Ayala GF, Mexicano G

Idioma: Español
Referencias bibliográficas: 49
Paginas: 37-45
Archivo PDF: 611.35 Kb.

RESUMEN

El sueño es un proceso fundamental para los animales, el cual puede ser modulado tanto por factores endógenos comoexógenos. A pesar de la clara importancia del dormir y de la gran cantidad de investigaciones que se llevan a cabo, todavía no se conoce con precisión el papel fundamental de este fenómeno. Tradicionalmente, el estudio comparativo del sueño ha tomado como referencia la actividad cerebral de los mamíferos, lo que ha dado origen a serias controversias acerca de su existencia en vertebrados exotermos (reptiles, anfibios y peces) y con mayor razón en invertebrados. Sin embargo, el análisis conductual ha permitido mostrar la existencia de este proceso no sólo a lo largo de todos los vertebrados, sino también de los invertebrados. Además, la implementación de técnicas moleculares ha permitido poner en evidencia que el proceso de dormir ya se encuentra presente desde los invertebrados, lo que pudiera sugerir que se trata de un fenómeno universal inherente a los seres vivos.

REFERENCIAS (EN ESTE ARTÍCULO)

1. Popoca-Gutiérrez J, García-Gomar ML, Osorio- Rodríguez O. Hipótesis de las funciones del sueño. En: Ayala-Guerrero F, Mexicano G, Guevara U, editores. Trastornos del sueño. Corinter: México; 2007. p. 263-80.

2. Raizen DM, y col. Lethargus is a Caenorhabditis elegans sleep-like state. Nature 2008; 451: 569- 72.

3. Huber R y col. Sleep homeostasis in Drosophila melanogaster. Sleep 2005; 27: 628-39.

4. Tobler I, Neuner-Jehle M. 24-h variation of vigilance in the cockroach Blaberus giganteus. J Sleep Res 1992; 1: 231-39.

5. Ramón F, Hernández-Falcón J, Nguyen B, Bullock TH. Slow wave sleep in crayfish. Proc Natl Acad Sci USA 2004; 101: 11857-61.

6. Ayala-Guerrero, F. y Mexicano, G. Filogenese Do Sono: Avancos Recentes. En: Sono. Estudo Abrangente. Reimao R, editor. Livraria Atheneu Editora, Sao Paulo Brasil; 1996, p. 99-112.

7. Siegel JM, y col. Monotremes and the evolution of rapid eye movement sleep. Phil Trans R Soc Lond B 1998; 353: 1147-57.

8. Medina L, Reiner A. Do birds possess homologues of mammalian primary, visual, somatosensory and motor corticies? Trends Neurosci 2000; 2: 1-12.

9. Ebner FF. The forebrain of reptiles and mammals. En: Masterton RB, y col., editores. Evolution of brain and behavior in vertebrates. New York: John Wiley and sons; 1976. p. 147-67.

10. Emde RN, Metcalf DR. An electroencephalographic study of behavioral rapid eye movement states in the human new born. J Nerv Ment Dis 1970; 150: 376-86.

11. Mukhametov LM. Sleep in marine mammals. Exp Brain Res 1984; 8: 227-36.

12. Garau C, Aparicio S, Rial RV, Esteban S. La evolución del sueño: las aves en la encrucijada entre mamíferos y reptiles. Rev Neurol 2005; 40: 423-30.

13. Yuan Q, Joiner WJ, Sehgal A. A sleep-promoting role for the Drosophila serotonin receptor 1A. Curr Biol 2006; 16: 1051-62.

14. Graves, LA y col. Genetic evidence for a role of CREB in sustained cortical arousal. J Neurophysiol 2003; 90: 1152-59.

15. Walker JM, Berger RJ, Scott TD. Absence of electrophysiological signs of sleep in the tortoise Testudo denticulata. Sleep Res 1973; 2: 88.

16. Jouvet M. Recherches sur les structures nerveuses et les mécanismes responsables des différentes phases du sommeil physiologique. Arch Ital Biol 1962; 100: 125-206.

17. Flanigan WF, Knight CP, Hartse KM, Rechtschaffen A. Sleep and wakefulness in chelonian reptiles. 1. The box turtle, Terrapene carolina. Arch Ital Biol 1974; 112: 227-52.

18. Frank MG. Phylogeny and evolution of rapid eye movement (REM) sleep. En: Mallick BN, Inoue S, editors. Rapid Eye Movement Sleep. New Delhi, India: Narosa Publishing House; 1999. p. 17-38.

19. Karmanova G, Churnosov EV. Electrophysiological investigation of natural sleep and waking in turtles and hens. J Evol Biochem Physiol 1972; 8: 47-53.

20. Ayala-Guerrero F. Sleep in the tortoise Kinosternon sp. Experientia 1987; 43: 296-98.

21. Flanigan WF, Wilcox RH, Rechtschaffen A. The EEG and behavioral continuum of the crocodilian, Caiman sclerops. Electroencephalogr ClinNeurophysiol 1973; 34:521-38.

22. Ayala-Guerrero F, Mexicano G. Topographical distribution of the locus coeruleus and raphe nuclei in the lizard Ctenosaura pectinata: functional implications on sleep. Comp Biochem Physiol A Mol Integr Physiol 2008; 149: 137-41.

