Cover not available
Article published In:
How the Brain Got Language: Towards a New Road Map
Edited by Michael A. Arbib
[Interaction Studies 19:1/2] 2018
► pp. 721

Computational challenges of evolving the language-ready brain

1. From manual action to protosign

| University of California at San Diego
Computational modeling of the macaque brain grounds hypotheses on the brain of LCA-m (the last common ancestor of monkey and human). Elaborations thereof provide a brain model for LCA-c (c for chimpanzee). The Mirror System Hypothesis charts further steps via imitation and pantomime to protosign and protolanguage on the path to a "language-ready brain" in Homo sapiens, with the path to speech being indirect. The material poses new challenges for both experimentation and modeling.
Keywords: action pattern reorganization, computational comparative neuroprimatology, imitation, language evolution, mirror system hypothesis, mirror systems, modeling cerebellum, speech evolution
Article outline
  • 1.The Mirror System Hypothesis (MSH) introduced
  • 2.Introducing computational comparative neuroprimatology
  • 3.Setting a baseline for LCA-m
    • 3.1The FARS (Fagg-Arbib-Rizzolatti-Sakata) model
    • 3.2Modeling mirror systems in action recognition
    • 3.3Flexible action patterns and their rapid reorganization
  • 4.An LCA-c innovation built on LCA-m mechanisms
  • 5.Varieties of imitation
  • 6.From imitation to pantomime
  • 7.Is the path to speech indirect?
    • 7.1Some macaque premotor neurons may control vocalization
    • 7.2Case study: The role of the cerebellum in prism adaptation
  • 8.Towards a new road map
  • Acknowledgements
  • References
Published online: 17 September 2018
DOI logo
https://doi.org/10.1075/is.17029.arb
References (40)
References
Aboitiz, F. (2018). Voice, gesture and working memory in the emergence of speech. Interaction Studies, 19(1–2), 70–85. DOI logoGoogle Scholar
Alstermark, B., Lundberg, A., Norrsell, U. & Sybirska, E. (1981). Integration in descending motor pathways controlling the forelimb in the cat: 9. Differential behavioural defects after spinal cord lesions interrupting defined pathways from higher centres to motoneurones. Experimental Brain Research, 421, 299–318. DOI logoGoogle Scholar
Arbib, M. A. (2005). Interweaving Protosign and Protospeech: Further Developments Beyond the Mirror. Interaction Studies: Social Behavior and Communication in Biological and Artificial Systems, 61, 145–171. DOI logoGoogle Scholar
(2007). How New Languages Emerge (Review of D. Lightfoot, 2006, How New Languages Emerge, Cambridge University Press). Linguist List, 18–432, Thu Feb 08 2007, [URL].
(2012). How the Brain Got Language: The Mirror System Hypothesis. New York & Oxford: Oxford University Press. DOI logoGoogle Scholar
(2016). Towards a Computational Comparative Neuroprimatology: Framing the Language-Ready Brain. Physics of Life Reviews, 161, 1–54. DOI logoGoogle Scholar
(2018). Computational Challenges of evolving the language-ready brain: 2. Building towards neurolinguistics. Interaction Studies, 19(1–2), 22–37. DOI logoGoogle Scholar
Arbib, M. A., Billard, A., Iacoboni, M. & Oztop, E. (2000). Synthetic brain imaging: grasping, mirror neurons and imitation. Neural Networks, 13(8–9), 975–997. DOI logoGoogle Scholar
Arbib, M. A., Ganesh, V. & Gasser, B. (2014). Dyadic Brain Modeling, Ontogenetic Ritualization of Gesture in Apes, and the Contributions of Primate Mirror Neuron Systems. Phil Trans Roy Soc B, 369 (1644), 20130414. DOI logoGoogle Scholar
Arbib, M. A. & Rizzolatti, G. (1997). Neural expectations: a possible evolutionary path from manual skills to language. Communication and Cognition, 291, 393–424.Google Scholar
Arbib, M. A., Schweighofer, N. & Thach, W. T. (1995) Modeling the Cerebellum: From Adaptation to Coordination in Glencross, D. J. & Piek, J. P. (eds), Motor Control and Sensory-Motor Integration: Issues and Directions. Amsterdam: North-Holland Elsevier Science, 11–36. DOI logoGoogle Scholar
Barrès, V., Simons, A. & Arbib, M. A. (2013). Synthetic event-related potentials: A computational bridge between neurolinguistic models and experiments. Neural Networks, 371, 66–92. DOI logoGoogle Scholar
Belmalih, A., Borra, E., Contini, M., Gerbella, M., Rozzi, S. & Luppino, G. (2009). Multimodal architectonic subdivision of the rostral part (area F5) of the macaque ventral premotor cortex. The Journal of Comparative Neurology, 512(2), 183–217. DOI logoGoogle Scholar
Bonaiuto, J. J. & Arbib, M. A. (2010). Extending the mirror neuron system model, II: what did I just do? A new role for mirror neurons. Biological cybernetics, 102(4), 341–59. DOI logoGoogle Scholar
Byrne, R. W. (2003). Imitation as behaviour parsing. Philos Trans R Soc Lond B Biol Sci, 358(1431), 529–36. DOI logoGoogle Scholar
