Relevant bibliographies by topics / Thalassinidean shrimp

Academic literature on the topic 'Thalassinidean shrimp'

Author: Grafiati
Published: 4 June 2021
Last updated: 31 January 2023

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Journal articles on the topic "Thalassinidean shrimp"

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Tudge, C. C., and C. W. Cunningham. "Molecular phylogeny of the mud lobsters and mud shrimps (Crustacea : Decapoda : Thalassinidea) using nuclear 18S rDNA and mitochondrial 16S rDNA." Invertebrate Systematics 16, no. 6 (2002): 839. http://dx.doi.org/10.1071/is02012.

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Partial sequences of the 18S nuclear and 16S mitochondrial ribosomal genes were obtained for 14�species of thalassinidean shrimp (families Callianassidae, Laomediidae, Strahlaxiidae, Thalassinidae and Upogebiidae) and a further six species in related decapod infraorders (families Aeglidae, Astacidae, Lithodidae, Palinuridae, Raninidae and Scyllaridae). Maximum-likelihood and Bayesian analyses show equivocal support for the monophyly of the Thalassinidea, but show strong support for division of the infraorder into two major clades. This dichotomy separates representatives in the Upogebiidae, Laomediidae and Thalassinidae from those in the Strahlaxiidae and Callianassidae. The Laomediidae is shown to be paraphyletic, with the thalassinid species, Thalassina squamifera, being placed on a branch between Axianassa and a clade comprising Jaxea and Laomedia, the three current laomediid genera. For a monophyletic Laomediidae, the family Axianassidae should be resurrected for the genus Axianassa.
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Griffis, RB, and TH Suchanek. "A model of burrow architecture and trophic modes in thalassinidean shrimp (Decapoda: Thalassinidea)." Marine Ecology Progress Series 79 (1991): 171–83. http://dx.doi.org/10.3354/meps079171.

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Stamhuis, E. J., J. J. Videler, and P. A. W. J. de Wilde. "Optimal foraging in the thalassinidean shrimp Callianassa subterranea." Journal of Experimental Marine Biology and Ecology 228, no. 2 (October 1998): 197–208. http://dx.doi.org/10.1016/s0022-0981(98)00026-4.

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Seo, Jaehwan, and Bon Joo Koo. "The Sediment Reworking of the Mud Shrimp Laomedia sp. (Crustacea: Laomediidae) with Tidal Conditions in the Intertidal Sediments of Gomso Bay, Korea." Journal of Marine Science and Engineering 9, no. 11 (November 11, 2021): 1251. http://dx.doi.org/10.3390/jmse9111251.

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Although the thalassinidean mud shrimp Laomedia sp. is one of the most abundant species in the upper tidal flats along the west coast of Korea, little is known of its ecological characteristics and bioturbation effects on intertidal sediments. This study estimated the sediment reworking rate (SRR) of Laomedia sp. by quantifying in situ sediments ejected from the burrows via direct entrapment and evaluated the effects of tidal conditions on the SRR. The amount of expelled sediments from individual burrows was significantly related to the duration of submergence, whereas SRR showed an increasing trend as elevation increased. The SRR of Laomedia sp. was estimated to be 40 g ind.−1 d−1 and the annual SRR of this species was 72.2 kg m−2 yr−1 based on the density in the study area, which is very high compared to other thalassinidean shrimp. These findings suggest that Laomedia sp. is an important bioturbator in intertidal sediments, and tidal conditions should be considered when evaluating the SRR of this species.
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Miller, M. F., and H. A. Curran. "Behavioral plasticity of modern and Cenozoic burrowing thalassinidean shrimp." Palaeogeography, Palaeoclimatology, Palaeoecology 166, no. 1-2 (February 2001): 219–36. http://dx.doi.org/10.1016/s0031-0182(00)00210-8.

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DWORSCHAK, PETER C., and MARINA R. CUNHA. "A new subfamily, Vulcanocalliacinae n.subfam., for Vulcanocalliax arutyunovi n.gen., n.sp. from a mud volcano in the Gulf of Cádiz (Crustacea, Decapoda, Callianassidae)." Zootaxa 1460, no. 1 (April 27, 2007): 35–46. http://dx.doi.org/10.11646/zootaxa.1460.1.3.

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A new ghost shrimp, Vulcanocalliax arutyunovi n.gen. n.sp., is described and accommodated in the new subfamily Vulcanocalliacinae. This subfamily shares with the Bathycalliacinae Sakai & Türkay, 1999 the presence of epipods on the third maxilliped and the first four pairs of pereopods, but differs by the absence of cardiac sulci and a dorsomedian carina. This is the second record of a thalassinidean crustacean from deep-sea chemoautotrophic communities.
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Kato, Makoto, and Gyo Itani. "Commensalism of a Bivalve, Peregrinamor Ohshimai, With a Thalassinidean Burrowing Shrimp, Upogebia Major." Journal of the Marine Biological Association of the United Kingdom 75, no. 4 (November 1995): 941–47. http://dx.doi.org/10.1017/s0025315400038261.

