Abstract
Filtration rates and the extent of phagocytosed food particles were determined in the offshore lamellibranchs Artica islandica and Modiolus modiolus in relation to particle concentration, body size and temperature. Pure cultures of the algae Chlamydomonas sp. and Dunaliella sp. were used as food. A new method for determining filtration rates was developed by modifying the classical indirect method. The concentration of the experimental medium (100%) was kept constant to ±1%. Whenever the bivalves removed algae from the medium, additional algae were added and the filtration rate of the bivalves expressed in terms of percentage amount of algae added per unit time. The concentration of the experimental medium was measured continuously by a flow colorimeter. By keeping the concentration constant, filtration rates could be determined even in relation to different definite concentrations and over long periods of time. The amount of phagocytosed food was measured by employing the biuret-method (algae cells ingested minus algae cells in faeces). Filtration rates vary continuously. As a rule, however, during a period of 24 h, two phases of high food consumption alternate with two phases of low food consumption during which the mussels' activities are almost exclusively occupied by food digestion. Filtration rate and amount of phagocytosed algae increase with increasing body size. Specimens of A. islandica with a body length of 33 to 83 mm filter between 0.7 to 71/h (30–280 mg dry weight of algae/24 h) and phagocytose 21 to 122 mg dry weight of algae during a period of 24 h. The extent of food utilization declines from 75 to 43% with increasing body size. In M. modiolus of 40 to 88 mm body length, the corresponding values of filtration rate and amount of phagocytosed algae range between 0.5 and 2.5 l/h (20–100 mg dry weight of algae) and 17 to 90 mg dry weight of algae, respectively; the percentage of food utilization does not vary much and lies near 87%. Filtration rate and amount of phagocytosed algae follow the allometric equation y=a·x b. In this equation, y represents the filtration rate (or the amount of phagocytosed algae), a the specific capacity of a mussel of 1 g soft parts (wet weight), x the wet weight of the bivalves' soft parts, and b the specific form of relationship between body size and filtration rate (or the amount of phagocytosed algae). The values obtained for b lie within a range which indicates that the filtration rate (or the amount of phagocytosed algae) is sometimes more or less proportional to body surface area, sometimes to body weight. Temperature coefficients for the filtration rate are in Arctica islandica Q10 (4°–14°C)=2.05 and Q10 (10°–20°C)=1.23, in Modiolus modiolus Q10 (4°–14°C)=2.33 and Q10 (10°–20°C)=1.63. In A. islandica, temperature coefficients for the amount of phagocytosed algae amount to Q10 (4°–14°C)=2.15 and Q10 (10°–20°C)=1.55, in M. modiolus to Q10 (4°–14°C)=2.54 and Q10 (10°–20°C)=1.92. Upon a temperature decrease from 12° to 4°C, filtration rate and amount of phagocytosed algae are reduced to 50%. At the increasing concentrations of 10×106, 20×106 and 40×106 cells of Chlamydomonas/l offered, filtration rates of both mollusc species decrease at the ratios 3:2:1. At 12°C, pseudofaeces production occurs in both species in a suspension of 40×106, at 20°C in 60×106 cells of Chlamydomonas/l. At 12°C and 10–20×106 cells of Chlamydomonas/l, the maximum amount of algae is phagocytosed. At 40×106 cells/l, the amount of phagocytosed cells is reduced by 26% as a consequence of low filtration rates and intensive production of pseudofaeces. At 20°C and 20–50×106 cells of Chlamydomonas/l, the maximum amount of algae is sieved out and phagocytosed; the concentration of 10×106 cells/l is too low and cannot be compensated for by increased activity of the molluscs. With increasing temperatures, the amount of suspended matter, allowing higher rates of filtration and food utilization, shifts toward higher particle concentrations; but at each temperature a threshold exists, above which increase in particle density is not followed by increase in the amount of particles ingested. Based on theoretical considerations and facts known from literature, 7 different levels of food concentration are distinguishable. Experiments with Chlamydomonas sp. and Dunaliella sp. used as food, reveal the combined influence of particle concentration and particle size on filtration rate. Supplementary experiments with Mytilus edulis resulted in filtration rates similar to those obtained for M. modiolus, whereas, experiments with Cardium edule, Mya arenaria, Mya truncata and Venerupis pullastra revealed low filtration rates. These species, inhabiting waters with high seston contents, seem to be adapted to higher food concentrations, and unable to compensate for low concentrations by higher filtration activities. Adaptation to higher food concentrations makes it possible to ingest large amounts of particles even at low filtration rates. Suspension feeding bivalves are subdivided into four groups on the basis of their different food filtration behaviour.
