Your search keyword '"Alfredo Fontanini"' showing total 9 results

1. Layer- and Cell Type-Specific Response Properties of Gustatory Cortex Neurons in Awake Mice

Author

Alfredo Fontanini, Dustin M. Graham, Gülce N. Dikecligil, and Il Memming Park

Subjects

0301 basic medicine, Cell type, Action Potentials, Sensory system, Stimulus (physiology), Inhibitory postsynaptic potential, Somatosensory system, Insular cortex, Mice, 03 medical and health sciences, 0302 clinical medicine, medicine, Animals, Research Articles, Neurons, Chemistry, General Neuroscience, Taste Perception, Neural Inhibition, Somatosensory Cortex, Primary sensory areas, 030104 developmental biology, medicine.anatomical_structure, nervous system, Taste, Female, Gustatory cortex, Neuroscience, 030217 neurology & neurosurgery

Abstract

Studies in visual, auditory, and somatosensory cortices have revealed that different cell types as well as neurons located in different laminae display distinct stimulus response profiles. The extent to which these layer and cell type-specific distinctions generalize to gustatory cortex (GC) remains unknown. In this study, we performed extracellular recordings in adult female mice to monitor the activity of putative pyramidal and inhibitory neurons located in deep and superficial layers of GC. Awake, head-restrained mice were trained to lick different tastants (sucrose, salt, citric acid, quinine, and water) from a lick spout. We found that deep layer neurons show higher baseline firing rates (FRs) in GC with deep-layer inhibitory neurons displaying highest FRs at baseline and following the stimulus. GC's activity shows robust modulations before animals' contact with tastants, and this phenomenon is most prevalent in deep-layer inhibitory neurons. Furthermore, we show that licking activity strongly shapes the spiking pattern of GC pyramidal neurons, eliciting phase-locked spiking across trials and tastants. We demonstrate that there is a greater percentage of taste-coding neurons in deep versus superficial layers with chemosensitive neurons across all categories showing similar breadth of tuning, but different decoding performance. Lastly, we provide evidence for functional convergence in GC, with neurons that can show prestimulus activity, licking-related rhythmicity and taste responses. Overall, our results demonstrate that baseline and stimulus-evoked firing profiles of GC neurons and their processing schemes change as a function of cortical layer and cell type in awake mice.SIGNIFICANCE STATEMENTSensory cortical areas show a laminar structure, with each layer composed of distinct cell types embedded in different circuits. While studies in other primary sensory areas have elucidated that pyramidal and inhibitory neurons belonging to distinct layers show distinct response properties, whether and how response properties of gustatory cortex (GC) neurons change as a function of their laminar position and cell type remains uninvestigated. Here, we show that there are several notable differences in baseline, prestimulus, and stimulus-evoked response profiles of pyramidal and inhibitory neurons belonging to deep and superficial layers of GC.

Published

2020

2. Synaptic Integration of Thalamic and Limbic Inputs in Rodent Gustatory Cortex

Author

M. E. Stone, Alfredo Fontanini, and Arianna Maffei

Subjects

Male, Population, Thalamus, integration, Rodentia, Gating, Biology, Stimulus (physiology), Inhibitory postsynaptic potential, 03 medical and health sciences, gustatory cortex, 0302 clinical medicine, Neural Pathways, medicine, Animals, Rats, Long-Evans, education, 030304 developmental biology, 0303 health sciences, education.field_of_study, Ventral Thalamic Nuclei, thalamocortical, General Neuroscience, excitation, General Medicine, inhibition, Rats, medicine.anatomical_structure, Taste, Excitatory postsynaptic potential, Sensory and Motor Systems, Female, Gustatory cortex, Neuroscience, amygdalocortical, 030217 neurology & neurosurgery, Research Article: New Research, Basolateral amygdala