Byrne, R. W. & Russon, A. E. (1998). Learning by imitation: a hierarchical approach. Behav Brain Sci, 21(5), 667–84; discussion 684–721. DOI logoGoogle Scholar
Cangelosi, A. & Parisi, D. (eds) (2002). Simulating the Evolution of Language. London: Springer. DOI logoGoogle Scholar
Cobas, A. & Arbib, M. (1992). Prey-catching and predator-avoidance in frog and toad: defining the schemas. J Theor Biol, 157(3), 271–304. DOI logoGoogle Scholar
Cooper, R. P. (2016) Schema Theory and Neuropsychology in Arbib, M. A. (ed), From Neuron to Cognition via Computational Neuroscience. Cambridge, MA: The MIT Press.Google Scholar
Corina, D. P., Poizner, H., Bellugi, U., Feinberg, T., Dowd, D. & O’Grady-Batch, L. (1992). Dissociation between linguistic and nonlinguistic gestural systems: a case for compositionality. Brain and Language, 43(3), 414–47. DOI logoGoogle Scholar
Coudé, G. & Ferrari, P. F. (2018). Reflections on the organization of the cortical motor system and its role in the evolution of communication in primates. Interaction Studies, 19(1–2), 38–53. DOI logoGoogle Scholar
Coudé, G., Ferrari, P. F., Rodà, F., Maranesi, M., Borelli, E., Veroni, V., Monti, F., Rozzi, S. & Fogassi, L. (2011). Neurons Controlling Voluntary Vocalization in the Macaque Ventral Premotor Cortex. PLoS One, 6(11), e26822. DOI logoGoogle Scholar
Fagg, A. H. & Arbib, M. A. (1998). Modeling parietal-premotor interactions in primate control of grasping. Neural Netw, 11(7–8), 1277–1303. DOI logoGoogle Scholar
Ferrari, P. F., Gerbella, M., Coudé, G. & Rozzi, S. (2017). Two different mirror neuron networks: The sensorimotor (hand) and limbic (face) pathways. Neuroscience. DOI logoGoogle Scholar
Fogassi, L., Coudé, G. & Ferrari, P. F. (2013). The extended features of mirror neurons and the voluntary control of vocalization in the pathway to language. Language and Cognition, 51, 145–155. DOI logoGoogle Scholar
Halina, M., Rossano, F. & Tomasello, M. (2013). The ontogenetic ritualization of bonobo gestures. Animal cognition, 16(4), 653–666. DOI logoGoogle Scholar
Hecht, E. E., Gutman, D. A., Preuss, T. M., Sanchez, M. M., Parr, L. A. & Rilling, J. K. (2012). Process Versus Product in Social Learning: Comparative Diffusion Tensor Imaging of Neural Systems for Action Execution–Observation Matching in Macaques, Chimpanzees, and Humans. Cerebral Cortex, 23(5), 1014–24. DOI logoGoogle Scholar
Hobaiter, C. & Byrne, R. W. (2011). The gestural repertoire of the wild chimpanzee. Animal cognition, 141, 745–767. DOI logoGoogle Scholar
Jürgens, U. (2002). Neural pathways underlying vocal control. Neuroscience and Biobehavioral Reviews, 26(2), 235–258. DOI logoGoogle Scholar
Maranesi, M., Livi, A. & Bonini, L. (2015). Processing of Own Hand Visual Feedback during Object Grasping in Ventral Premotor Mirror Neurons. The Journal of Neuroscience, 35(34), 11824–11829. DOI logoGoogle Scholar
Marshall, J., Atkinson, J., Smulovitch, E., Thacker, A. & Woll, B. (2004). Aphasia in a user of British Sign Language: Dissociation between sign and gesture. Cognitive Neuropsychology, 211, 537–554. DOI logoGoogle Scholar
Martin, T. A., Keating, J. G., Goodkin, H. P., Bastian, A. J. & Thach, W. T. (1996). Throwing while looking through prisms. II. Specificity and storage of multiple gaze-throw calibrations. Brain, 119, (Pt 4), 1199–211. DOI logoGoogle Scholar
Oztop, E. & Arbib, M. A. (2002). Schema design and implementation of the grasp-related mirror neuron system. Biol Cybern, 87(2), 116–40. DOI logoGoogle Scholar
Oztop, E., Kawato, M. & Arbib, M. (2006). Mirror neurons and imitation: a computationally guided review. Neural Netw, 19(3), 254–71. DOI logoGoogle Scholar
Oztop, E., Kawato, M. & Arbib, M. A. (2013). Mirror neurons: Functions, mechanisms and models. Neuroscience Letters, 5401, 43–55. DOI logoGoogle Scholar
Poizner, H., Klima, E. S. & Bellugi, U. (1987). What the hands reveal about the brain. Cambridge, MA: MIT Press.Google Scholar
Rizzolatti, G., Camarda, R., Fogassi, L., Gentilucci, M., Luppino, G. & Matelli, M. (1988). Functional organization of inferior area 6 in the macaque monkey. II. Area F5 and the control of distal movements. Exp. Brain Res., 711, 491–507. DOI logoGoogle Scholar
Russon, A. (2018). Pantomime and imitation in great apes: Implications for reconstructing the evolution of language. Interaction studies, 19(1–2), 200–215. DOI logoGoogle Scholar
Taira, M., Mine, S., Georgopoulos, A. P., Murata, A. & Sakata, H. (1990). Parietal cortex neurons of the monkey related to the visual guidance of hand movement. Experimental Brain Research, 831, 29–36. DOI logoGoogle Scholar
Tomasello, M. & Call, J. (1997). Primate Cognition. New York: Oxford University Press.Google Scholar
Cited by (6)