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Zitierte literatur
Adler, J. and A. Hancock: On the branchial currents in Pholas and Mya. Ann. Mag. nat. Hist. 8, 370 (1851).
Allen, J. A.: On the structure and adaptations of Pandora inaequivalvis and P. pinna. Q. Jl microsc. Sci. 95, 473–482 (1954a).
—: A comparative study of the British species of Nucula and Nuculana. J. mar. biol. Ass. U.K. 33, 457–472 (1954b).
—: The British species of Thracia (Eulamellibranchia). J. mar. biol. Ass. U.K. 41, 723–735 (1961).
—: Preliminary experiments on the feeding and excretion of bivalves using Phaeodactylum labelled with 32P. J. mar. biol. Ass. U.K. 42, 609–623 (1962).
Ansell, A. D.: The functional morphology of the British species of Veneracea. J. mar. biol. Ass. U.K. 41, 489–515 (1961).
—: Some parameters of growth of mature Venus mercenaria L. J. Cons. perm. int. Explor. Mer 29, 214–220 (1964).
Atkins, D.: On the ciliary mechanisms and interrelationships of lamellibranchs. Part I. Some new observations on sorting mechanisms in certain lamellibranchs. Q. Jl microsc. Sci. 79, 181–308 (1936).
—: On the ciliary mechanisms and interrelationships of lamellibranchs. Part II. Sorting devices on the gills. Q. Jl microsc. Sci. 79, 339–373 (1937a).
—: On the ciliary mechanisms and interrelationships of lamellibranchs. Part III. Types of lamellibranch gills and their food currents. Q. Jl microsc. Sci. 79, 375–421 (1937b).
—: On the ciliary mechanisms and interrelationships of lamellibranchs. Part VII. Latero-frontal cilia of the gill filaments and their phylogenetic value. Q. Jl microsc. Sci. 80, 345–436 (1938)
—: On the ciliary mechanisms and interrelationships of lamellibranchs. Part VIII. Notes on gil musculature in Microciliobranchia. Q. Jl microsc. Sci. 84, 187–256 (1943).
Ballantine, D. and J. E. Morton: Filtering feeding and digestion in the lamellibranch Lasaea rubra. J. mar. biol. Ass. U.K. 35, 241–274 (1956).
Bennett, M. F.: The rhythmic activity of the quahog, Venus mercenaria, and its modification by light. Biol. Bull. mar. biol. Lab., Woods Hole 107, 174–191 (1954).
Bertalanffy, L. Von: Theoretische Biologie, Vol. 2, 362 pp. Bern: Francke 1942.
Blake, J. W.: Preliminary measurements of filter feeding activity of the soft-shell clam, Mya arenaria, by the use of radioactive algae. Biol. Bull. mar. biol. Lab., Woods Hole 121, 383 (1961).
Boje, R.: Weight of meat and shell and shell-shape of the mussel (Mytilus edulis L.) under different food conditions. Council Meeting of International Council for the Exploration of the Sea, Shellfish Committee 125 (1964).
—: Die Bedeutung von Nahrungsfaktoren für das Wachstum von Mytilus edulis L. in der Kieler Födde und im Nord-Ostsee-Kanal. Kieler Meeresforsch. 21, 81–100 (1965).
—: Proteine. Limnologica, Berlin 4, 383–386 (1966).
Bursche, E. M., H. Kühl und H. Mann: Beziehungen zwischen dem Chemismus und der Phytoplanktonentwicklung auf der unteren Weser. Int. Revue ges. Hydrobiol. 44, 277–298 (1959).
Carter, G. S.: On the structure and movements of the laterofrontal cilia of the gills of Mytilus edulis. Proc. R. Soc. (B) 96, 115–122 (1924).
Caspers, H.: Die Bodenfauna der Helgoländer Tiefen Rinne. Helgoländer wiss. Meeresunters. 2, 1–112 (1939).
