Cofer D et al. (2010). AnimatLab: a 3D graphics environment for neuromechanical simulations. Journal of neuroscience methods. 187 [PubMed]
Grillner S, McClellan A, Sigvardt K, Wallén P, Wilén M. (1981). Activation of NMDA-receptors elicits "fictive locomotion" in lamprey spinal cord in vitro. Acta physiologica Scandinavica. 113 [PubMed]
Hiebert GW, Pearson KG. (1999). Contribution of sensory feedback to the generation of extensor activity during walking in the decerebrate Cat. Journal of neurophysiology. 81 [PubMed]
Hunt A, Schmidt M, Fischer M, Quinn R. (2015). A biologically based neural system coordinates the joints and legs of a tetrapod. Bioinspiration & biomimetics. 10 [PubMed]
Hunt A, Szczecinski N, Quinn R. (2017). Development and Training of a Neural Controller for Hind Leg Walking in a Dog Robot. Frontiers in neurorobotics. 11 [PubMed]
Hägglund M et al. (2013). Optogenetic dissection reveals multiple rhythmogenic modules underlying locomotion. Proceedings of the National Academy of Sciences of the United States of America. 110 [PubMed]
Lafreniere-Roula M, McCrea DA. (2005). Deletions of rhythmic motoneuron activity during fictive locomotion and scratch provide clues to the organization of the mammalian central pattern generator. Journal of neurophysiology. 94 [PubMed]
Markin SN, Lemay MA, Prilutsky BI, Rybak IA. (2012). Motoneuronal and muscle synergies involved in cat hindlimb control during fictive and real locomotion: a comparison study. Journal of neurophysiology. 107 [PubMed]
McCrea DA, Rybak IA. (2008). Organization of mammalian locomotor rhythm and pattern generation. Brain research reviews. 57 [PubMed]
Mussa-Ivaldi FA, Bizzi E. (2000). Motor learning through the combination of primitives. Philosophical transactions of the Royal Society of London. Series B, Biological sciences. 355 [PubMed]
Pearson K, Ekeberg O, Büschges A. (2006). Assessing sensory function in locomotor systems using neuro-mechanical simulations. Trends in neurosciences. 29 [PubMed]
Rybak IA, Shevtsova NA, Lafreniere-Roula M, McCrea DA. (2006). Modelling spinal circuitry involved in locomotor pattern generation: insights from deletions during fictive locomotion. The Journal of physiology. 577 [PubMed]
Rybak IA, Stecina K, Shevtsova NA, McCrea DA. (2006). Modelling spinal circuitry involved in locomotor pattern generation: insights from the effects of afferent stimulation. The Journal of physiology. 577 [PubMed]
Shevtsova NA, Rybak IA. (2016). Organization of flexor-extensor interactions in the mammalian spinal cord: insights from computational modelling. The Journal of physiology. 594 [PubMed]
Tryba AK, Peña F, Ramirez JM. (2006). Gasping activity in vitro: a rhythm dependent on 5-HT2A receptors. The Journal of neuroscience : the official journal of the Society for Neuroscience. 26 [PubMed]
Wenger N et al. (2016). Spatiotemporal neuromodulation therapies engaging muscle synergies improve motor control after spinal cord injury. Nature medicine. 22 [PubMed]
Zhang J et al. (2014). V1 and v2b interneurons secure the alternating flexor-extensor motor activity mice require for limbed locomotion. Neuron. 82 [PubMed]
Zhong G, Shevtsova NA, Rybak IA, Harris-Warrick RM. (2012). Neuronal activity in the isolated mouse spinal cord during spontaneous deletions in fictive locomotion: insights into locomotor central pattern generator organization. The Journal of physiology. 590 [PubMed]
d'Avella A, Saltiel P, Bizzi E. (2003). Combinations of muscle synergies in the construction of a natural motor behavior. Nature neuroscience. 6 [PubMed]