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Peripheral Feedback Mechanisms Acting On The Central Pattern Generators For Locomotion In Fish And Cat.

O. Andersson, H. Forssberg, S. Grillner, P. Wallén
Published 1981 · Chemistry, Medicine

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The feedback mechanisms taking part in the control of locomotion in cat and fish are reviewed, particularly with regard to position- and movement-related feedback. It is shown that in both fish and cat there is a powerful position-dependent negative feedback which will act only in the position range where the muscle activity normally changes, e.g., from extensor to flexor activity. In addition, there is positive feedback in the middle of the movement range which will act in certain conditions, e.g., to promote and maintain flexor activity during the flexion of the hind limb.



This paper is referenced by
10.1016/0014-4886(87)90172-5
Effect of experimentally elicited rhythmic oral activity on the linguodigastric reflex in the lightly anesthetized rabbit
A. Thexton (1987)
10.1038/323440A0
Two identified afferent neurones entrain a central locomotor rhythm generator
K. Sillar (1986)
On peripheral control mechanisms acting on the central pattern generators for swimming in the dogfish.
S. Grillner (1982)
10.1523/JNEUROSCI.08-01-00133.1988
Features of entrainment of spinal pattern generators for locomotor activity in the lamprey spinal cord
A. McClellan (1988)
10.1007/978-94-011-7084-0_21
The Role of Movement-Related Feedback in The Control of Locomotion in Fish and Lamprey
P. Wallén (1985)
10.1007/978-1-349-06022-1_45
On the feedback control of the cat’s hindlimb during locomotion
O. Andersson (1981)
10.1101/141911
Distributed rhythm generators underlie Caenorhabditis elegans forward locomotion
Anthony D Fouad (2017)
10.1007/978-1-62703-197-4_8
The Cat Model of Spinal Cord Injury
A. Frigon (2013)
The Influence of the Initiation of a Graded Exercise Protocol on Dynamic Postural Stability Following a Concussion
L. Hunter (2013)
10.1007/978-3-642-78102-5_23
Entrainment of the Spinal Neuronal Network Generating Locomotion
G. V. D. Prisco (1993)
10.1109/ACC.1997.611976
Central pattern generators and their interaction with sensory feedback
P. Wallen (1997)
10.1007/BF00204664
Interruption of searching movements of partly restrained front legs of stick insects, a model situation for the start of a stance phase?
U. Bässler (2004)
10.1152/JN.1983.49.5.1168
Phase-dependent influences of wing stretch receptors on flight rhythm in the locust.
K. Pearson (1983)
10.1007/978-94-011-7084-0_3
Neural Control of Vertebrate Locomotion - Central Mechanisms and Reflex Interaction with Special Reference to the Cat
S. Grillner (1985)
10.1310/E3W4-PCN9-V5FY-900A
Pattern Generators in Locomotion: Implications for Recovery of Walking After Spinal Cord Injury
S. Harkema (2000)
10.1007/978-94-011-7084-0_20
Are there Central Pattern Generators for Walking and Flight in Insects
K. Pearson (1985)
10.1007/BF01342705
Entrainment of the locust central flight oscillator by wing stretch receptor stimulation
D. N. Reye (2005)
Organização central na geração de ajustes posturais reativos em idosos
S. Paulo. (2013)
Neural mechanisms of gait regulation and olfactory plasticity in Caenorhabditis elegans
Y. Shen (2015)
10.1038/s41593-019-0536-7
Sensory cortical control of movement
S. Karadimas (2019)
10.1152/JN.1990.64.5.1555
Sensory input induces long-lasting changes in the output of the lobster pyloric network.
S. Hooper (1990)
10.1002/JEZ.1402500302
Effect of sensory input from the tongue on jaw movement in normal feeding in the opossum.
A. Thexton (1989)
In its natural habitat, a fish must continuously adapt its
P. Wallén (1985)
10.1126/SCIENCE.3975635
Neurobiological bases of rhythmic motor acts in vertebrates.
S. Grillner (1985)
10.1016/0165-0270(87)90120-8
In vitro CNS preparations: unique approaches to the study of command and pattern generation systems in motor control
A. McClellan (1987)
10.1101/2020.06.22.164939
Phase response analyses support a relaxation oscillator model of locomotor rhythm generation in Caenorhabditis elegans
Hongfei Ji (2020)
Entrainment of the Breathing Rhythm of the Carp by Imposed Oscillation of the Gill Arches
P. D. Graaf (1991)
10.1523/JNEUROSCI.10-05-01495.1990
Neuromodulation of the crab pyloric central pattern generator by serotonergic/cholinergic proprioceptive afferents
P. Katz (1990)
10.1111/J.1748-1716.1983.TB07193.X
On the control of myotomal motoneurones during "fictive swimming" in the lamprey spinal cord in vitro.
D. Russell (1983)
10.1016/S0165-0173(02)00193-5
Cellular bases of a vertebrate locomotor system–steering, intersegmental and segmental co-ordination and sensory control
S. Grillner (2002)
10.1093/PTJ/82.1.69
Central pattern generation of locomotion: a review of the evidence.
M. MacKay-Lyons (2002)
10.1016/0168-0102(84)90003-8
Disruption of fore- and hindlimb coordination during overground locomotion in cats with bilateral serial hemisection of the spinal cord
M. Kato (1984)
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