Chipman, W. A. and J. G. Hopkins: Water filtration by the bay scallop, Pecten irradians, as observed with the use of radioactive plankton. Biol. Bull. mar. biol. Lab., Woods Hole 107, 80–91 (1954).
Clausen, C.: On the anatomy and histology of the eulamellibranch Kelliella miliaris (Philippi) with observations on the ciliary mechanisms in the mantle cavity. Nytt Mag. Zool. 6, 144–175 (1958).
Cole, H. A. and B. T. Hepper: The use of neutral red solution for the comparative study of filtration rates of lamellibranchs. J. Cons. perm. int. Explor. Mer 20, 197–204 (1954).
Collier, A., S. M. Ray, A. W. Magnitzky and J. O. Bell: Effect of dissolved organic substances on osyters. Fish. Bull. Fish Wildl. Serv. U.S. 54, 165–185 (1953).
Coughlan, J.: The estimation of filtering rate from the clearance of suspensions. Mar. Biol. 2, 356–358 (1969).
— and A. D. Ansell: A direct method for determining the pumping rate of siphonate bivalves. J. Cons. perm. int. Explor. Mer 29, 205–213 (1964).
Dam, L. Van: On the utilization of oxygen by Mya arenaria. J. exp. Biol. 12, 86–94 (1935).
Davids, C.: The influence of suspensions of microorganisms of different concentrations on the pumping and retention of food by the mussel (Mytilus edulis L.) Neth. J. Sea Res. 2, 233–249 (1964).
Deutscher Wetterdienst, Seewetteramt: Meteorologische Beobachtungen von deutschen Feuerschiffen der Nord- und Ostsee (Bundesrepublik), 1953–1961. Deutscher Wetterdienst, Seewetteramt Hamburg, in: Einzelveröffentlichungen 13–15, 19, 22, 32, 35, 36, 42 und 45 (1957–1965).
Dinamani, P.: A note on feeding and excretion in bivalves. Veliger 11, 198–199 (1969).
Dral, A. D. G.: The movements of the latero-frontal cilia and the mechanisms of particle retention in the mussel (Mytilus edulis L.). Neth. J. Sea Res. 3, 391–422 (1967).
—: On the feeding of mussels (Mytilus edulis L.) in concentrated food suspensions. Neth. J. Zool. 18, 440–441 (1968).
Drinnan, R. E.: An apparatus for recording the waterpumping behaviour of lamellibranchs. Neth. J. Sea Res. 2, 223–232 (1964).
Durve, V. S.: A study on the rate of filtration of the clam Meretrix casta (Chemnitz). J. mar. biol. Ass. India 5, 221–231 (1963).
Elsey, C. R.: On the structure and function of the mantle and gill of Ostrea gigas Thunberg and Ostrea lurida Carpenter. Trans. R. Soc. Can. 5, 131–158 (1935).
Erman, P.: Der Einfluß physikalischer und chemischer Faktoren auf die Pumprate der Miesmuschel Mytilus edulis L. Kieler Meeresforsch. 18, 51–66 (1961).
Fish, G. R.: Digestion and the production of sulphuric acid by Mollusca. Nature, Lond. 175, 733–734 (1955).
Flügel, H. und C. Schlieper: Der Einfluß physikalischer und chemischer Faktoren auf die Cilienaktivität und Pumprate der Miesmuschel Mytilus edulis. Kieler Meeresforsch. 18, 51–66 (1962).
Fox, D. L., H. U. Sverdrup and J. P. Cunningham: The rate of water propulsion by the California mussel. Biol. Bull. mar. biol. Lab., Woods Hole 72, 417–438 (1937).
Galtsoff, P. S.: New methods to measure the rate of flow produced by the gills of oyster and other mollusca. Science, N.Y. 63, 233–234 (1926).
—: Experimental study of the function of the oyster gills and its bearing on the problems of oyster-culture and sanitary control of the oyster industry. Bull. Bur. Fish., Wash. 44, 1–39 (1928a).
—: The effect of temperature on the mechanical activity of the gills of the oyster (Ostrea virginica Gm.). J. gen. Physiol. 11, 415–431 (1928b).
