Normalization by valence and motivational intensity in the sensorimotor cortices (PMd, M1, and S1)

Zhao Yao; John P. Hessburg; Joseph Thachil Francis

doi:10.1038/s41598-021-03200-3

Normalization by Valence and Motivational Intensity in the Primary Sensorimotor Cortices (PMd, M1 and S1)

10.1101/702050 ◽

2019 ◽

Cited By ~ 2

Author(s):

Zhao Yao ◽

John P Hessburg ◽

Joseph Thachil Francis

Keyword(s):

Grip Force ◽

Dynamic Range ◽

Receptive Fields ◽

Small Range ◽

Bonnet Macaque ◽

Time Out ◽

Motivational Intensity ◽

Motor Control System ◽

Cortical Regions ◽

Human Primate

AbstractOur brain’s ability to represent vast amounts of information, such as continuous ranges of reward spanning orders of magnitude, with limited dynamic range neurons, may be possible due to normalization. Recently our group and others have shown that the sensorimotor cortices are sensitive to reward value. In order to determine if normalization plays a role in the sensorimotor cortices when considering non-sensorimotor variables, such as valence and motivational intensity, we had two non-human primate (NHP) subjects (one male bonnet macaque and one female rhesus macaque) make cued grip-force movements while simultaneously cueing the level of possible reward if successful, or time-out punishment if unsuccessful. We recorded simultaneously from 96 electrodes in each the somatosensory, motor and dorsal premotor cortices (S1, M1, PMd). We utilized several normalization models for valence, and motivational intensity in all three regions. We found three types of divisive normalized relationships between neural activity and the representation of reward and punishment, linear, sigmodal and hyperbolic. The hyperbolic relationships resemble receptive fields in psychological affect space, where a unit is particularly sensitive to a small range of the valence/motivational space. We found that these cortical regions have both strong valence and motivational intensity representations.Significance StatementBrain machine interfaces (BMIs) are likely to make their way into the clinical setting in the future. Increasing stability of brain derived control of such BMI systems is one essential aspect towards user acceptance, and stability must be maintained no matter the emotional state of the user. However, it is well known that we move faster for rewards of higher magnitude, indicating that emotions influence the motor control system, where BMI control signals come from. Here we report widespread affective modulation of the sensorimotor regions (PMd, PMv, M1 and S1) by cued levels of possible reward if successful and time-out punishment if unsuccessful in non-human primates, and that affect divisively normalizes these regions activity.

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Faculty Opinions recommendation of Resting-state neural activity across face-selective cortical regions is behaviorally relevant.

Faculty Opinions – Post-Publication Peer Review of the Biomedical Literature ◽

10.3410/f.13135958.14465056 ◽

2011 ◽

Author(s):

Cheryl Grady

Keyword(s):

Neural Activity ◽

Resting State ◽

Cortical Regions

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Implantable hearing interfaces

10.1093/oso/9780199674923.003.0054 ◽

2018 ◽

Author(s):

Torsten Lehmann ◽

André van Schaik

Keyword(s):

Cochlear Implants ◽

Neural Activity ◽

Dynamic Range ◽

Systems Design ◽

Fundamental Operation ◽

Profound Hearing Loss ◽

Biomedical Implant ◽

Dynamic Range Compression ◽

Hearing Function ◽

Key Aspects

The chapter Implantable hearing interfaces describes the fundamental operation of a commonly available biohybrid system, the cochlear implant, or bionic ear. This neuro-stimulating biomedical implant is very successful in restoring hearing function to people with profound hearing loss. The fundamental operation of the biological cochlea is described and parallels are drawn between key aspects of the biological system and the biohybrid implementation: dynamic range compression, translation of sound to neural activity, and tonotopic mapping. Critical considerations are discussed for simultaneously meeting biological, surgical, and engineering restrictions in successful biohybrid systems design. Finally, challenges in present and future cochlear implants are outlined and directions of current research given.

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Mirror neurons are modulated by grip force and reward expectation in the sensorimotor cortices (S1, M1, PMd, PMv)

Scientific Reports ◽

10.1038/s41598-021-95536-z ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Md Moin Uddin Atique ◽

Joseph Thachil Francis

Keyword(s):

