Cardiovascular dynamics inCrocodylus porosus breathing air and during voluntary aerobic dives (original) (raw)

Summary

Pressure records from the heart and out-flow vessels of the heart of_Crocodylus porosus_ resolve previously conflicting results, showing that left aortic filling via the foramen of Panizza may occur during both cardiac diastole and systole. Filling of the left aorta during diastole, identified by the asynchrony and comparative shape of pressure events in the left and right aortae, is reconciled more easily with the anatomy, which suggests that the foramen would be occluded by opening of the pocket valves at the base of the right aorta during systole. Filling during systole, indicated when pressure traces in the left and right aortae could be superimposed, was associated with lower systemic pressures, which may occur at the end of a voluntary aerobic dive or can be induced by lowering water temperature or during a long forced dive. To explain this flexibility, we propose that the foramen of Panizza is of variable calibre. The presence of a ‘right-left’ shunt, in which increased right ventricular pressure leads to blood being diverted from the lungs and exiting the right ventricle via the left aorta, was found to be a frequent though not obligate correlate of voluntary aerobic dives. This contrasts with the previous concept of the shunt as a correlate of diving bradycardia. The magnitude of the shunt is difficult to assess but is likely to be relatively small. This information has allowed some new insights into the functional significance of the complex anatomy of the crocodilian heart and major blood vessels.

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Abbreviations

bpm :

beats per minute

LAo :

left aorta (aortic)

LV :

left ventricle (ventricular)

PA:

pulmonary artery

RAo :

right aorta (aortic)

RV :

right ventricle (ventricular)

SC :