—, W. A. Chipman, J. B. Engle and H. N. Calderwood: Ecological and physiological studies of the effect of sulfate pulp mill wastes on oysters in the York River, Virginia. Fishery Bull. Fish Wildl. Serv. U.S. 51, 59–186 (1947).
Graham, A.: On the morphology, feeding mechanisms and digestion of Ensis siliqua (Schumacher). Trans. R. Soc. Edinb. 56, 725–752 (1931).
—: On the ciliary currents on the gills of some Tellinacea (Lamellibranchiata). Proc. R. Soc. Edinb. 57, 128–134 (1937).
Gray, J.: Ciliary movements, 192 pp. Cambridge: University Press 1928.
Hagmeier, E.: Assimilation and dissimilation measurements on plankton of Helgoland waters. Helgoländer wiss. Meeresunters. 15, 137–142 (1967).
—: Planktonbestand und Primärproduktion bei Helgoland. Jber. Biol. Anst. Helgol. 1967 ca, 66–69 (1968).
Hamwi, A. and H. H. Haskin: Oxygen consumption and pumping rates in the hard clam Mercenaria mercenaria: A direct method. Science, N.Y. 163, 823–824 (1969).
Hazelhoff, E. H.: Über die Ausnutzung des Sauerstoffs bei verschiedenen Wassertieren. Z. vergl. Physiol. 26, 306–327 (1938).
Hecht, F. und H. Matern: Zur Ökologie von Cardium edule L. Senckenbergiana 12, 364–368 (1930).
Hersh, G. L.: A method for the study of the water currents of invertebrate ciliary filter feeders. Veliger 2, 77–83 (1960).
Hopkins, A. E.: Temperature and shell movements of oysters. Bull. Bur. Fish., Wash. 47, 1–14 (1931).
—: Sonsory stimulation of the oyster, Ostrea virginica, by chemicals. Bull. Bur. Fish., Wash. 47, 249–261 (1932a).
—: Chemical stimulation by salts in the oyster, Ostrea virginica. J. exp. Zool. 61, 14–27 (1932b).
—: Experiments on the feeding behaviour of the oyster Ostrea gigas. J. exp. Zool. 64, 469–494 (1933).
—: Temperature optima in the feeding mechanisms of the oyster, Ostrea gigas. J. exp. Zool. 71, 195–208 (1935).
—: Adaptation of the feeding mechanism of the oyster (Ostrea gigas) to changes in salinity. Bull. Bur. Fish., Wash. 48, 345–363 (1936a).
—: Adtivity of the adductor muscle in oysters. Physiol. Zoöl. 9, 498–507 (1936b).
Jørgensen, C. B.: On the water transport through the gills of bivalves. Acta physiol. scand. 5, 297–304 (1943).
—: Feeding-rates of sponges, lamellibranchs and ascidians. Nature, Lond. 163, 912 (1949a).
—: The rate of feeding by Mytilus edulis in different kinds of suspensions. J. mar. biol. Ass. U.K. 28, 333–344 (1949b).
—: On the relation between water transport and food requirements in some marine filter-feeding invertebrates. Biol. Bull. mar. biol. Lab., Woods Hole 103, 356–363 (1952).
—: Quantitative aspects of filter feeding in invertebrates. Biol. Rev. 30, 391–454 (1955).
—: On porosity of gill filters and filtration rate in mussels (Mytilus edulis). Bull. Mt Desert Isl. biol. Lab. 4, 28 (1959).
—: Efficiency of particle retention and rate of water transport in undisturbed lamellibranchs. J. Cons. perm. int. Explor. Mer 26,94–116 (1960).
—: Biology of suspension feeding, 645 pp. New York: Academic Press 1966.
— and E. D. Goldberg: Particle filtration in some ascidians and lamellibranchs. Biol. Bull. mar. biol. Lab., Woods Hole 105, 477–489 (1953).
Johannes, R. E. and M. Satomi: Composition and nutrive value of fecal pellets of a marine crustacean. Limnol. Oceanogr. 11, 191–197 (1966).
Kellogg, J. L.: Ciliary mechanisms of lamellibranchs with descriptions of anatomy. J. Morph. 26, 625–701 (1951).
Kittel, A.: Körpergroße, Körperzeiten und Energiebilanz. II. Der Sauerstoffverbrauch der Insekten in Abhängigkeit von der Körpergröße. Z. vergl. Physiol. 28, 553–562 (1941).
