Dr Stig Walsh is Senior Curator of Vertebrate Palaeobiology.
Dr Stig Walsh came to National Museums Scotland from the Natural History Museum (London) at the start of 2009. Dr Walsh’s research uses X-ray micro computed-tomographic (µCT) techniques to investigate the evolution of the vertebrate brain and senses, a branch of palaeobiology known as ‘palaeoneurology’.
Nerve and sensory structures rarely fossilise, so palaeoneurology must rely on information recorded by the bone associated with the structures in life. This evidence, such as the relative size of parts of the brain cavity, the diameter of nerve canals and the form of other bony anatomical structures such as the inner ear, can provide insight into the behaviour and sensory abilities of extinct animals.
Current approaches in palaeoneurology apply numerical modelling to the neurosensory structures of living species – in which behaviour and sensory abilities are known – to interpret the same structures preserved in fossils. Such research has tended to concentrate on the evolution of specific sensory modalities. For instance, the evolution of balance in a particular group is normally investigated by analysing the form of the inner ear in isolation. However, vertebrate balance is controlled via a dynamic system that integrates vestibular, visual and proprioceptive signals through plastic processing in the cerebellum.
Dr Walsh’s research has now moved towards finding approaches that can integrate multiple lines of evidence in order to understand how the vertebrate brain and senses have evolved over time.
Ten selected publications
- Walsh, S. A. & Knoll, F. 2018. The Evolution of Avian Intelligence and Sensory Capabilities: the Fossil Evidence. pp.59-69. In: Bruner, E., Ogihara, N. & Tanabe, H. C. (eds). Digital Endocasts: from skulls to brains. Replacement of Neanderthals by Modern Humans Series. Springer, Tokyo. https://doi.org/10.1007/978-4-431-56582-6_5
- Benson, R. B. J., Starmer-Jones, E., Close, R. A. & Walsh, S. A. 2017. Comparative analysis of vestibular ecomorphology in birds. Journal of Anatomy 231: 990-1018. https://doi.org/10.1111/joa.12726
- Walsh, S. A., Milner, A.C. and Bourdon, E. 2016. A reappraisal of Cerebavis cenomanica (Aves, Ornithurae), from Melovatka, Russia. Journal of Anatomy 229: 215-227. https://doi.org/10.1111/joa.12406.
- Walsh, S. A., Zhe-Xi, L. & Barrett, P. 2014. Modern imaging techniques as a window to prehistoric auditory worlds. pp. 227-261 In: Köppl, C. & Manley, G. (eds). Insights from Comparative Hearing Research. Springer Handbook of Auditory Research 49, Springer Verlag.
- Walsh, S. A., Iwaniuk, A. N., Knoll M. A., Bourdon, E., Barrett, P. M., Milner, A. C., Nudds, R., Abel, R. L. & Dello Sterpaio, P. 2013. Avian cerebellar floccular fossa size is not a proxy for flying ability in birds. PLoS ONE 8 (6): e67176. https://doi.org/10.1371/journal.pone.0067176.
- Walsh, S. A. & Milner, A. C. 2011. Evolution of the avian brain and senses. pp. 282-305 In Dyke, G. & Kaiser, G. (eds) Living dinosaurs: the evolutionary history of modern birds. 422 p.
- Walsh, S. A. & Knoll, M. A. 2011. Directions in palaeoneurology. Special Papers in Palaeontology 86: 263-279.
- Walsh, S. A. & Milner, A. C. 2011. Halcyornis toliapicus (Aves: Lower Eocene, England) indicates advanced neuromorphology in Mesozoic Neornithes. Journal of Systematic Palaeontology 9 (1): 173-181.
- Walsh, S. A., Barrett, P. M., Milner, A. C., Manley, G., & Witmer, L. M. 2009. Inner ear anatomy is a proxy for deducing auditory capability and behaviour in reptiles and birds. Proceedings of the Royal Society B 276: 1355-1360.
- Milner, A. C. & Walsh, S. A. 2009. Avian brain evolution: new data from Palaeogene birds (Lower Eocene) from England. Zoological Journal of the Linnean Society 155: 198-219.
For further publications see: National Museums Scotland Research Repository.