Abstract

Neurons in the gustatory cortex (GC) process multiple aspects of a tasting experience, encoding not only the physiochemical identity of tastes, but also their anticipation and hedonic value. Information pertaining to these stimulus features is relayed to GC via the gustatory thalamus (VPMpc) and basolateral amygdala (BLA). It is not known whether these inputs drive separate groups of neurons, thus activating separate channels of information, or are integrated by neurons that receive both afferents. Here, we used anterograde labeling andin vivointracellular recordings in anesthetized rats to assess the potential convergence of BLA and VPMpc inputs in GC, and to investigate the dynamics of integration of these inputs. We report substantial anatomic overlap of BLA and VPMpc axonal fields across GC, and identify a population of GC neurons receiving converging BLA and VPMpc inputs. Our data show that BLA modulates the gain of VPMpc-evoked responses in a time-dependent fashion and that this modulation is dependent on the recruitment of synaptic inhibition by both BLA and VPMpc. Our results suggest that BLA shapes cortical processing of thalamic inputs by dynamically gating the excitatory/inhibitory balance of the GC circuit.

Published

2020

3. Processing of Intraoral Olfactory and Gustatory Signals in the Gustatory Cortex of Awake Rats

Author

Alfredo Fontanini and Chad L. Samuelsen

Subjects

0301 basic medicine, Sucrose, Taste, media_common.quotation_subject, Administration, Oral, Aversive taste, Olfaction, Olfactory Receptor Neurons, 03 medical and health sciences, 0302 clinical medicine, Perception, Animals, Rats, Long-Evans, Palatability, Wakefulness, Research Articles, Flavor, media_common, Cerebral Cortex, General Neuroscience, Water, Olfactory Perception, Rats, Smell, 030104 developmental biology, Odor, Odorants, Female, Gustatory cortex, Psychology, Neuroscience, psychological phenomena and processes, 030217 neurology & neurosurgery

Abstract

The integration of gustatory and olfactory information is essential to the perception of flavor. Human neuroimaging experiments have pointed to the gustatory cortex (GC) as one of the areas involved in mediating flavor perception. Although GC's involvement in encoding the chemical identity and hedonic value of taste stimuli is well studied, it is unknown how single GC neurons process olfactory stimuli emanating from the mouth. In this study, we relied on multielectrode recordings to investigate how single GC neurons respond to intraorally delivered tastants and tasteless odorants dissolved in water and whether/how these two modalities converge in the same neurons. We found that GC neurons could either be unimodal, responding exclusively to taste (taste-only) or odor (odor-only), or bimodal, responding to both gustatory and olfactory stimuli. Odor responses were confirmed to result from retronasal olfaction: monitoring respiration revealed that exhalation preceded odor-evoked activity and reversible inactivation of olfactory receptors in the nasal epithelium significantly reduced responses to intraoral odorants but not to tastants. Analysis of bimodal neurons revealed that they encode palatability significantly better than the unimodal taste-only group. Bimodal neurons exhibited similar responses to palatable tastants and odorants dissolved in water. This result suggested that odorized water could be palatable. This interpretation was further supported with a brief access task, where rats avoided consuming aversive taste stimuli and consumed the palatable tastants and dissolved odorants. These results demonstrate the convergence of the chemosensory components of flavor onto single GC neurons and provide evidence for the integration of flavor with palatability coding.SIGNIFICANCE STATEMENTFood perception and choice depend upon the concurrent processing of olfactory and gustatory signals from the mouth. The primary gustatory cortex has been proposed to integrate chemosensory stimuli; however, no study has examined the single-unit responses to intraoral odorant presentation. Here we found that neurons in gustatory cortex can respond either exclusively to tastants, exclusively to odorants, or to both (bimodal). Several differences exist between these groups' responses; notably, bimodal neurons code palatability significantly better than unimodal neurons. This group of neurons might represent a substrate for how odorants gain the quality of tastants.