Krey, J.: Eine neue Methode zur quantitativen Bestimmung des Planktons. Kieler Meeresforsch. 7, 58–75 (1950).
—: Quantitative Bestimmung von Eiweiß in Plankton mittels der Biuretreaktion. Kieler Meeresforsch. 8, 16–29 (1951).
—: Die Trophie küstennaher Meeresgebiete. Kieler Meeres forsch. 12, 46–64 (1956).
—, K. Banse und E. Hagmeier: über die Bestimmung von Eiweiß im Plankton mittles der Biuretreaktion. Kieler Meeresforsch. 13, 35–40 (1957).
Krishnamurthy, S. and V. D. Ramamurthy: Studies on the rate of feeding of estuarine vivalve Arca granosa (L.). In: Symposium on Mollusca; Ernakulam (Cochin). Mar. biol. Ass. India, Abstract No. 32, 28 (1968).
Krüger, F.: Die Beziehungen des Sauerstoffverbrauchs zur Körperoberfläche beim Schweinespulwurm (Asceris lumbricoides). J. wiss. Zool. 152, 547–570 (1940).
—: Zur Frage der Größenabhängigkeit des Sauerstoffverbrauchs von Mytilus edulis L. Helgoländer wiss. Meeresunters. 7, 125–148 (1960).
Kuenzler, E. J.: Phosphorus budget of a mussel population. Limnol. Oceanogr. 6, 400–415 (1961).
Kühl, H.: Studien über die Klaffmuschel Mya arenaria. Die Myasiedlungen am Hakensand (Elbmündung). Arch. Fisch Wiss. 4, 126–131 (1952).
Lavine, T. F.: A study of the enzymatic and other properties of the crystalline style of clams: evidence for the presence of a cellulase. J. cell. comp. Physiol. 28, 183–195 (1946).
Loosanoff, V. L.: Some aspects of behavior of oysters at different temperatures. Biol. Bull. mar. biol. Lab., Woods Hole 114, 57–70 (1958).
—: Effects of turbidity on some larval and adult bivalves. Proc. Gulf Caribb. Fish. Inst. 14, 80–94 (1961).
— and H. C. Davis: Rearing of bivalve molluscs. In: Advances in marine biology, Vol. 1, pp 1–136. Ed. by F. S. Russell. London: Academic Press 1963.
— and J. B. Engle: Effects of different concentrations of plankton forms upon shell movements, rate of water pumping and feeding and fattening of oysters. Anat. Rec. 84, 86–87 (1942).
— and J. B. Engle: Effects ofdifferent concentrations of microorganisms on the feeding of oysters. Fishery Bull. Fish Wildl. Serv. U.S. 51, 31–57 (1947a).
— and J. B. Engle: Feeding of oysters in relation to density of microorganisms. Science, N.Y. 105, 260–261 (1947b).
— and C. A. Nomejko: Feeding of oysters in relation to tidal stages and to periods of light and darkness. Biol. Bull. mar. biol. Lab., Woods Hole 90, 244–264 (1946).
— and F. D. Tommers: Effect of suspended silt and other substances on rate of feeding of oysters. Science, N.Y. 107, 69–70 (1948).
Lucas, A. M.: An investigation of the nervous system as a possible factor in the regulation of ciliary activity of the lamellibranch gill. J. Morph. 51, 147–193 (1931a).
—: The distribution of the branchial nerve in Mytilus edulis and its relation to the problem of nervous control of ciliary activity. J. Morph. 51, 195–205 (1931b).
—: Co-ordination of ciliary movement. I. Methods of study and the relation of ciliary co-ordination to ciliary inhbition. J. Morph. 53, 243–263 (1932).
Lüneburg, H.: Die Verteilung der Sinkstoffe in den Seitenräumen der Wesermündung. Veröff. Inst. Meeresforsch. Bremerh. 3, 228–258 (1955).
MacGinitie, G. E.: On the method of feeding of four pelecypods. Biol. Bull. mar. biol. Lab., Woods Hole 80, 18–25 (1941).
—: The size of the mesh openings in mucus feeding nets of marine animals. Biol. Bull. mar. biol. Lab., Woods Hole 88, 107–111 (1945).
