output. The predicted output was more broadly tuned than the obtained spike response, demonstrating for the first time that the regulation of the spike threshold by the properties of the synaptic response effectively enhances the selectivity of the spike output.

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Section: Direction Sensitivity and Direction Tuning Of Rat Barrel Corsupporting

confidence: 88%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

See 2 more Smart Citations

Stimulus-Dependent Changes in Spike Threshold Enhance Feature Selectivity in Rat Barrel Cortex Neurons

Wilent¹,

Contreras²

2005

J. Neurosci.

Self Cite

108

136

View full text Add to dashboard Cite

show abstract

“…This observation is consistent with previous findings in cortical slices that L5 inputs are located more proximally than L2/3 inputs (16,35), giving the L5 inputs greater control of postsynaptic responses. In the somatosensory cortex, the sensory response is also found to be more transient in L5 than in L2/3 (36,37), perhaps due to the same mechanism.…”

Section: Discussionmentioning

confidence: 90%

Layer-specific network oscillation and spatiotemporal receptive field in the visual cortex

Sun

Dan

2009

Proc. Natl. Acad. Sci. U.S.A.

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A quintessential feature of the neocortex is its laminar organization, and characterizing the activity patterns in different layers is an important step in understanding cortical processing. Using in vivo whole-cell recordings in rat visual cortex, we show that the temporal patterns of ongoing synaptic inputs to pyramidal neurons exhibit clear laminar specificity. Although low-frequency (ϳ2 Hz) activity is widely observed in layer 2/3 (L2/3), a narrow-band fast oscillation (10 -15 Hz) is prominent in layer 5 (L5). This fast oscillation is carried exclusively by excitatory inputs. Moreover, the frequency of ongoing activity is strongly correlated with the spatiotemporal window of visual integration: Neurons with fast-oscillating spontaneous inputs exhibit transient visual responses and small receptive fields (RFs), whereas those with slow inputs show prolonged responses and large RFs. These findings suggest that the neural representation of visual information within each layer is strongly influenced by the temporal dynamics of the local network manifest in spontaneous activity.lamina ͉ ongoing activity ͉ patch clamp ͉ pyramidal cell ͉ vision C oherent oscillatory activity in neuronal populations has been widely observed in the nervous system. Studies in both humans and animal models have shown that oscillations in various frequency bands are correlated with the behavioral or attentional state of the subject (1-5). The synchronization of activity within an oscillating ensemble and the temporal phase of single neuron spiking relative to the network oscillation may be used to carry sensory information (6-9), to control synaptic interactions (10), or to regulate activity-dependent synaptic modification (2,11,12). Thus, network oscillations may be involved in a range of essential brain functions.To elucidate the function of a given type of oscillation, it is important to know which neurons participate in the oscillating ensemble. In the neocortex, the spatial extent of coherent oscillation has been studied extensively along the cortical surface (4-6, 13). However, little is known about the laminar distribution of oscillations in the intact brain. The laminar organization of cortical microcircuit plays crucial roles in information processing. Neurons in different layers exhibit different synaptic connectivity, and the representation of sensory signals is transformed systematically across layers (14, 15). Thus, an important question is whether oscillations show any laminar specificity, and whether layer-specific oscillations contribute to cortical processing.In the current study, we used in vivo whole-cell recordings to measure both the spontaneous activity and the spatiotemporal receptive fields (RFs) of rat visual cortical neurons. We found that pyramidal neurons in L2/3 and L5 exhibit distinct patterns of membrane potential oscillations in the absence of visual input, whereas L2/3 neurons exhibit slow spontaneous activity at Ϸ2 Hz, reflecting both excitatory and inhibitory inputs, L5 neurons show a strong oscillation...

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In Vivo Dynamic-Clamp Manipulation of Extrinsic and Intrinsic Conductances: Functional Roles of Shunting Inhibition and I BK in Rat and Cat Cortex

Graham

Schramm²

2009

Dynamic-Clamp

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Synaptic Responses to Whisker Deflections in Rat Barrel Cortex as a Function of Cortical Layer and Stimulus Intensity

Cited by 127 publications

References 56 publications

Stimulus-Dependent Changes in Spike Threshold Enhance Feature Selectivity in Rat Barrel Cortex Neurons

Stimulus-Dependent Changes in Spike Threshold Enhance Feature Selectivity in Rat Barrel Cortex Neurons

Layer-specific network oscillation and spatiotemporal receptive field in the visual cortex

In Vivo Dynamic-Clamp Manipulation of Extrinsic and Intrinsic Conductances: Functional Roles of Shunting Inhibition and I BK in Rat and Cat Cortex

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