Published

2016

4. Laminar- and Target-Specific Amygdalar Inputs in Rat Primary Gustatory Cortex

Author

Alfredo Fontanini, Melissa S. Haley, and Arianna Maffei

Subjects

Male, 0301 basic medicine, Patch-Clamp Techniques, Sensory processing, medicine.medical_treatment, Action Potentials, Sensory system, Tetrodotoxin, Inhibitory postsynaptic potential, Amygdala, 03 medical and health sciences, 0302 clinical medicine, Channelrhodopsins, Quinoxalines, Potassium Channel Blockers, medicine, Biological neural network, Animals, 4-Aminopyridine, Afferent Pathways, General Neuroscience, Excitatory Postsynaptic Potentials, Neural Inhibition, Articles, Electric Stimulation, Rats, Parvalbumins, 030104 developmental biology, medicine.anatomical_structure, Taste, Excitatory postsynaptic potential, Female, Sensorimotor Cortex, Psychology, Gustatory cortex, Excitatory Amino Acid Antagonists, Neuroscience, 030217 neurology & neurosurgery, Sodium Channel Blockers, Basolateral amygdala

Abstract

The primary gustatory cortex (GC) receives projections from the basolateral nucleus of the amygdala (BLA). Behavioral and electrophysiological studies demonstrated that this projection is involved in encoding the hedonic value of taste and is a source of anticipatory activity in GC. Anatomically, this projection is largest in the agranular portion of GC; however, its synaptic targets and synaptic properties are currently unknown.In vivoelectrophysiological recordings report conflicting evidence about BLA afferents either selectively activating excitatory neurons or driving a compound response consistent with the activation of inhibitory circuits. Here we demonstrate that BLA afferents directly activate excitatory neurons and two distinct populations of inhibitory neurons in both superficial and deep layers of rat GC. BLA afferents recruit different proportions of excitatory and inhibitory neurons and show distinct patterns of circuit activation in the superficial and deep layers of GC. These results provide the first circuit-level analysis of BLA inputs to a sensory area. Laminar- and target-specific differences of BLA inputs likely explain the complexity of amygdalocortical interactions during sensory processing.SIGNIFICANCE STATEMENTProjections from the basolateral nucleus of the amygdala (BLA) to the cortex convey information about the emotional value and the expectation of a sensory stimulus. Although much work has been done to establish the behavioral role of BLA inputs to sensory cortices, very little is known about the circuit organization of BLA projections. Here we provide the first in-depth analysis of connectivity and synaptic properties of the BLA input to the gustatory cortex. We show that BLA afferents activate excitatory and inhibitory circuits in a layer-specific and pattern-specific manner. Our results provide important new information about how neural circuits establishing the hedonic value of sensory stimuli and driving anticipatory behaviors are organized at the synaptic level.

Published

2016

5. State Dependency of Chemosensory Coding in the Gustatory Thalamus (VPMpc) of Alert Rats

Author

Alfredo Fontanini and Haixin Liu

Subjects

Taste, Thalamus, Sensory system, Neural Pathways, medicine, Animals, Rats, Long-Evans, Wakefulness, Ventral Thalamic Nuclei, Communication, Parabrachial Nucleus, business.industry, General Neuroscience, Taste Perception, Articles, Chemoreceptor Cells, Rats, medicine.anatomical_structure, Female, Neuron, Brainstem, Psychology, Gustatory cortex, business, Neuroscience

Abstract

The parvicellular portion of the ventroposteromedial nucleus (VPMpc) is the part of the thalamus that processes gustatory information. Anatomical evidence shows that the VPMpc receives ascending gustatory inputs from the parabrachial nucleus (PbN) in the brainstem and sends projections to the gustatory cortex (GC). Although taste processing in PbN and GC has been the subject of intense investigation in behaving rodents, much less is known on how VPMpc neurons encode gustatory information. Here we present results from single-unit recordings in the VPMpc of alert rats receiving multiple tastants. Thalamic neurons respond to taste with time-varying modulations of firing rates, consistent with those observed in GC and PbN. These responses encode taste quality as well as palatability. Comparing responses to tastants either passively delivered, or self-administered after a cue, unveiled the effects of general expectation on taste processing in VPMpc. General expectation led to an improvement of taste coding by modulating response dynamics, and single neuron ability to encode multiple tastants. Our results demonstrate that the time course of taste coding as well as single neurons' ability to encode for multiple qualities are not fixed but rather can be altered by the state of the animal. Together, the data presented here provide the first description that taste coding in VPMpc is dynamic and state-dependent.SIGNIFICANCE STATEMENTOver the past years, a great deal of attention has been devoted to understanding taste coding in the brainstem and cortex of alert rodents. Thanks to this research, we now know that taste coding is dynamic, distributed, and context-dependent. Alas, virtually nothing is known on how the gustatory thalamus (VPMpc) processes gustatory information in behaving rats. This manuscript investigates taste processing in the VPMpc of behaving rats. Our results show that thalamic neurons encode taste and palatability with time-varying patterns of activity and that thalamic coding of taste is modulated by general expectation. Our data will appeal not only to researchers interested in taste, but also to a broader audience of sensory and systems neuroscientists interested in the thalamocortical system.