Cited by six other publications

Arbib, Michael A., Francisco Aboitiz, Judith M. Burkart, Michael C. Corballis, Gino Coudé, Erin Hecht, Katja Liebal, Masako Myowa-Yamakoshi, James Pustejovsky, Shelby S. Putt, Federico Rossano, Anne E. Russon, P. Thomas Schoenemann, Uwe Seifert, Katerina Semendeferi, Chris Sinha, Dietrich Stout, Virginia Volterra, Sławomir Wacewicz & Benjamin Wilson
2020. The comparative neuroprimatology 2018 (CNP-2018) road map for research on How the Brain Got Language. In How the Brain Got Language – Towards a New Road Map [Benjamins Current Topics, 112],  pp. 370 ff. DOI logo
Anderlini, Deanna, Guy Wallis & Welber Marinovic
2019. Language as a Predictor of Motor Recovery: The Case for a More Global Approach to Stroke Rehabilitation. Neurorehabilitation and Neural Repair 33:3  pp. 167 ff. DOI logo
Arbib, Michael A.
2018. Computational challenges of evolving the language-ready brain. Interaction Studies. Social Behaviour and Communication in Biological and Artificial Systems 19:1-2  pp. 22 ff. DOI logo
Arbib, Michael A.
2020. Computational challenges of evolving the language-ready brain. In How the Brain Got Language – Towards a New Road Map [Benjamins Current Topics, 112],  pp. 22 ff. DOI logo
Arbib, Michael A., Francisco Aboitiz, Judith M. Burkart, Michael Corballis, Gino Coudé, Erin Hecht, Katja Liebal, Masako Myowa-Yamakoshi, James Pustejovsky, Shelby Putt, Federico Rossano, Anne E. Russon, P. Thomas Schoenemann, Uwe Seifert, Katerina Semendeferi, Chris Sinha, Dietrich Stout, Virginia Volterra, Sławomir Wacewicz & Benjamin Wilson
2018. The comparative neuroprimatology 2018 (CNP-2018) road map for research on How the Brain Got Language . Interaction Studies. Social Behaviour and Communication in Biological and Artificial Systems 19:1-2  pp. 370 ff. DOI logo
Gong, Tao, Lan Shuai & Yicheng Wu
2018. Extending research on language foundations and evolution. Physics of Life Reviews 26-27  pp. 184 ff. DOI logo

This list is based on CrossRef data as of 12 september 2024. Please note that it may not be complete. Sources presented here have been supplied by the respective publishers. Any errors therein should be reported to them.