Neural Activity ◽

Visual Information ◽

Mirror Neurons ◽

Grip Force ◽

Neural Representation ◽

Virtual Object ◽

Time Lags ◽

Subjective Value ◽

Machine Interface ◽

Definition Of

AbstractMirror Neurons (MNs) respond similarly when primates make or observe grasping movements. Recent work indicates that reward expectation influences rostral M1 (rM1) during manual, observational, and Brain Machine Interface (BMI) reaching movements. Previous work showed MNs are modulated by subjective value. Here we expand on the above work utilizing two non-human primates (NHPs), one male Macaca Radiata (NHP S) and one female Macaca Mulatta (NHP P), that were trained to perform a cued reward level isometric grip-force task, where the NHPs had to apply visually cued grip-force to move and transport a virtual object. We found a population of (S1 area 1–2, rM1, PMd, PMv) units that significantly represented grip-force during manual and observational trials. We found the neural representation of visually cued force was similar during observational trials and manual trials for the same units; however, the representation was weaker during observational trials. Comparing changes in neural time lags between manual and observational tasks indicated that a subpopulation fit the standard MN definition of observational neural activity lagging the visual information. Neural activity in (S1 areas 1–2, rM1, PMd, PMv) significantly represented force and reward expectation. In summary, we present results indicating that sensorimotor cortices have MNs for visually cued force and value.

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Activation of Spinal Wide Dynamic Range Neurons by Intracutaneous Microinjection of Nicotine

Journal of Neurophysiology ◽

10.1152/jn.1999.82.6.3046 ◽

1999 ◽

Vol 82 (6) ◽

pp. 3046-3055 ◽

Cited By ~ 26

Author(s):

Steven L. Jinks ◽

E. Carstens

Keyword(s):

Nicotinic Acetylcholine Receptors ◽

Acetylcholine Receptors ◽

Dynamic Range ◽

Receptive Fields ◽

Threshold Region ◽

Partial Recovery ◽

Evoked Responses ◽

Wide Dynamic Range ◽

Analgesic Effects ◽

Wdr Neurons

Nicotine evokes pain in the skin and oral mucosa and excites a subpopulation of cutaneous nociceptors, but little is known about the central transmission of chemogenic pain. We have investigated the responses of lumbar spinal wide dynamic range (WDR)-type dorsal horn neurons to intracutaneous (ic) microinjection of nicotine in pentobarbital-anesthetized rats. Nearly all (97%) units responded to nicotine microinjected ic (1 μl) into the low-threshold region of the hind-paw mechanosensitive receptive field in a concentration-related manner (0.01–10%). Responses to repeated injections of 10% nicotine exhibited tachyphylaxis at 5-, 10-, and 15-min interstimulus intervals. Significant tachyphylaxis was not seen with 1% nicotine. All nicotine-responsive units tested ( n = 30) also responded to ic histamine (1 μl, 3%) and did not exhibit tachyphylaxis to repeated histamine. However, there was significant cross-tachyphylaxis of nicotine to histamine. Thus 5 min after ic nicotine, histamine-evoked responses were attenuated significantly compared with the initial histamine-evoked response prior to nicotine, with partial recovery over the ensuing 15 min. Neuronal excitation by ic nicotine was not mediated by histamine H1 receptors because ic injection of the H1 receptor antagonist, cetirizine, had no effect on ic nicotine-evoked responses, whereas it significantly attenuated ic histamine-evoked responses in the same neurons. The lowest-threshold portion of cutaneous receptive fields showed a significant expansion in area at 20 min after ic nicotine 10%, indicative of sensitization. Responses to 1% nicotine were significantly reduced after ic injection of the nicotinic antagonist, mecamylamine (0.1% ic), with no recovery over the ensuing 40–60 min. These data indicate that nicotine ic excites spinal WDR neurons, partly via neuronal nicotinic acetylcholine receptors that are presumably expressed in cutaneous nociceptor terminals. Repeated injections of high concentrations of nicotine led to tachyphylaxis and cross-tachyphylaxis with histamine, possibly relevant to peripheral analgesic effects of nicotine.

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Patterns of EEG Activity in Individuals with Autism Spectrum Disorders

Psychological Science and Education ◽

10.17759/pse.2016210306 ◽

2016 ◽

Vol 21 (3) ◽

pp. 47-55

Author(s):

M.A. Zhukova

Keyword(s):

Autism Spectrum Disorders ◽

Neural Activity ◽

Low Frequency ◽

Strong Relationship ◽

Autism Spectrum ◽

Semantic Integration ◽

Adults With Autism ◽

Eeg Activity ◽

Spectrum Disorders ◽

Cortical Regions

The article reviews most recent findings on neural activity in children and adults with autism spectrum disorders (ASD). Most of the studies demonstrate decreased connectivity in cortical regions, excitatory/inhibitory imbalance and atypical processing of language in people with ASD. It is argued that difficulties in semantic integration are connected to selective insensitivity to language, which is manifested in atypical N400 ERP component. In the article we analyze the data suggesting a strong relationship between ASD and epilepsy and argue that the comorbidity is more prevalent among individuals who have cognitive dysfunction. The EEG profile of people with ASD suggests U-shaped alterations with excess in high- and low-frequency EEG bands. We critically analyze the “broken mirror” hypothesis of ASD and demonstrate findings which challenge this theory.

