Hostname: page-component-586b7cd67f-rdxmf Total loading time: 0 Render date: 2024-11-28T03:21:20.888Z Has data issue: false hasContentIssue false
  • English
  • Français

The Decapod Crustacean Circulatory System: A Case That Is neither Open nor Closed

Published online by Cambridge University Press:  28 January 2005

Iain J. McGaw
Iain J. McGaw
Affiliation:
Department of Biological Sciences, University of Nevada, Las Vegas, NV 89154, USA Bamfield Marine Sciences Centre, Bamfield, British Columbia V0R 1B0, Canada
Get access

Abstract

Historically, the decapod crustacean circulatory system has been classed as open. However, recent work on the blue crab, Callinectes sapidus, suggests the circulatory system may be more complex than previously described. Corrosion casting techniques were refined and used to map the circulatory system of a variety of crab species (order: Decapoda; family: Cancridae) to determine if the complexity observed in the blue crab was present in other species. Seven arteries arose from the single chambered heart. The anterior aorta, the paired anterolateral arteries, and the paired hepatic arteries exited from the anterior aspect of the heart. The small-diameter posterior aorta exited posteriorly from the heart. Exiting from the ventral surface of the heart, the sternal artery branched to supply the legs and mouthparts of the crab. These arteries were more complex than previously described, with arterioles perfusing all areas of the body. The arterioles split into fine capillary-like vessels. Most of these capillaries were blind ending. However, in several areas (antennal gland, supraesophageal ganglion) complete capillary beds were present. After passing through the capillary-like vessels, blood drained into a series of sinuses. However, rather than being arbitrary spaces as previously described, scanning electron micrographs showed the sinuses to be distinct units. Most of the sinuses formed a series of flattened membrane-bound lacunae. This complexity may qualify the decapod crustacean circulatory system as one that is “partially closed” rather than open.

Keywords

arterycrabcirculationcardiovascularheartsinuscorrosion castingscanning electron microscopy
Type
BIOLOGICAL APPLICATIONS
Information
Microscopy and Microanalysis , Volume 11 , Issue 1 , February 2005 , pp. 18 - 36
Copyright
© 2005 Microscopy Society of America

