Bilateral Integration of Whisker Information in the Primary Somatosensory Cortex of Rats

Shuler, Marshall G. Hussain; Krupa, David J.; Nicolelis, Miguel A. L.

doi:10.1523/jneurosci.21-14-05251.2001

Cited by 120 publications

(152 citation statements)

References 37 publications

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“…In the rodent, it has been observed that deflection of ipsilateral whiskers suppresses cortical responses evoked by contralateral whisker stimulation (Shuler et al, 2001), consistent with other anatomical (Carr and Sesack, 1998) and electrophysiological (Kawaguchi, 1992) evidence supporting the conclusion that, under normal conditions, callosal inputs have a net inhibitory influence.…”

Section: Introductionsupporting

confidence: 77%

“…Although transection of the corpus callosum, the main anatomical structure that connects the two cortical hemispheres, results in only subtle sensory and motor deficits (Gazzaniga, 2000), many studies have confirmed that cortical neuron responses can be strongly influenced by activation of peripheral ipsilateral inputs (Armstrong-James and George, 1988;Clarey et al, 1996;Shuler et al, 2001Shuler et al, , 2002Pluto et al, 2005).…”

Section: Introductionmentioning

confidence: 99%

“…The clear anatomy of the rodent somatosensory cortex, where individual whiskers project to topographically defined cortical columns (Woolsey and Van der Loos, 1970), as well as the complete crossing of primary sensory afferents at the midline (Waite, 1969;Smith, 1973;Erzurumlu and Killackey, 1980), makes this an attractive system to study the influence of interhemispheric interactions in shaping receptive field properties (Clarey et al, 1996;Shuler et al, 2001Shuler et al, , 2002Pluto et al, 2005). In the rodent, it has been observed that deflection of ipsilateral whiskers suppresses cortical responses evoked by contralateral whisker stimulation (Shuler et al, 2001), consistent with other anatomical (Carr and Sesack, 1998) and electrophysiological (Kawaguchi, 1992) evidence supporting the conclusion that, under normal conditions, callosal inputs have a net inhibitory influence.…”

Section: Introductionmentioning

confidence: 99%

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Ipsilateral Whiskers Suppress Experience-Dependent Plasticity in the Barrel Cortex

Głażewski¹,

Benedetti²,

Barth³

2007

J. Neurosci.

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Each cerebral hemisphere processes sensory input from both sides of the body, but the impact of this convergence on shaping and modifying receptive field properties remains controversial. Here we investigated the effect of chronic deprivation of ipsilateral sensory whiskers on receptive field plasticity in primary somatosensory cortex. In the absence of ipsilateral whiskers, cortical receptive fields were significantly larger than control after 1 week. Removal of all but a single whisker from one side of the face [single-whisker experience (SWE)] has been shown to result in the expansion of the cortical area responding to the spared whisker. We compared the effects of SWE in the presence (SWE-unilateral) and absence (SWE-bilateral) of ipsilateral whiskers. SWE-bilateral deprivation results in a significant increase in neuronal responses to spared whisker stimulation both in its cognate barrel column and in adjacent, surrounding barrel columns compared with control and SWE-unilateral deprived animals. Surround receptive fields in deprived columns were maintained in SWE-bilateral treated animals but depressed in SWE-unilateral animals. The increase in spared whisker responses was progressive with longer deprivation periods. These data show that ipsilateral whiskers can constrain receptive field size in the barrel cortex.

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Section: Introductionsupporting

confidence: 77%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Ipsilateral Whiskers Suppress Experience-Dependent Plasticity in the Barrel Cortex

Głażewski¹,

Benedetti²,

Barth³

2007

J. Neurosci.

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“…The SII fields are connected by callosal fibers, and their role may not be simply combining excitatory signals of two hemispheres to yield bilateral receptive fields. Experiments using denervation or reversible inactivation have attributed transcallosal activity a modulatory role in bilateral interactions (Shuler et al, 2001). In addition to the direct callosal projection, SII and SI fields in the two hemispheres can also interact via fibers descending to the thalamus (Raij et al, 2008).…”

