Auditory peripheral tuning: evidence for a simple resonance phenomenon in the lizard Tiliqua
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Cited by (56)
Suppression tuning of spontaneous otoacoustic emissions in the barn owl (Tyto alba)
2020, Hearing ResearchCitation Excerpt :Note that these secondary minima were also seen in neural tuning curves in the bobtail and other lizard species (e.g, Manley, et al., 1988). However, the side lobes of STCs and neural tuning curves in lizards cannot be caused by standing waves, as suggested for humans, as there are no traveling waves on the basilar membrane (e.g., Manley, et al., 1988). The inconsistent presence of side lobes in suppression tuning curves and neural tuning curves suggests different inner ear tuning mechanisms in mammals, birds and lizards.
Experiments in comparative hearing: Georg von Békésy and beyond
2012, Hearing ResearchCitation Excerpt :Measurements of basilar-membrane tuning in two quite different species with very different BM lengths, a short (0.4 mm, alligator lizard, Peake and Ling, 1980) and a long (2 mm, bobtail skink, Manley et al., 1988) BM indicates that each location along the BM length shows the same tuning. This tuning is equivalent to that of the middle ear (Manley et al., 1988). Thus the BM itself shows no difference in tuning selectivity at different locations on the BM and its selectivity is poor (Fig. 3).
The development and evolution of a tonotopic organization in the cochlea
2011, Hearing ResearchTectorial membrane morphological variation: Effects upon stimulus frequency otoacoustic emissions
2010, Biophysical JournalCitation Excerpt :Lizards exhibit robust emissions (13,21–24), in addition to wide variations in inner ear structure (25). As put forth by Manley, the lizard inner ear represents “a playground of evolution” (26) and differs significantly from mammals in that lizard ears lack a traveling wave that propagates along the basilar membrane (27,28). Lizards have been described as having two populations of different hair cell types (29):