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The Mechanosensory Lateral Line System of the Hypogean form of Astyanax Fasciatus

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Abstract

The mechanosensory lateral line is a distributed, hair-cell based system which detects the water flow regime at the surface of the fish. Superficial neuromasts densely scattered over the surface of some cave fish detect the pattern of flow over the surface of the body and are important in rheotactic behaviors and perhaps in the localization of small vibrating sources. Canal neuromasts are very likely also involved in the detection of small planktonic prey, but seem also to play an essential role in replacing vision as the major sense by which blind cave-fish perceive their surroundings. The flow-field that exists around a gliding fish is perturbed by objects in the immediate vicinity, these perturbations are detected by the lateral line system. In this way the fish can build up a ‘picture’ of its environment, a process that has been called active hydrodynamic imaging. None of the lateral line behaviors exhibited by blind cave fish are necessarily exclusive to these species, but there is some evidence that their lateral line capabilities are enhanced with respect to their sighted relatives.

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Montgomery, J.C., Coombs, S. & Baker, C.F. The Mechanosensory Lateral Line System of the Hypogean form of Astyanax Fasciatus. Environmental Biology of Fishes 62, 87–96 (2001). https://doi.org/10.1023/A:1011873111454

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