Maurer, D.: Feltering experiments on marine pelecypods from Tomales Bay, California. Veliger 9, 305–309 (1967).
Mikhejev, V. P. and Y. J. Sorokin: Quantitative studies of Dreissena feeding habits by the radiocarbon method. Zh. obshch. Biol. 27, 463–472 (1966).
Moore, H. F.: Volumetric studies of the food and feeding of oysters. Bull. Bur. Fish., Wash. 28, 1297–1308 (1910).
Morton, J. E.: Molluscs, 232 pp. London: Hutchinson & Co. 1958.
Murakami, A.: Analysis of metachronical co-ordination in ciliary pads of Mytilus gill. J. Fac. Sci. Tokyo Univ. (4) 10, 23–35 (1963).
Muus, B. J.: The fauna of Danish estuaries and lagoons. —Distribution and ecology of dominating species in the shallow reaches of the mesohaline zone. Meddr Danm. Fisk.-og Havunders. 5, 1–316 (1967).
Nagabhushanam, R.: The rate of water filtration in the marine wood-boring molluse, Martesia striata L. Proc. India Acad. Sci. 43, 223–227 (1956).
—: Rate of water pumping of Modiolus demissus in relation to salinity and temperature. J. scient. ind. Res. 20, 67–68 (1961).
—: Rhythmic activity of the ribbed mussel, Modiolus demissus (Dillwyn). Sci. Cult. 29, 410 (1963).
Nelson, T. C.: On the feeding habits of oysters. Proc. Soc. exp. Biol. Med. 21, 90–91 (1923a).
—: The mechanism of feeding in the oyster. Proc. Soc. exp. Biol. Med. 21, 166–168 (1923b).
—: Water filtration by the oyster and a new hormone effect thereon. Anat. Rec. 64 (Suppl. 1), 68 (1935).
—: Water filtration by the oyster and a new hormone effect upon the rate of flow. Proc. Soc. exp. Biol. Med. 34, 189–190 (1936).
—: The feeding mechanism of the oyster. J. Morph. 63, 1–61 (1938).
—: The feeding mechanism of the oyster. II. On the gills and palps of Ostrea edulis, Crassostrea virginica and C. angulata. J. Morph. 107, 163–191 (1960).
Newell, B. S.: Cellulolytic activity in the lamellibranch crystalline style. J. mar. biol. Ass. U.K. 32, 491–495 (1953).
Newell, R.: The role of detritus in the nutrition of two marine deposit feeders, the prosobranch Hydrobia ulva and and the bivalve Macoma balthica. Proc. Zool. Soc. Lond. 144, 25–45 (1965).
Newell, R. C.: Effect of temperature on the metabolism of poikilotherms. Nature, Lond. 212, 426–428 (1966).
Oldfield, E.: Observations on the anatomy and mode of life of Lasaea rubra (Montagu) and Turtonia minuta (Fabricius). Proc. malac. Soc. Lond. 31, 226–249 (1955).
—: The functional morphology of some small lamellibranchs. Rep. Challenger Soc. 3, 23 (1958).
—: The functional morphology of Kellia suborbicularis, Montacuta ferruginosa and M. substriata. Proc. malac. Soc. Lond. 34, 255–295 (1961).
Orton, J. H.: The ciliary mechanisms on the gill and the mode of feeding in Amphioxus, ascidians and Solenomya togata. J. mar. biol. Ass. U.K. 10, 19–49 (1913).
Owen, G.: On the biology of Glossus humanus (L.). J. mar. biol. Ass. U.K. 32, 85–106 (1953).
Purchon, R. D.: On the biology and relationship of the lamellibranch Xylophaga dorsalis (Turton). J. mar. biol. Ass. U.K. 25, 1–41 (1941).
—: A note on the biology of the lamellibranch Rocellaria cuneformis Spengler. Proc. Zool. Soc. Lond. 124, 17–33 (1954).
—: The functional morphology of the rock-boring lamellibranch, Petricola pholadiformis Lamarck. J. mar. biol. Ass. U.K. 34, 257–278 (1955).
Rao, K. P.: Rate of water propulsion in Mytilus californianus as a function of latitude. Biol. Bull. mar. biol. Lab., Woods Hole 104, 171–181 (1953).