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Abbott, N.J. (1971). The organization of the cerebral ganglion in the shore crab Carcinus maenas. II. The relation of intracerebral blood vessels to other brain elements. Z Zellforsch 120, 401419.Google Scholar
Airriess, C.N. (1994). The control of the cardiovascular system of Cancer magister. Ph.D. thesis. University of Calgary.
Airriess, C.N. & McMahon, B.R. (1994). Cardiovascular adaptations enhance tolerance of environmental hypoxia in the crab Cancer magister. J Exp Biol 190, 2341.Google Scholar
Airriess, C.N. & McMahon, B.R. (1996). Short-term emersion affects cardiac function and regional hemolymph distribution in the crab Cancer magister. J Exp Biol 199, 110.Google Scholar
Alexandrowicz, J.S. (1932). The innervation of the heart of the Crustacea. I. Decapoda. Quart J Micro Sci 75, 181249.Google Scholar
Baumann, H. (1921). Das Gefassystem von Astacus fluviatilis (Potamobius astacus). Z Wiss Zool 118, 246342.Google Scholar
Bouvier, E.L. (1891). Recherches anatomiques sur le systeme arterial des Crustaces Decapodes. Ann Sci Nat Zool Biol Anim II Ser 9, 197282.Google Scholar
Brody, M.S. & Perkins, E.B. (1930). The arterial system of Palaemonetes. J Morphol 50, 127142.Google Scholar
Burnett, B.R. (1984). Striated muscle in the wall of the dorsal abdominal artery of the California lobster Panulirus interruptus. J Crust Biol 4, 560566.Google Scholar
Claus, C. (1884). Zur kenntnis der kreislauforgane der Schizopoden und Decapoden. Ar Zool Inst Univ Wien U Zool Sta Triest 5, 271318.Google Scholar
Davidson, G.M. & Taylor, H.H. (1995). Ventilatory and vascular routes in a sand burying swimming crab, Ovalipes catharus (White, 1843) (Brachyura, Portunidae). J Crust Biol 15, 605624.Google Scholar
DeWachter, B. & McMahon, B.R. (1996). Hemolymph flow distribution, cardiac performance and ventilation during moderate walking activity in Cancer magister (Dana) (Decapoda, Crustacea). J Exp Biol 199, 627633.Google Scholar
Factor, J.R. & Naar, M. (1990). The digestive system of the lobster, Homarus americanus: II. Terminal hepatic arterioles of the digestive gland. J Morphol 206, 283291.Google Scholar
Farrelly, C. & Greenaway, P. (1987). The morphology and vasculature of the lungs and gills of the soldier crab, Mictyris longicarpus. J Morphol 193, 285304.Google Scholar
Govind, C.K. & Guchardi, J. (1986). Vascularization of a lobster muscle. J Morphol 188, 327333.Google Scholar
Greenaway, P. & Farrelly, C. (1990). Vasculature of the gas exchange organs in air breathing brachyurans. Physiol Zool 63, 117139.Google Scholar
Greenaway, P., Morris, S., McMahon, B.R., Farrelly, C.A., & Gallagher, K.L. (1996). Air breathing by the purple shore crab Hemigrapsus nudus (Dana). I. Morphology, behaviour and respiratory gas exchange. Physiol Zool 69, 785805.Google Scholar
Haeckel, E. (1857). Uber die Gewebe des Flusskrebses. Arch Anat Physiol U Wiss Med pp. 469568.Google Scholar
Hossler, F. & Douglas, J.E. (2001). Vascular corrosion casting: Review of advantages and limitations in the application of some simple quantitative methods. Microsc Microanal 7, 253264.Google Scholar
Hunter, K.C. & Rudy, P.P. (1975). Osmotic and ionic regulation in the Dungeness crab Cancer magister (Dana). Comp Biochem Physiol 51A, 439447.Google Scholar
Icely, J.D. & Nott, J.A. (1992). Digestion and absorption: Digestive system and associated organs. In Microscopic Anatomy of Invertebrates. Decapod Crustaceans, Harrison, F.W. (Ed.), vol. 10, pp. 147201. New York: Wiley Liss.
Johnson, P.T. (1980). Histology of the Blue Crab. A Model for the Decapoda. New York: Praeger Scientific.
Kratky, R.G., Zeindler, C.M., Lo, D.K.G., & Roach, M.R. (1989). Quantitative measurement from vascular corrosion casts. Scanning Micros 3, 937943.Google Scholar
Martin, G.G., Hose, J.E., & Corzine, C.J. (1989). Morphological comparisons of the major arteries in the ridgeback prawn, Sicyonia ingentis. J Morphol 200, 175183.Google Scholar
Maynard, D.M. (1960). Circulation and heart function. In The physiology of Crustacea, Waterman, T.H. (Ed.), vol. 1, pp. 161225. New York: Academic Press.
McGaw, I.J. (2004). Ventilatory and cardiovascular modulation associated with burying behavior in two sympatric crab species, Cancer magister and Cancer productus. (Submitted)Google Scholar
McGaw, I.J., Airriess, C.N., & McMahon, B.R. (1994a). Patterns of hemolymph flow variation in decapod crustaceans. Mar Biol 121, 5360.Google Scholar
McGaw, I.J., Airriess, C.N., & McMahon, B.R. (1994b). Peptidergic modulation of cardiovascular dynamics in the Dungeness crab Cancer magister. J Comp Physiol B 164, 103111.Google Scholar