Published

2015

6. Encoding and Tracking of Outcome-Specific Expectancy in the Gustatory Cortex of Alert Rats

Author

Alfredo Fontanini and Matthew P.H. Gardner

Subjects

Neurons, Expectancy theory, Sucrose, Communication, Quinine, business.industry, General Neuroscience, Taste Perception, Sensory system, Somatosensory Cortex, Articles, Anticipation, Psychological, Somatosensory system, Insular cortex, Rats, Animals, Learning, Female, Rats, Long-Evans, business, Psychology, Gustatory cortex, Neuroscience

Abstract

In natural conditions, gustatory stimuli are typically expected. Anticipatory and contextual cues provide information that allows animals to predict the availability and the identity of the substance to be ingested. Recording in alert rats trained to self-administer tastants following a go signal revealed that neurons in the primary gustatory cortex (GC) can respond to anticipatory cues. These experiments were optimized to demonstrate that even the most general form of expectation can activate neurons in GC, and did not provide indications on whether cues predicting different tastants could be encoded selectively by GC neurons. Here we recorded single-neuron activity in GC of rats engaged in a task where one auditory cue predicted sucrose, while another predicted quinine. We found that GC neurons respond differentially to the two cues. Cue-selective responses develop in parallel with learning. Comparison between cue and sucrose responses revealed that cues could trigger the activation of anticipatory representations. Additional experiments showed that an expectation of sucrose leads a subset of neurons to produce sucrose-like responses even when the tastant was omitted. Altogether, the data show that primary sensory cortices can encode for cues predicting different outcomes, and that specific expectations result in the activation of anticipatory representations.

Published

2014

7. Processing of Hedonic and Chemosensory Features of Taste in Medial Prefrontal and Insular Networks

Author

Ahmad Jezzini, Luca Mazzucato, Giancarlo La Camera, and Alfredo Fontanini

Subjects

Taste, Journal Club, Nerve net, Prefrontal Cortex, Somatosensory system, behavioral disciplines and activities, Food Preferences, Discrimination, Psychological, Reward, medicine, Animals, Rats, Long-Evans, Palatability, Prefrontal cortex, Cerebral Cortex, Neurons, General Neuroscience, Somatosensory Cortex, Stimulation, Chemical, Electrophysiological Phenomena, Rats, medicine.anatomical_structure, nervous system, Cerebral cortex, Data Interpretation, Statistical, Female, Orbitofrontal cortex, Nerve Net, Gustatory cortex, Psychology, Neuroscience, Algorithms, psychological phenomena and processes

Abstract

Most of the research on cortical processing of taste has focused on either the primary gustatory cortex (GC) or the orbitofrontal cortex (OFC). However, these are not the only areas involved in taste processing. Gustatory information can also reach another frontal region, the medial prefrontal cortex (mPFC), via direct projections from GC. mPFC has been studied extensively in relation to its role in controlling goal-directed action and reward-guided behaviors, yet very little is known about its involvement in taste coding. The experiments presented here address this important point and test whether neurons in mPFC can significantly process the physiochemical and hedonic dimensions of taste. Spiking responses to intraorally delivered tastants were recorded from rats implanted with bundles of electrodes in mPFC and GC. Analysis of single-neuron and ensemble activity revealed similarities and differences between the two areas. Neurons in mPFC can encode the chemosensory identity of gustatory stimuli. However, responses in mPFC are sparser, more narrowly tuned, and have a later onset than in GC. Although taste quality is more robustly represented in GC, taste palatability is coded equally well in the two areas. Additional analysis of responses in neurons processing the hedonic value of taste revealed differences between the two areas in temporal dynamics and sensitivities to palatability. These results add mPFC to the network of areas involved in processing gustatory stimuli and demonstrate significant differences in taste-coding between GC and mPFC.