—: Tidal rhythmicity of rate of water propulsion in Mytilus and its modificibility by transplantation. Biol. Bull. mar. biol. Lab., Woods Hole 106, 353–359 (1954).
Rice, T. R. and R. J. Smith: Filtering rates of the hard clam (Venus mercenaria) determined with radioactive plankton. Fishery Bull. Fish. Wildl. Serv. U.S. 58, 73–82 (1958).
Ridewood, W. G.: On the structure of the gills of the Lamellibranchia. Phil. Trans. R. Soc. 195, 147–284 (1903).
Riley, G. A.: Plankton studies. III. Long Island Sound. Bull. Bingham oceanogr. Coll. 7, 1–93 (1941).
Rotthauwe H. W.: Untersuchungen zur Atmungsphysiologie und Osmoregulation bei Mytilus edulis mit einem kurzen Anhang über die Blutkonzentration von Dreissensia polymorpha in Abhängigkeit vom Elektrolytgehalt des Außenmediums. Veröff. Inst. Meeresforsch. Bremerh. 5, 143–159 (1958).
Salánki, J.: Daily acitivity rhythm of two mediterranean Lamellibranchia (Pecten jacobaeus and Lithophaga lithophaga) regulated by light-dark period. Annls Inst. biol. Tihany 33, 135–142 (1966a).
—: Comparative studies on the regulation of the periodic activity in marine lamellibranchs. Comp. Biochem. Physiol. 18, 829–843 (1966b).
— and F. Lukacsovics: Filtration and O2 consumption related to the periodic activity of the freshwater mussel Anodonta cygnea L. Annls Inst. biol. Tihany 34, 85–98 (1967).
Schlieper, C.: Über die physiologischen Wirkungen des Brackwassers. (Nach Versuchen an der Miesmuschel Mytilus edulis L.). Kieler Meeresforsch. 11, 22–33 (1955).
— und R. Kowalski: Über den einfluß des Mediums auf die thermische und osmotische Resistenz des Kiemengewebes der Miesmuschel Mytilus edulis L. Kieler Meeresforsch. 12, 37–45 (1956).
— und R. Kowalski: Weitere Beobachtungen zur ökologischen Physiologie der Miesmuschel Mytilus edulis L. Kieler Meeresforsch. 13, 3–10 (1957).
— und R. Kowalski: Ein zellulärer Regulationsmechanismus für erhöhte Kiemenventilation nach Anoxybiose bei Mytilus edulis L. Kieler Meeresforsch. 14, 42–47 (1958a).
— und R. Kowalski: Der Einfluß gelöster organischer Zellnahrungsstoffe und anorganischer stickstoffhaltiger Verbindungen auf die Cilienaktivität der isolierten Kiemen von Mytilus edulis L. Kieler Meeresforsch. 14, 114–129 (1958b).
— und P. Erman: Beitrag zur ökologisch-zellphysiologischen Charakterisierung des borealen Lamellibranchier Modiolus modiolus L. Kieler Meeresforsch. 14, 3–10 (1958).
Segal, E., K. P. Rao and T. W. James: Rate of activity as a function of intertidal height within populations of some littoral molluscs. Nature, Lond. 172, 1108–1109 (1953).
Setna, S. B.: Neuro-musculature mechanism of the gill of Pecten. Q. J. microsc. Sci. 73, 365–391 (1930).
Smith, R. J.: Filtering efficiency of hard clams in mixed suspensions of radioactive phytoplankton. Proc. natn. Shellfish. Ass. 48, 115–124 (1958).
Spärck, R.: On the relation between metabolism and temperature in some marine lamellibranchs, and its zoogeographical significance. Biol. Meddr 13, 1–27 (1936).
Stasek, C. R.: The ciliation and function of the labial palps of Acila castrensis, with an evaluation of the role of the protobranch organs of feeding in the evolution of the Bivalvia. Proc. Zool. Soc. Lond. 137, 511–538 (1961).
Stickney, A. P.: Feeding and growth of juvenile soft-shell clams, Mya arenaria. Fishery Bull. Fish Wildl. Serv. U.S. 63, 635–655 (1964).