23. Tauber ES, Rojas-Ramírez JA, Hernández-Peón R. Electrophysio1ogica1 and behavioral correlates of wakefulness and sleep in the lizard Ctenosaura pectinata. Electroencephalogr Clin Neurophysiol 1968; 24: 424-33.

24. Ayala-Guerrero F, Huitrón-Reséndiz S. Sleep patterns in the lizard Ctenosaura pectinata. Physiol Behav 1991; 49: 1305-07

25. Huitrón-Reséndiz S, Mexicano G, Ayala-Guerrero F. Effect of atropine sulphate on sleep of the guanid lizard Ctenosaura similis. Proc West Pharmacol Soc 1992; 35: 157-60.

26. Flanigan WF. Sleep and wakefulness in iguanid lizards, Ctenosaura pectinata and Iguana iguana. Brain Behav Evol 1973; 8: 401-36.

27. Liknowski P, Kerkhofs M, Hauspie R, Mendlewicz J. A genetic study of sleep in twins living apart.Sleep Res 1991; 20A: 41.

28. Butler AB. Cytoarchitectonic and connectional organization of the lacertilian telencephalon with comments on vertebrates forebrain evolution. En: Ebbesson SOE, editor. Comparative Neurology of the Telencephalon. New York: Plenum Press; 1980. p. 297-25

29. Finlay BL, Innocenti G, Scheich H. The neocortex, Ontogeny and phylogeny. New York: Plenum Press. 1991.

30. Lindsley B, Schreiner LH, Knowles WB, Magoun HW. Behavioral and EEG changes following chronic brain stem lesions in the cat. Electroencephalogr Clin Neurophysiol 1950; 2: 483-98.

31. Lohman AH, Smeets WJ. The dorsal ventricularridge and cortex of reptiles in historical and phylogenetic perspective. En: Finlay BL, Innocenti G, Scheich H, editors. The Neocortex: Ontogeny and phylogeny. New York: Plenum Press. 1991. p. 59-74.

32. Astic L, Sastre JP, Brandon AM. Etude polygraphique des états de vigilance chez le foetus du cobaye. Physiol Behav 1973; 11: 647-54.

33. Hartse KM, Rechtschaffen A. The effect of amphetamine, nembutal, alpha-methyl-tyrosine, and parachlorophenylalanine on sleep-related spike activity of the tortoise, Geochelone carbonaria, and on the cat ventral hippocampus spike. Brain Behav Evol 1982; 21: 199-22.

34. Vasilescu E. Sleep and wakefulness in the tortoise (Emys orbicularis). Rev Roum Biol Ser Zool 1970; 15: 177-79.

35. Ruckebusch Y, Barbey P, Guillemont P. Les étates de sommeil chez le cheval (Equus caballus). C R Séances Soc Biol (Paris) 1970; 164: 658-66.

36. Allison T, Van Twyver H, Goff WR. Electrophysiological studies of the echidna, Tachyglossus aculeatus. 1. Waking and sleeping. Arch Ital Biol 1972; 110: 145-84.

37. Borbely A. Effects of light on sleep and activity rhythms. Prog Neurobiol 1978; 10: 1-31.

38. Benington H, Heller C. Implications of sleep deprivation experiments for our understanding of sleep homeostasis. Sleep 1999; 22: 1033-37.

39. Dement WC. The effect of dream deprivation. Science 1960; 131: 1705-7.

40. Tauber ES, Weitzman ED, Korey SR. Eye movements during behavioral inactivity in certain Bermuda reef fish. Behav Biol 1969; 3:131-35.

41. Lucas E, Sterman MB, Mc Ginty DJ. The salamander EEG: A model of primitive sleep and wakefulness. Psychophysiology 1969; 6: 230.

42. Hobson AJ. Electrographic correlates of behavior in the frog with special reference to sleep. Electroencephalogr Clin Neurophysiol 1967; 22:113-21.

43. Hobson AJ, Goin OB, Goin CJ. Electrographic correlates of behavior en tree frogs. Nature (London). 1968; 220: 386-7.

44. Voronov IB, y col. The effect of arecoline on thestructure of rest and active wakefulness in the brown bull-head toad. Zh Evol Biokhim Fiziol 1977; 13: 525-8.

45. Popova DI, Churnosov EV. Diurnal Cycles of waking and rest in the frog Rana temporaria. J Evol Biochem Physiol 1976; 12: 186-8.

46. Shappiro CM, y Helpburn HR. Sleep in the schooling fish, Tilapia mossambica. Physiol Behav 1976; 16: 613-15.

47. Mussen TD, Peeke HVS. Nocturnal feeding in the marine threespine stickleback (Gasterosteus aculeatus): modulation by chemical stimulation. Behaviour 2001; 138: 857-71.

48. Reebs SG. Plasticity of diel and circadian activity rhythms in fishes. Fish Biology and fisheries. 2002; 12: 349-71.

49. Zhadanova IV, Reebs SG. Circadian Rhythms. En: Sloman KA, Wilson RW, Balshine S, editores. Behaviour and Physiology of fish. San Diego: Elsevier; 2006. p. 197-38.