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Primate nucleus gracilis neurons: responses to innocuous and noxious stimuli

Journal of Neurophysiology ◽

10.1152/jn.1988.59.3.886 ◽

1988 ◽

Vol 59 (3) ◽

pp. 886-907 ◽

Cited By ~ 56

Author(s):

D. G. Ferrington ◽

J. W. Downie ◽

W. D. Willis

Keyword(s):

Conduction Velocity ◽

Dynamic Range ◽

Subcutaneous Tissue ◽

Receptive Fields ◽

High Threshold ◽

Spinothalamic Tract ◽

Sinusoidal Vibration ◽

Nucleus Gracilis ◽

Pressure Sensitive ◽

Stimulation Of

1. Recordings were made from 67 neurons in the nucleus gracilis (NG) of anesthetized macaque monkeys. All of the cells were activated antidromically from the ventral posterior lateral (VPL) nucleus of the contralateral thalamus. Stimuli used to activate the cells orthodromically were graded innocuous and noxious mechanical stimuli, including sinusoidal vibration and thermal pulses. 2. The latencies of antidromic action potentials following stimulation in the VPL nucleus were significantly shorter for cells in the caudal compared with the rostral NG. The mean minimum afferent conduction velocity of the afferent conduction velocity of the afferent fibers exciting the NG cells was 52 m/s, as judged from the latencies of the cells to orthodromic volleys evoked by electrical stimulation of peripheral nerves. The overall conduction velocity of the pathway from peripheral nerve to thalamus was approximately 40 m/s. 3. Cutaneous receptive fields on the distal hindlimb usually occupied an area equivalent to much less than a single digit. However, a few cells had receptive fields up to or exceeding the area of the foot. 4. NG cells were classified by their responses to graded mechanical stimulation of the skin as low threshold (LT) or wide dynamic range (WDR). No high-threshold NG cells were found. A special subcategory of pressure-sensitive LT (SA) neurons was recognized. Many of these cells were maximally responsive to maintained indentation of the skin. The sample of NG cells differed from the population of primate spinothalamic and spinocervicothalamic pathways so far examined, in having a larger proportion of LT neurons and a smaller proportion of WDR cells. A few NG cells responded best to manipulation of subcutaneous tissue. 5. Discriminant analysis permitted the NG cells to be assigned to classes determined by a k-means cluster analysis of the responses of a reference set of 318 primate spinothalamic tract (STT) cells. There were four classes of cells based on normalized responses of individual neurons and another four classes based upon responses compared across the population of cells. The NG cells were allocated to the various categories in different proportions than either primate STT cells or spinocervicothalamic neurons, consistent with the view that the functional roles of these somatosensory pathways differ. 6. Some of the pressure-sensitive NG cells were excited when the skin was stretched, suggesting an input from type II slowly adapting (Ruffini) mechanoreceptors.(ABSTRACT TRUNCATED AT 400 WORDS)

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Response and receptive-field properties of spinomesencephalic tract cells in the cat

Journal of Neurophysiology ◽

10.1152/jn.1986.55.1.76 ◽

1986 ◽

Vol 55 (1) ◽

pp. 76-96 ◽

Cited By ~ 41

Author(s):

R. P. Yezierski ◽

R. H. Schwartz

Keyword(s):

Spinal Cord ◽

Receptive Field ◽

Dynamic Range ◽

Receptive Fields ◽

The Body ◽

Noxious Stimulation ◽

Primary Afferent ◽

Receptive Field Properties ◽

Afferent Fibers ◽

Primary Afferent Fibers

Recordings were made from 90 identified spinomesencephalic tract (SMT) cells in the lumbosacral spinal cord of cats anesthetized with alpha-chloralose and pentobarbital sodium. Recording sites were located in laminae I-VIII. Antidromic stimulation sites were located in different regions of the rostral and caudal midbrain including the periaqueductal gray, midbrain reticular formation, and the deep layers of the superior colliculus. Twelve SMT cells were antidromically activated from more than one midbrain level or from sites in the medial thalamus. The mean conduction velocity for the population of cells sampled was 45.2 +/- 21.4 m/s. Cells were categorized based on their responses to graded intensities of mechanical stimuli and the location of excitatory and/or inhibitory receptive fields. Four major categories of cells were encountered: wide dynamic range (WDR); high threshold (HT); deep/tap; and nonresponsive. WDR and HT cells had excitatory and/or inhibitory receptive fields restricted to the ipsilateral hindlimb or extending to other parts of the body including the tail, forelimbs, and face. Some cells had long afterdischarges following noxious stimulation, whereas others had high rates of background activity that was depressed by nonnoxious and noxious stimuli. Deep/tap cells received convergent input from muscle, joint, or visceral primary afferent fibers. The placement of mechanical lesions at different rostrocaudal levels of the cervical spinal cord provided information related to the spinal trajectory of SMT axons. Six axons were located contralateral to the recording electrode in the ventrolateral/medial or lateral funiculi while two were located in the ventrolateral funiculus of the ipsilateral spinal cord. Stimulation at sites used to antidromically activate SMT cells resulted in the inhibition of background and evoked responses for 22 of 25 cells tested. Inhibitory effects were observed on responses evoked by low/high intensity cutaneous stimuli and by the activation of joint or muscle primary afferent fibers. Based on the response and receptive-field properties of SMT cells it is suggested that the SMT may have an important role in somatosensory mechanisms, particularly those related to nociception.