McGaw, I.J. & McMahon, B.R. (1995). The FMRFamide-related peptides F1 and F2 alter hemolymph distribution and cardiac output in the crab Cancer magister. Biol Bull 188, 186196.Google Scholar
McGaw, I.J. & McMahon, B.R. (1998). Endogenous rhythms of hemolymph flow and cardiac performance in the crab Cancer magister. J Exp Mar Biol Ecol 224, 127142.Google Scholar
McGaw, I.J. & McMahon, B.R. (1999). Actions of putative cardioinhibitory substances on the in vivo decapod crustacean cardiovascular system. J Crust Biol 19, 435449.Google Scholar
McGaw, I.J. & Reiber, C.L. (2002). Cardiovascular system of the blue crab Callinectes sapidus. J Morphol 251, 121.Google Scholar
McLaughlin, P.A. (1983). Internal Anatomy. Internal Anatomy and Physiological Regulation. Vol 5. Biology of Crustacea. L.H. Mantel & D.E. Bliss (Eds.), pp. 153. New York: Academic Press.
McMahon, B.R. (1999). Intrinsic and extrinsic influences on cardiac rhythms in crustaceans. Comp Biochem Physiol 124A, 539547.Google Scholar
McMahon, B.R. & Burnett, L.E. (1990). The crustacean open circulatory system: A reexamination. Physiol Zool 63, 3571.Google Scholar
McMahon, B.R., Wilkens, J.L., & Smith, P.J.S. (1997). Invertebrate circulatory systems. In Handbook of Physiology, W.H. Dantzler, (Ed.), pp. 9311008. New York: American Physiological Society, Oxford University Press.
Miyawaki, M. & Ukeshima, A. (1967). On the ultrastructure of the antennal gland epithelium of the crayfish Procambarus clarkii. Kumamoto J Sci Ser B 6, 111.Google Scholar
Pearson, J. (1908). Cancer. In Liverpool Marine Biology Committee Memoirs XVI, pp. 1209.
Peterson, D.R. & Loizzi, R.F. (1974). Ultrastructure of the crayfish kidney—Coelomosac, labyrinth, nephridial canal. J Morphol 142, 241264.Google Scholar
Pyle, R. & Cronin, E. (1950). The general anatomy of the blue crab Callinectes sapidus. State of Maryland, Board of Natural Resources. Publication No. 87.
Reiber, C.L., McMahon, B.R., & Burggren, W.W. (1997). Cardiovascular functions in two Macruran decapod crustaceans (Procambarus clarkii and Homarus americanus) during periods of inactivity, tail flexion and cardiorespiratory pauses. J Exp Biol 200, 11031113.Google Scholar
Sandeman, D.C. (1967). The vascular circulation in the brain, optic lobes and thoracic ganglion of the crab Carcinus. Proc Roy Soc Lond B 168, 8290.Google Scholar
Schmidt, M. (1989). The hair peg organs of the shore crab Carcinus maenas (Crustacea: Decapoda): Ultrastructure and functional properties of sensilla sensitive to changes in seawater concentration. Cell Tiss Res 257, 609621.Google Scholar
Shadwick, R.E., Pollock, C.M., & Stricker, S.A. (1990). Structure and biomechanical properties of crustacean blood vessels. Physiol Zool 63, 90101.Google Scholar
Steinacker, A. (1978). The anatomy of the decapod crustacean auxiliary heart. Biol Bull 154, 497507.Google Scholar
Tan, E.C. & Van Engel, W.A. (1966). Osmoregulation in the adult blue crab Callinectes sapidus. Chesapeake Sci 7, 3035.Google Scholar
Taylor, G.M. (2000). Maximum force production: Why are crabs so strong. Proc Roy Soc Lond B 267, 14751480.Google Scholar
Taylor, H.H. & Greenaway, P. (1979). The structure of the gills and lungs of the arid zone crab Holthusiana (Austrothelphusa) transversa (Brachyura, Sundathelphusidae) including observations on arterial vessels within the gills. J Zool (Lond) 189, 359384.Google Scholar
Taylor, H.H. & Greenaway, P. (1984). The role of the gills and branchiostegites in gas exchange in a bimodally air breathing crab Holthusiana transversa: Evidence for a facultative change in the distribution of the respiratory circulation. J Exp Biol 111, 103121.Google Scholar
Taylor, H.H. & Taylor, E.W. (1992). Gills and lungs: The exchange of gases and ions. In Microscopic Anatomy of the Invertebrates, Harrison, F.W. & Humes, A.G. (Eds.), vol. 10, pp. 203293. New York: Wiley Liss.
Wilkens, J.L. (1997). Possible mechanisms of control of vascular resistance in the lobster Homarus americanus. J Exp Biol 200, 487493.Google Scholar
Wilkens, J.L. (1999). The control of cardiac rhythmicity and of blood distribution in crustaceans. Comp Biochem Physiol 124A, 513538.Google Scholar
Wilkens, J.L., Davidson, G.M., & Cavey, M.J. (1997a). Vascular resistance and compliance in the lobster Homarus americanus. J Exp Biol 200, 477485.Google Scholar
Wilkens, J.L. & Taylor, H.H. (2003). The control of vascular resistance in the southern rock lobster, Jasus edwardsii (Decapoda: Palinuridae). Comp Biochem Physiol 135, 369376.Google Scholar
Wilkens, J.L., Yazawa, T., & Cavey, M.J. (1997b). Evolutionary derivation of the American lobster cardiovascular system: An hypothesis based on morphological and physiological evidence. Inverte Biol 116, 3038.Google Scholar