Published

2013

8. Learning-Related Plasticity of Temporal Coding in Simultaneously Recorded Amygdala–Cortical Ensembles

Author

Jeffrey S Wieskopf, Donald B. Katz, Alfredo Fontanini, and Stephen E. Grossman

Subjects

Cerebral Cortex, Male, Taste, Neuronal Plasticity, Time Factors, General Neuroscience, Sensory system, Articles, Stimulus (physiology), Amygdala, Rats, Electrophysiology, medicine.anatomical_structure, Neural Pathways, medicine, Taste aversion, Animals, Learning, Female, Rats, Long-Evans, Gustatory cortex, Psychology, Neuroscience, Basolateral amygdala

Abstract

Emotional learning requires the coordinated action of neural populations in limbic and cortical networks. Here, we performed simultaneous extracellular recordings from gustatory cortical (GC) and basolateral amygdalar (BLA) neural ensembles as awake, behaving rats learned to dislike the taste of saccharin [via conditioned taste aversion (CTA)]. Learning-related changes in single-neuron sensory responses were observed in both regions, but the nature of the changes was region specific. In GC, most changes were restricted to relatively late aspects of the response (starting ∼1.0 s after stimulus administration), supporting our hypothesis that in this paradigm palatability-related information resides exclusively in later cortical responses. In contrast, and consistent with data suggesting the amygdala's primary role in judging stimulus palatability, CTA altered all components of BLA taste responses, including the earliest. Finally, learning caused dramatic increases in the functional connectivity (measured in terms of cross-correlation peak heights) between pairs of simultaneously recorded BLA and GC neurons, increases that were evident only during taste processing. Our simultaneous assays of the activity of single neurons in multiple relevant brain regions across learning suggest that the transmission of taste information through amygdala–cortical circuits plays a vital role in CTA memory formation.

Published

2008

9. Ketamine-Xylazine-Induced Slow (< 1.5 Hz) Oscillations in the Rat Piriform (Olfactory) Cortex Are Functionally Correlated with Respiration

Author

James M. Bower, Alfredo Fontanini, and PierFranco Spano

Subjects

Xylazine, Olfactory system, Periodicity, Behavioral/Systems/Cognitive, Biology, Membrane Potentials, Rats, Sprague-Dawley, Biological Clocks, Physical Stimulation, Cortex (anatomy), Piriform cortex, Respiration, medicine, Animals, Extracellular field potential, Neurons, Membrane potential, Pyramidal Cells, General Neuroscience, Olfactory Pathways, Electric Stimulation, Rats, Olfactory bulb, medicine.anatomical_structure, Breathing, Drug Therapy, Combination, Ketamine, Tracheotomy, Sleep, Neuroscience

Abstract

The occurrence of low frequency (in vivointracellular and extracellular field potential recordings obtained under conditions of ketamine-xylazine anesthesia to examine slow-wave behavior in the olfactory system. We demonstrate the occurrence of low-frequency oscillations in field potentials of both the olfactory bulb and cortex and in the membrane potentials of cortical pyramidal cells. By monitoring ongoing breathing, we also show that these oscillations are all correlated with the natural breathing cycle. Using a tracheotomized preparation, we demonstrate that slow oscillatory patterns could occasionally be produced even when air is no longer entering the nose, supporting the view that the olfactory system has an intrinsic propensity to oscillate. However, in the case of tracheotomized rats, the amplitude and regularity of the oscillations as well as their patterns of correlation are disrupted. All temporal relationships were restored when air was pulsed into the nostrils. We conclude that, in the olfactory system of freely breathing rats, there is a strong relationship between the occurrence and timing of slow oscillations and the ongoing periodic sensory input resulting from respiration. This coupling between olfactory cortex slow oscillations and respiration may result from the interaction between respiratory-related rhythmic input and the tendency for olfactory structures to oscillate intrinsically. We believe this finding has important functional as well as evolutionary implications.

Published

2003