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Spatial precision of population activity in primate area MT

Journal of Neurophysiology ◽

10.1152/jn.00152.2015 ◽

2015 ◽

Vol 114 (2) ◽

pp. 869-878 ◽

Cited By ~ 13

Author(s):

Spencer C. Chen ◽

John W. Morley ◽

Samuel G. Solomon

Keyword(s):

Neural Activity ◽

Visual Processing ◽

Receptive Fields ◽

Object Motion ◽

Spatial Position ◽

Multielectrode Arrays ◽

Visual World ◽

Population Activity ◽

Area Mt ◽

Mt Neurons

The middle temporal (MT) area is a cortical area integral to the “where” pathway of primate visual processing, signaling the movement and position of objects in the visual world. The receptive field of a single MT neuron is sensitive to the direction of object motion but is too large to signal precise spatial position. Here, we asked if the activity of MT neurons could be combined to support the high spatial precision required in the where pathway. With the use of multielectrode arrays, we recorded simultaneously neural activity at 24–65 sites in area MT of anesthetized marmoset monkeys. We found that although individual receptive fields span more than 5° of the visual field, the combined population response can support fine spatial discriminations (<0.2°). This is because receptive fields at neighboring sites overlapped substantially, and changes in spatial position are therefore projected onto neural activity in a large ensemble of neurons. This fine spatial discrimination is supported primarily by neurons with receptive fields flanking the target locations. Population performance is degraded (by 13–22%) when correlations in neural activity are ignored, further reflecting the contribution of population neural interactions. Our results show that population signals can provide high spatial precision despite large receptive fields, allowing area MT to represent both the motion and the position of objects in the visual world.

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Alteration of Medullary Dorsal Horn Neuronal Activity Following Inferior Alveolar Nerve Transection in Rats

Journal of Neurophysiology ◽

10.1152/jn.2001.86.6.2868 ◽

2001 ◽

Vol 86 (6) ◽

pp. 2868-2877 ◽

Cited By ~ 60

Author(s):

Koichi Iwata ◽

Takao Imai ◽

Yoshiyuki Tsuboi ◽

Akimasa Tashiro ◽

Akiko Ogawa ◽

...

Keyword(s):

Dorsal Horn ◽

Neuronal Activity ◽

Dynamic Range ◽

Escape Behavior ◽

Receptive Fields ◽

Inferior Alveolar Nerve ◽

Skin Incision ◽

Medullary Dorsal Horn ◽

Whisker Pad ◽

Wdr Neurons

The effects of inferior alveolar nerve (IAN) transection on escape behavior and MDH neuronal activity to noxious and nonnoxious stimulation of the face were precisely analyzed. Relative thresholds for escape from mechanical stimulation applied to the whisker pad area ipsilateral to the transection were significantly lower than that for the contralateral and sham-operated whisker pad until 28 days after the transection, then returned to the preoperative level at 40 days after transection. A total of 540 neurons were recorded from the medullary dorsal horn (MDH) of the nontreated naive rats [low-threshold mechanoreceptive (LTM), 27; wide dynamic range (WDR), 31; nociceptive specific (NS), 11] and sham-operated rats with skin incision (LTM, 34; WDR, 30; NS, 23) and from the ipsilateral (LTM, 82; WDR, 82; NS, 31) and contralateral MDH relative to the IAN transection (LTM, 77; WDR, 82; NS, 33). The electrophysiological properties of these neurons were precisely analyzed. Background activity of WDR neurons on the ipsilateral side relative to the transection was significantly increased at 2–14 days after the operation as compared with that of naive rats. Innocuous and noxious mechanical-evoked responses of LTM and WDR neurons were significantly enhanced at 2–14 days after IAN transection. The mean area of the receptive fields of WDR neurons was significantly larger on the ipsilateral MDH at 2–7 days after transection than that of naive rats. We could not observe any modulation of thermal responses of WDR and NS neurons following IAN transection. Also, no MDH neurons were significantly affected in the rats with sham operations. The present findings suggest that the increment of neuronal activity of WDR neurons in the MDH following IAN transection may play an important role in the development of the mechano-allodynia induced in the area adjacent to the area innervated by the injured nerve.

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