Stone, B. A. and J. E. Morton: The distribution of cellulases and related enzymes in Mollusca. Proc. malac. Soc. Lond. 33, 127–141 (1958).
Studnitz, G. Von: Die Morphologie und Anatomie von Lima inflata, der Feilenmuschel, nebst biologischen Untersuchungen an Lima hians Gmel. (Diss.). Zool. Jb. 53, 199–317 (1931).
Tammes, P. M. L. and A. D. G. Dral: Observations on the straining of suspensions by mussels. Archs néerl. Zool. 11, 87–112 (1955).
Theede, H.: Experimentelle Untersuchungen über die Filtrierleistung der Miesmuschel Mytilus edulis L. Kieler Meeresforsch. 19, 20–41 (1963).
— Vergleichende experimentelle Untersuchungen über die zelluläre Gefrierresistenz mariner Muscheln. Kieler Meeresforsch. 21, 153–166 (1965).
— and J. Lassig: Comparative studies on cellular resistance of bivalves from marine and brackish waters. Helgoländer wiss. Meeresunters. 16, 119–129 (1967).
Thorson, G.: Zur jetzigen Lage der marinen Bodentier-Ökologie. 45. Verh. dt. zool. Ges. (= Zool. Anz. Suppl. Bd. 16), 276–327 (1951).
Tomczak, G. und E. Goedecke: Monatskarten der Temperatur der Nordsee, dargestellt für verschiedene Tiefenhorizonte. Dt. hydrogr. Z. (Suppl. B) 7, 1–16 (1962).
Trevallion, A. and A. D. Ansell: Studies on Tellina tenuis da Costa: II. Preliminary experiments in enriched sea water. J. exp. mar. Biol. Ecol. 1, 257–270 (1967).
Vernberg, F. J., C. Schlieper and D. E. Schneider: The influence of temperature and salinity on ciliary activity of excised gill tissue of molluscs from North Carolina. Comp. Biochem. Physiol. 8, 271–285 (1963).
Wallengren, H.: Zur Biologie der Muscheln. 1. Die Wasserströmungen. Lunds Univ. Årsskr. (Afd. 2) 1, 1–64 (1905a).
—: Zur Biologie der Muscheln. 2. Die Nahrungsaufnahme. Lunds Univ. Årsskr. (Afd. 2) 1, 1–59 (1905b).
Willemsen, J.: Quantities of water pumped by mussels (Mytilus edulis) and cockles (Cardium edule). Archs néerl. Zool. 10, 152–160 (1952).
Yonge, C. M.: The mechanism of feeding, digestion and assimilation in Mya. Br. J. exp. Biol. 1, 15–64 (1923).
—: The digestive diverticula in the lamellibranchs. Trans. R. Soc. Edinb. 54, 703–718 (1926).
—: Structure and function of the organs of feeding and digestion in the septibranchs, Cuspidaria and Poromya. Phil. Trans. R. Soc. 216, 212–263 (1928a).
—: Feeding mechanisms in the invertebrates. Biol. Rev. 3, 21–76 (1928b).
—: Mode of life, feeding, digestion and symbiosis with Zooxanthellae in the Tridacnidae. Scient. Rep. Gt Barrier Reef Exped. 1, 283–321 (1936).
—: On the habits and adaptations of Aloides gibba. J. mar. biol. Ass. U.K. 26, 358–376 (1946).
—: Cleansing mechanisms and the function of the fourth pallial aperture in Spisula subtruncata (da Costa) and Lutraria lutraria (L.). J. mar. biol. Ass. U.K. 27, 585–596 (1948).
—: On the structure and adaptations of the Tellinacea, deposit-feeding Eulamellibranchia. Phil. Trans. R. Soc. 234, 29–76 (1949).
Zeuthen, E.: Body size and metabolic rate in the animal kingdom with special regard to the marine microfauna. C. r. Trav. Lab. Carlsberg (Ser. chim.) 26, 17–161 (1947).
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Winter, J.E. Über den Einfluß der Nahrungskonzentration und anderer Faktoren auf Filtrierleistung und Nahrungsausnutzung der Muscheln Arctica islandica und Modiolus modiolus . Marine Biology 4, 87–135 (1969). https://doi.org/10.1007/BF00347037
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DOI: https://doi.org/10.1007/BF00347037