subclavian artery

References

• Ackerman RA, White FN (1979) Cyclic carbon dioxide exchange in the turtle,Pseudemys scripta. Physiol Zool 52:378–389
  Google Scholar
• Anderson HT (1961) Physiological adjustments to prolonged diving in the American alligator. Acta Physiol Scand 53:23–45
  Google Scholar
• Burggren WW (1982) Pulmonary blood plasma filtration in reptiles: a ‘wet’ vertebrate lung? Science 215:77–78
  Google Scholar
• Burggren WW (1985) Hemodynamics and regulation of central cardiovascular shunts in reptiles. In: Johansen K, Burggren WW (eds) Cardiovascular Shunts: Phylogenetic, Ontogenetic and Clinical Aspects. Alfred Benzon Symposium 21. Munksgaard, Copenhagen, pp 121–142
  Google Scholar
• Fritsch G (1869) Zur vergleichenden Anatomie des Amphibien-herzens. Arch Anat Physiol 6:654–758
  Google Scholar
• Gaunt AS, Gans C (1969) Diving bradycardia and withdrawal bradycardia in_Caiman crocodilus_. Nature 223:207–208
  Google Scholar
• Goodrich ES (1919) Note on the reptilian heart. J Anat 53:298–304
  Google Scholar
• Greenfield LJ, Morrow AG (1961) The cardiovascular hemodynamics of Crocodilia. J Surg Res 1:97–103
  Google Scholar
• Greil A (1903) Beiträge zur vergleichenden Anatomie und Entwicklungsgeschichte des Herzens und des Truncus arteriosus der Wirbeltiere. Morphol Jahrb 31:123–310
  Google Scholar
• Grigg GC, Cairncross M (1980) Respiratory properties of the blood of_Crocodylus porosus_. Respir Physiol 41:367–380
  Google Scholar
• Grigg GC, Gruca M (1979) Possible adaptive significance of low red cell organic phosphates in crocodiles. J Exp Zool 209:161–169
  Google Scholar
• Grigg GC, Farwell WD, Kinney JL, Harlow P, Taplin LE, Johansen Kjell, Johansen Kjetil (1985) Diving and amphibious behaviour in a free-living_Crocodylus porosus_. Aust Zool 21:599–605
  Google Scholar
• Johansen K (1979) Cardiovascular support of metabolic functions in vertebrates. In: Wood SC, Lenfant C (eds) Evolution of respiratory processes — a comparative approach. Marcel Dekker, New York, pp 107–192
  Google Scholar
• Johansen K (1985) A phylogenetic view of cardiovascular shunts. In: Johansen K, Burggren WW (eds) Cardiovascular shunts: phylogenetic, ontogenetic and clinical aspects. Alfred Benzon Symposium 21. Munksgaard, Copenhagen, pp 17–37
  Google Scholar
• Johansen K, Burggren WW (1980) Cardiovascular function in lower vertebrates. In: Bourne GH (ed) Hearts and heart-like organs. Academic Press, New York, pp 61–117
  Google Scholar
• Khalil F, Zaki K (1964) Distribution of blood in the ventricle and aortic arches in reptilia. Z Vergl Physiol 48:663–689
  Google Scholar
• Messel H, Vorlicek GC, Wells AG, Green WJ (1981) Surveys of tidal river systems in the Northern Territory of Australia and their crocodile populations. Monogr 1. Pergamon Press, Sydney
  Google Scholar
• Panizza B (1833) Sulla structura del cuore e sulla circolazione del sangue del_Crocodilus lucius_. Biblioth Ital LXX 87:87–91
  Google Scholar
• Sabatier A (1873) Etudier sur le coeur et la circulation centrale dans la série des vertebrés. Ann Sci Nat Zool, Sér V, 18:1–89
  Google Scholar
• Smith EN, Allison RD, Crowder WE (1974) Bradycardia in a free ranging American alligator. Copeia 1974:770–772
  Google Scholar
• Tazawa H, Johansen K (1987) Comparative model analysis of central shunts in vertebrate cardiovascular systems. Comp Biochem Physiol (in press)
• Webb GJW (1979) Comparative cardiac anatomy of the reptilia. III The heart of crocodilians and an hypothesis on the completion of the interventricular septum of crocodilians and birds. J Morphol 161:221–240
  Google Scholar
• White FN (1956) Circulation in the reptilian heart (Caiman sclerops). Anat Rec 125:417–432
  Google Scholar
• White FN (1968) Functional anatomy of the heart of reptiles. Am Zool 8:211–219
  Google Scholar
• White FN (1969) Redistribution of cardiac output in the diving alligator. Copeia 1969:567–570
  Google Scholar
• White FN (1970) Central vascular shunts and their control in reptiles. Fed Proc 29:1149–1153
  Google Scholar
• White FN (1976) Circulation. In: Gans C (ed) Biology of the Reptilia, vol 5, Physiology A. Academic Press, London, pp 275–334
  Google Scholar
• White FN (1985) Role of intracardiac shunts in pulmonary gas exchange in chelonian reptiles. In: Johansen K, Burggren WW (eds) Cardiovascular shunts: phylogenetic, ontogenetic and clinical aspects. Alfred Benzon Symposium 21. Munksgaard, Copenhagen, pp 296–309
  Google Scholar
• Wood SC (1984) Cardiovascular shunts and oxygen transport in lower vertebrates. Am J Physiol 247:R3-R14
  Google Scholar
• Wright J (1985) Diving and exercise physiology in the Estuarine Crocodile,Crocodylus porosus. PhD thesis, The University of Sydney, Australia
  Google Scholar

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Authors and Affiliations

1. Zoology A.08, The University of Sydney, 2006, NSW, Australia
   Gordon C. Grigg
2. Department of Zoophysiology, University of Aarhus, DK-8000, Aarhus, Denmark
   Kjell Johansen

Authors

1. Gordon C. Grigg
2. Kjell Johansen

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Deceased

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Grigg, G.C., Johansen, K. Cardiovascular dynamics in_Crocodylus porosus_ breathing air and during voluntary aerobic dives.J Comp Physiol B 157, 381–392 (1987). https://doi.org/10.1007/BF00693365

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• Accepted: 01 December 1986
• Issue date: May 1987
• DOI: https://doi.org/10.1007/BF00693365

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