Your search keyword '"Masanori Kawabata"' showing total 5 results

1. A spike analysis method for characterizing neurons based on phase locking and scaling to the interval between two behavioral events

Author

Satoshi Nonomura, Yutaka Sakai, Masanori Kawabata, Junichi Yoshida, Shogo Soma, Akiko Saiki-Ishikawa, Yoshikazu Isomura, and Alain Ríos

Subjects

Cerebral Cortex, Male, Neurons, Time Factors, Dependency (UML), Behavior, Animal, Physiology, Computer science, General Neuroscience, Action Potentials, Models, Theoretical, medicine.anatomical_structure, Cerebral cortex, medicine, Animals, Interval (graph theory), Rats, Long-Evans, Spike (software development), Electrocorticography, Neuron, Latency (engineering), Neuroscience, Scaling, Analysis method

Abstract

Standard analysis of neuronal functions assesses the temporal correlation between animal behaviors and neuronal activity by aligning spike trains with the timing of a specific behavioral event, e.g., visual cue. However, spike activity is often involved in information processing dependent on a relative phase between two consecutive events rather than a single event. Nevertheless, less attention has so far been paid to such temporal features of spike activity in relation to two behavioral events. Here, we propose "Phase-Scaling analysis" to simultaneously evaluate the phase locking and scaling to the interval between two events in task-related spike activity of individual neurons. This analysis method can discriminate conceptual "scaled"-type neurons from "nonscaled"-type neurons using an activity variation map that combines phase locking with scaling to the interval. Its robustness was validated by spike simulation using different spike properties. Furthermore, we applied it to analyzing actual spike data from task-related neurons in the primary visual cortex (V1), posterior parietal cortex (PPC), primary motor cortex (M1), and secondary motor cortex (M2) of behaving rats. After hierarchical clustering of all neurons using their activity variation maps, we divided them objectively into four clusters corresponding to nonscaled-type sensory and motor neurons and scaled-type neurons including sustained and ramping activities, etc. Cluster/subcluster compositions for V1 differed from those of PPC, M1, and M2. The V1 neurons showed the fastest functional activities among those areas. Our method was also applicable to determine temporal "forms" and the latency of spike activity changes. These findings demonstrate its utility for characterizing neurons.

Published

2020

2. Automated and parallelized spike collision tests to identify spike signal projections

Author

Yutaka Sakai, Masanori Kawabata, Keita Mitani, and Yoshikazu Isomura

Subjects

medicine.anatomical_structure, Computer science, medicine, Excitatory postsynaptic potential, Spike (software development), Neuron, Optogenetics, Projection (set theory), Collision, Neuroscience, Signal, Antidromic

Abstract

The spike collision test is a highly reliable technique to identify axonal projection of a neuron recorded electrophysiologically for investigating functional spike information among brain areas. It is potentially applicable to more neuronal projections by combining multi-channel recording with optogenetic stimulation. Yet, it remains inefficient and laborious because an experimenter must visually select spikes in every channel and manually repeat spike collision tests for each neuron serially. Here, we established a novel technique to automatically perform spike collision tests for all channels in parallel (Multi-Linc analysis), employing two distinct protocols implemented in a multi-channel real-time processing system. The rat cortical neurons identified with this technique displayed physiological spike features consistent with excitatory projection neurons. Their antidromic spikes were similar in shape but slightly larger in amplitude compared with spontaneous spikes. In addition, we demonstrated simultaneous identification of reciprocal or bifurcating projections among cortical areas. Thus, our Multi-Linc analysis will be a powerful research approach to elucidate interareal spike communication.

Published

2021

3. Ipsilateral-Dominant Control of Limb Movements in Rodent Posterior Parietal Cortex

Author

Yoshikazu Isomura, Kazuto Kobayashi, Shigeki Kato, Yutaka Sakai, Masanori Kawabata, Junichi Yoshida, Satoshi Nonomura, Alain Ríos, Shogo Soma, Fusao Kato, Yukari Takahashi, and Yae K. Sugimura

Subjects

Male, 0301 basic medicine, Patch-Clamp Techniques, genetic structures, Movement, Channelrhodopsin, Posterior parietal cortex, Biology, Optogenetics, behavioral disciplines and activities, Functional Laterality, Lateralization of brain function, Premotor cortex, 03 medical and health sciences, 0302 clinical medicine, Channelrhodopsins, Parietal Lobe, Forelimb, medicine, Animals, gamma-Aminobutyric Acid, Research Articles, Electromyography, General Neuroscience, Motor Cortex, Rats, body regions, 030104 developmental biology, medicine.anatomical_structure, nervous system, Conditioning, Operant, Rats, Transgenic, Primary motor cortex, Neuroscience, Psychomotor Performance, psychological phenomena and processes, 030217 neurology & neurosurgery, Motor cortex