Section: Discussionmentioning

confidence: 99%

“…Interhemispheric connections between the barrel fields were described by Olavarria et al (1984) and Koralek et al (1990) in the rat, who found that they are confined to the septal regions. The work on unanesthetized rats by Shuler et al (2001) and Wiest et al (2010) found a proportion of units that responded to stimulation of vibrissae from either side of the muzzle in layer V of the barrel cortex. Bilateral subthreshold receptive fields were also described in that layer by Manns et al (2004).…”

Section: Discussionmentioning

confidence: 99%

Bilateral Plasticity of Vibrissae SII Representation Induced by Classical Conditioning in Mice

Dębowska¹,

Liguz-Lecznar²,

Kossut³

2011

J. Neurosci.

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The somatosensory cortex in mice contains primary (SI) and secondary (SII) areas, differing in somatotopic precision, topographic organization, and function. The role of SII in somatosensory processing is still poorly understood. SII is activated bilaterally during attentional tasks and is considered to play a role in tactile memory and sensorimotor integration. We measured the plasticity of SII activation after associative learning based on classical conditioning, in which unilateral stimulation of one row of vibrissae was paired with a tail shock. The training consisted of three daily 10 min sessions, during which 40 pairings were delivered. Cortical activation driven by stimulation of vibrissae was mapped with 2-[ 14 C]deoxyglucose (2DG) autoradiography 1 d after the end of conditioning. We reported previously that the conditioning procedure resulted in unilateral enlargement of 2DG-labeled cortical representation of the "trained" row of vibrissae in SI. Here, we measured the width and intensity of the labeled region in SII. We found that both measured parameters in SII increased bilaterally. The increase was observed in cortical layers II/III and IV. Apparently, plasticity in SII is not a simple reflection of changes in SI. It may be attributable to bilateral integrative role of SII, its lesser topographical specificity, and strong involvement in attentional processing.

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In Vivo Functional Ultrasound (fUS) Real‐Time Imaging and Dosimetry of Mice Brain Under Radiofrequency Exposure

Orlacchio

Percherancier

Gannes

et al. 2022

Bioelectromagnetics

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This study aims to analyze in real‐time the potential modifications induced by low‐level continuous‐wave and Global System for Mobile Communications radiofrequency (RF) exposure at 1.8 GHz on brain activation in anesthetized mice. A specific in vivo experimental setup consisting of a dipole antenna for the local exposure of the brain was fully characterized. A unique neuroimaging technique based on a functional ultrasound (fUS) probe was used to observe the areas of mice brain activation simultaneously to the RF exposure with unprecedented spatial and temporal resolution (~100 μm, 1 ms) following manual whisker stimulation using a brush. Numerical and experimental dosimetry was carried out to characterize the exposure and to guarantee the validity of the biological results. Our results show that the fUS probe can be efficiently used during in vivo exposure without interference with the dipole. In addition, we conclude that exposure to brain‐averaged specific absorption rate levels of 2 and 6 W/kg does not introduce significant changes in the time course of the evoked fUS response in the left barrel field cortex. The proposed technique represents a valuable instrument for providing new insights into the possible effects induced on brain activation under RF exposure. For the first time, brain activity under mobile phone exposure was evaluated in vivo with fUS imaging, paving the way for more realistic exposure configurations, i.e. awake mice and new signals such as the 5 G networks. © 2022 Bioelectromagnetics Society.

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Bilateral Integration of Whisker Information in the Primary Somatosensory Cortex of Rats

Cited by 120 publications

References 37 publications

Ipsilateral Whiskers Suppress Experience-Dependent Plasticity in the Barrel Cortex

Ipsilateral Whiskers Suppress Experience-Dependent Plasticity in the Barrel Cortex

Bilateral Plasticity of Vibrissae SII Representation Induced by Classical Conditioning in Mice

In Vivo Functional Ultrasound (fUS) Real‐Time Imaging and Dosimetry of Mice Brain Under Radiofrequency Exposure

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