Central Pattern Generation of Locomotion: A Review of the Evidence

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Spinal Cord Injury Special Series

Central Pattern Generation of Locomotion: A Review of the Evidence

Marilyn MacKay-Lyons

M MacKay-Lyons, PT, PhD, is Assistant Professor, School of Physiotherapy, Dalhousie University, 5869 University Ave, Halifax, Nova Scotia, Canada, B3H 3J5 (m.mackay-lyons{at}dal.ca)

Neural networks in the spinal cord, referred to as "centralpattern generators" (CPGs), are capable of producing rhythmicmovements, such as swimming, walking, and hopping, even whenisolated from the brain and sensory inputs. This article reviewsthe evidence for CPGs governing locomotion and addresses otherfactors, including supraspinal, sensory, and neuromodulatoryinfluences, that interact with CPGs to shape the final motoroutput. Supraspinal inputs play a major role not only in initiatinglocomotion but also in adapting the locomotor pattern to environmentaland motivational conditions. Sensory afferents involved in muscleand cutaneous reflexes have important regulatory functions inpreserving balance and ensuring stable phase transitions inthe locomotor cycle. Neuromodulators evoke changes in cellularand synaptic properties of CPG neurons, conferring flexibilityto CPG circuits. Briefly addressed is the interaction of CPGnetworks to produce intersegmental coordination for locomotion.Evidence for CPGs in humans is reviewed, and although a comprehensiveclinical review is not an objective, examples are provided ofanimal and human studies that apply knowledge of CPG mechanismsto improve locomotion. The final section deals with future directionsin CPG research.

Key Words: Central pattern generator • Locomotion • Movement sciences • Rehabilitation • Spinal cord

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