Abstract

It is well known that the posterior parietal cortex (PPC) and frontal motor cortices in primates preferentially control voluntary movements of contralateral limbs. The PPC of rats has been defined based on patterns of thalamic and cortical connectivity. The anatomical characteristics of this area suggest that it may be homologous to the PPC of primates. However, its functional roles in voluntary forelimb movements have not been well understood, particularly in the lateralization of motor limb representation; that is, the limb-specific activity representations for right and left forelimb movements. We examined functional spike activity of the PPC and two motor cortices, the primary motor cortex (M1) and the secondary motor cortex (M2), when head-fixed male rats performed right or left unilateral movements. Unlike primates, PPC neurons in rodents were found to preferentially represent ipsilateral forelimb movements, in contrast to the contralateral preference of M1 and M2 neurons. Consistent with these observations, optogenetic activation of PPC and motor cortices, respectively, evoked ipsilaterally and contralaterally biased forelimb movements. Finally, we examined the effects of optogenetic manipulation on task performance. PPC or M1 inhibition by optogenetic GABA release shifted the behavioral limb preference contralaterally or ipsilaterally, respectively. In addition, weak optogenetic PPC activation, which was insufficient to evoke motor responses by itself, shifted the preference ipsilaterally; although similar M1 activation showed no effects on task performance. These paradoxical observations suggest that the PPC plays evolutionarily different roles in forelimb control between primates and rodents.SIGNIFICANCE STATEMENTIn rodents, the primary and secondary motor cortices (M1 and M2, respectively) are involved in voluntary movements with contralateral preference. However, it remains unclear whether and how the posterior parietal cortex (PPC) participates in controlling multiple limb movements. We recorded functional activity from these areas using a behavioral task to monitor movements of the right and left forelimbs separately. PPC neurons preferentially represented ipsilateral forelimb movements and optogenetic PPC activation evoked ipsilaterally biased forelimb movements. Optogenetic PPC inhibition via GABA release shifted the behavioral limb preference contralaterally during task performance, whereas weak optogenetic PPC activation, which was insufficient to evoke motor responses by itself, shifted the preference ipsilaterally. Our findings suggest rodent PPC contributes to ipsilaterally biased motor response and/or planning.

Published

2018

4. In Vivo Spiking Dynamics of Intra- and Extratelencephalic Projection Neurons in Rat Motor Cortex

Author

Junichi Yoshida, Yoshikazu Isomura, Minoru Kimura, Yutaka Sakai, Kazuto Kobayashi, Shogo Soma, Masanori Kawabata, Hiromu Yawo, Ryoji Fukabori, and Akiko Saiki

Subjects

Male, Telencephalon, 0301 basic medicine, Cognitive Neuroscience, Thalamus, Action Potentials, Striatum, Biology, Optogenetics, Statistics, Nonparametric, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Channelrhodopsins, In vivo, Neural Pathways, medicine, Animals, Neurons, Membrane potential, Motor Cortex, Motor control, Rats, Luminescent Proteins, 030104 developmental biology, medicine.anatomical_structure, Nonlinear Dynamics, nervous system, Cerebral cortex, Rats, Transgenic, Neuroscience, 030217 neurology & neurosurgery, Motor cortex

Abstract

In motor cortex, 2 types of deep layer pyramidal cells send their axons to other areas: intratelencephalic (IT)-type neurons specifically project bilaterally to the cerebral cortex and striatum, whereas neurons of the extratelencephalic (ET)-type, termed conventionally pyramidal tract-type, project ipsilaterally to the thalamus and other areas. Although they have totally different synaptic and membrane potential properties in vitro, little is known about the differences between them in ongoing spiking dynamics in vivo. We identified IT-type and ET-type neurons, as well as fast-spiking-type interneurons, using novel multineuronal analysis based on optogenetically evoked spike collision along their axons in behaving/resting rats expressing channelrhodopsin-2 (Multi-Linc method). We found "postspike suppression" (~100 ms) as a characteristic of ET-type neurons in spike auto-correlograms, and it remained constant independent of behavioral conditions in functionally different ET-type neurons. Postspike suppression followed even solitary spikes, and spike bursts significantly extended its duration. We also observed relatively strong spike synchrony in pairs containing IT-type neurons. Thus, spiking dynamics in IT-type and ET-type neurons may be optimized differently for precise and coordinated motor control.

Published

2017

5. Differential Changes in the Lateralized Activity of Identified Projection Neurons of Motor Cortex in Hemiparkinsonian Rats

Author

Yutaka Sakai, Junichi Yoshida, Masanori Kawabata, Shogo Soma, Alain Ríos, Satoshi Nonomura, and Yoshikazu Isomura

Subjects

Male, home cage, motion detector, Movement, Population, continuous activity monitoring, physical activity, Biology, Novel Tools and Methods, Functional Laterality, Lesion, Parkinsonian Disorders, Dopamine, Neural Pathways, Basal ganglia, medicine, Animals, Rats, Long-Evans, education, Methods/New Tools, Neurons, education.field_of_study, Pyramidal tracts, Impaired Balance, General Neuroscience, Motor Cortex, General Medicine, Cortical neurons, Disease Models, Animal, medicine.anatomical_structure, 7.2, medicine.symptom, Neuroscience, Motor cortex, medicine.drug

Abstract

In the parkinsonian state, the motor cortex and basal ganglia (BG) undergo dynamic remodeling of movement representation. One such change is the loss of the normal contralateral lateralized activity pattern. The increase in the number of movement-related neurons responding to ipsilateral or bilateral limb movements may cause motor problems, including impaired balance, reduced bimanual coordination, and abnormal mirror movements. However, it remains unknown how individual types of motor cortical neurons organize this reconstruction. To explore the effect of dopamine depletion on lateralized activity in the parkinsonian state, we used a partial hemiparkinsonian model [6-hydroxydopamine (6-OHDA) lesion] in Long–Evans rats performing unilateral movements in a right–left pedal task, while recording from primary (M1) and secondary motor cortex (M2). The lesion decreased contralateral preferred activity in both M1 and M2. In addition, this change differed among identified intratelencephalic (IT) and pyramidal tract (PT) cortical projection neurons, depending on the cortical area. We detected a decrease in lateralized activity only in PT neurons in M1, whereas in M2, this change was observed in IT neurons, with no change in the PT population. Our results suggest a differential effect of dopamine depletion in the lateralized activity of the motor cortex, and suggest possible compensatory changes in the contralateral hemisphere.

Published

2019