Activity of motor cortex neurons during backward locomotion

Zelenin, Pavel V.; Deliagina, T. G.; Orlovsky, G. N.; Karayannidou, Anastasia; Stout, Erik E.; Sirota, Mikhail G.; Beloozerova, Irina N.

doi:10.1152/jn.00120.2011

Cited by 26 publications

(25 citation statements)

References 37 publications

(43 reference statements)

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“…The right and left limbs were stepping in anti-phase. These characteristics of backward locomotor pattern were similar to those described earlier for intact (Buford and Smith, 1990; Buford et al, 1990; Zelenin et al, 2011) and decerebrate cats (Musienko et al, 2007). …”

Section: Resultssupporting

confidence: 87%

“…Most bipeds and quadrupeds, in addition to the main form of locomotion – forward walking, are also capable of backward and sideward walking (e.g. Stein et al, 1986; Buford and Smith, 1990; Buford et al, 1990; Rossignol, 1996; Deliagina et al, 1997; Zelenin et al, 2011). Also, the steps deviated from the direction of progression are used for correcting perturbations of balance during forward walking (Karayannidou et al, 2009; Musienko et al, 2012).…”

Section: Introductionmentioning

confidence: 99%

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Spinal and Supraspinal Control of the Direction of Stepping during Locomotion

et al. 2012

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Most bipeds and quadrupeds, in addition to forward walking, are also capable of backward and sideward walking. The direction of walking is determined by the direction of stepping movements of individual limbs in relation to the front-to-rear body axis. Our goal was to assess the functional organization of the system controlling the direction of stepping. Experiments were carried out on decerebrate cats walking on the treadmill with their hindlimbs, whereas the head and trunk were rigidly fixed. Different directions of the treadmill motion relative to the body axis were used (0°, ±45°, ±90°, and 180°). For each direction, we compared locomotion evoked from the brainstem (by stimulation of the mesencephalic locomotor region, MLR) with locomotion evoked by epidural stimulation of the spinal cord (SC). It was found that SC stimulation evoked well-coordinated stepping movements at different treadmill directions. The direction of steps was opposite to the treadmill motion, suggesting that this direction was determined by sensory input from the limb during stance. Thus, SC stimulation activates limb controllers, which are able to generate stepping movements in different directions. By contrast, MLR stimulation evoked well-coordinated stepping movements only if the treadmill was moving in the front-to-rear direction. One can conclude that supraspinal commands (caused by MLR stimulation) select one of the numerous forms of operation of the spinal limb controllers, namely, the forward walking. The MLR can thus be considered as a command center for forward locomotion, which is the main form of progression in bipeds and quadrupeds.

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Section: Resultssupporting

confidence: 87%

Section: Introductionmentioning

confidence: 99%

Spinal and Supraspinal Control of the Direction of Stepping during Locomotion

et al. 2012

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“…There were no significant differences between the two sequences in the location of the most active voxel within the primary motor hand area contralateral to the performing hand or in the mean magnitude of activity evoked during the performance. The current results, therefore, are in line with the results of animal studies showing that the representation of motor sequences in M1 may not be reliably assessed by averaging neuronal activity (Zelenin et al, 2011;Ben-Shaul et al, 2004;Hatsopoulos, Paninski, & Donoghue, 2003). There are data suggesting that different tasks can be reliably expressed in the modulation patterns rather than in the population mean of activity of motor cortex neurons (Zelenin et al, 2011), presumably reflecting the fact that the same neuronal pool in the motor cortex can be recruited in different tasks ( Yang et al, 2014;Zelenin et al, 2011).…”

Section: Discussionsupporting

confidence: 88%

Patterns of Modulation in the Activity and Connectivity of Motor Cortex during the Repeated Generation of Movement Sequences

Gabitov

Manor

Karni

2015

Journal of Cognitive Neuroscience

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It is not clear how the engagement of motor mnemonic processes is expressed in online brain activity. We scanned participants, using fMRI, during the paced performance of a finger-to-thumb opposition sequence (FOS), intensively trained a day earlier (T-FOS), and a similarly constructed, but novel, untrained FOS (U-FOS). Both movement sequences were performed in pairs of blocks separated by a brief rest interval (30 sec). We have recently shown that in the primary motor cortex (M1) motor memory was not expressed in the average signal intensity but rather in the across-block signal modulations, that is, when comparing the first to the second performance block across the brief rest interval. Here, using an M1 seed, we show that for the T-FOS, the M1-striatum functional connectivity decreased across blocks; however, for the U-FOS, connectivity within the M1 and between M1 and striatum increased. In addition, in M1, the pattern of within-block signal change, but not signal variability per se, reliably differentiated the two sequences. Only for the U-FOS and only within the first blocks in each pair, the signal significantly decreased. No such modulation was found within the second corresponding blocks following the brief rest interval in either FOS. We propose that a network including M1 and striatum underlies online motor working memory. This network may promote a transient integrated representation of a new movement sequence and readily retrieves a previously established movement sequence representation. Averaging over single events or blocks may not capture the dynamics of motor representations that occur over multiple timescales.

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“…How the different commands are channeled to spinal cord networks remains poorly understood. In a few previous studies, the activity of forelimb-and hindlimb-related PTNs were compared and it was found that while some quantitative differences exist, qualitatively, commands sent by PTNs to forelimbs and hindlimbs are quite similar (Karayannidou et al 2009;Widajewicz et al 1994;Zelenin et al 2011). In this study we hypothesized that there are different spinal targets within each girdle's neuronal network that receive different signals from the motor cortex during locomotion.…”

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confidence: 81%

Pyramidal tract neurons receptive to different forelimb joints act differently during locomotion

Stout

Beloozerova

2012

Journal of Neurophysiology

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During locomotion, motor cortical neurons projecting to the pyramidal tract (PTNs) discharge in close relation to strides. How their discharges vary based on the part of the body they influence is not well understood. We addressed this question with regard to joints of the forelimb in the cat. During simple and ladder locomotion, we compared the activity of four groups of PTNs with somatosensory receptive fields involving different forelimb joints: 1) 45 PTNs receptive to movements of shoulder, 2) 30 PTNs receptive to movements of elbow, 3) 40 PTNs receptive to movements of wrist, and 4) 30 nonresponsive PTNs. In the motor cortex, a relationship exists between the location of the source of afferent input and the target for motor output. On the basis of this relationship, we inferred the forelimb joint that a PTN influences from its somatosensory receptive field. We found that different PTNs tended to discharge differently during locomotion. During simple locomotion shoulder-related PTNs were most active during late stance/early swing, and upon transition from simple to ladder locomotion they often increased activity and stride-related modulation while reducing discharge duration. Elbow-related PTNs were most active during late swing/early stance and typically did not change activity, modulation, or discharge duration on the ladder. Wrist-related PTNs were most active during swing and upon transition to the ladder often decreased activity and increased modulation while reducing discharge duration. These data suggest that during locomotion the motor cortex uses distinct mechanisms to control the shoulder, elbow, and wrist.

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Activity of motor cortex neurons during backward locomotion

Cited by 26 publications

References 37 publications

Spinal and Supraspinal Control of the Direction of Stepping during Locomotion

Spinal and Supraspinal Control of the Direction of Stepping during Locomotion

Patterns of Modulation in the Activity and Connectivity of Motor Cortex during the Repeated Generation of Movement Sequences

Pyramidal tract neurons receptive to different forelimb joints act differently during locomotion

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