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Ecological, behavioural and anatomical observations of a commensal bivalve, Peregrinamor ohshimai (Mollusca: Galeommatoidea), were carried out in a tidal mudflat in the Seto Inland Sea, Japan. The bivalve attached specifically to the longitudinal groove of the ventral side of the cephalothorax of thalassinidean burrowing shrimps, Upogebia major and Lf. narutensis (Crustacea: Decapoda), singly, dorso-ventrally and longitudinally, using its byssus, with its anterior part towards the head of the host. The mantle of the commensal bivalve has wide anterior (branchio-pedal) and narrow posterior (exhalant) apertures. In the living organism, the extended anterior edges of the mantle protrude from the shell and are inserted into the host's filtering basket, which is formed by the setal rows of the first two pairs of pereiopods and utilized for intercepting suspended matter. By beating its pleopods in a U-shaped burrow, the filter-feeding Upogebia shrimp creates water currents, which are also utilized by the commensal bivalve for filter-feeding. The shell length of the commensal bivalve was in proportion to the host's carapace length. This suggests that the veliger larva attaches to a young host and grows, thus maintaining the host-commensal morphological matching. The bivalve is a hermaphrodite and individuals of >8–5 mm in shell length were already producing eggs. Anatomical observations suggest that P. ohshimai is most closely related to the Montacutidae in Galeommatoidea.
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Candisani, Luciano C., Paulo Y. G. Sumida, and Ana Maria S. Pires-Vanin. "Burrow morphology and mating behaviour of the thalassinidean shrimp Upogebia noronhensis." Journal of the Marine Biological Association of the United Kingdom 81, no. 5 (October 2001): 799–803. http://dx.doi.org/10.1017/s0025315401004611.

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Burrow morphology and mating behaviour of Upogebia noronhensis was studied using resin casting of burrows in the field and observation of laboratory maintained animals. Burrows of U. noronhensis showed a typical Y-shaped pattern in over 70% of the cases analysed. The remaining 30% comprised U-shaped burrows lacking the lower tunnel (shaft) and burrows with long additional branches projecting from the U portion. Results from animals left to construct burrows in the aquarium closely matched those found in nature. Field and laboratory burrows showed that different shapes are related to the collapse of the burrow walls, the burrowing activities of other individuals and species, and to the behaviour of the species itself. U-shaped burrows form as a result of the partial construction of the burrow (the U part is always built first) or owing to the collapse of the shaft. Burrows with additional branches always belonged to males and result from their search for a female with which to reproduce. This process also produced connected burrows. Mating occurs within the female burrow and this is the only time when two animals occupy the same burrow. After mating, the male returns to its burrow and immediately closes the connection. Larvae are planktonic and probably settle in adult areas, since the smallest juvenile burrows were always associated with adult burrows. This may contribute to the high population densities found in the field (∼200 ind m−2), which in consequence facilitates fossorial encounters for reproduction. This is the first time fossorial encounters for reproduction are reported for an Upogebia species and probably for all Thalassinidea.
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Swinbanks, David D., and John L. Luternauer. "Burrow distribution of thalassinidean shrimp on a Fraser Delta tidal flat, British Columbia." Journal of Paleontology 61, no. 2 (March 1987): 315–32. http://dx.doi.org/10.1017/s0022336000028493.

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Burrows of the thalassinidean shrimp Callianassa californiensis and Upogebia pugettensis, which resemble the trace fossils Thalassinoides and Ophiomorpha, respectively, occur on the southern tidal flats at the western front of the Fraser Delta. Burrow densities for both shrimp species are highest at lower intertidal levels immediately inshore of an extensive bed of Zostera marina eelgrass, but the high-density shrimp populations are segregated: the highest densities of C. californiensis burrows (350–450 burrow openings/m2) occur in a strip of clean sandy sediments, whereas U. pugettensis burrows are most abundant (30–80 burrow openings/m2) in a patch of muddy sands and sandy muds. On the tidal flats of the Fraser Delta as a whole, however, textural properties of the sediment show no consistent correlation with the burrow density of either shrimp.In the eelgrass bed, eelgrass root mats appear to markedly restrict the density of C. californiensis burrows. Towards the shore, the well-lined dwelling burrows of U. pugettensis occur no higher than mean sea level where maximum continuous exposure is ≤0.5 days. In contrast, C. californiensis, which has an unlined feeding burrow and a higher tolerance for anoxia, is present up to the margin of the local salt marsh which lies near the mean higher high water level where the flats can be exposed continuously up to 5 days.In situ experiments indicate that C. californiensis extrudes 18 ± 9 ml of wet sediment/shrimp/ day onto the substrate surface, while U. pugettensis seldom forms a mound around its burrow entrance. Burial of filter-feeding postlarval U. pugettensis under the mounds produced by C. californiensis may increase postlarval mortality and reduce adult populations of U. pugettensis in areas of high C. californiensis burrow density.The results of this study suggest that in distinguishing Ophiomorpha from Thalassinoides more emphasis should be placed on the presence of an extensive burrow lining in Ophiomorpha than on the presence of a knobby burrow exterior, because the former characteristic has a more profound bearing on burrow function, physiology of the occupant organism, and, consequently, burrow distribution.
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GRIPPA, G. "Salmoneus kekovae, a new species of alpheid shrimp (Crustacea: Decapoda: Caridea) from the south-western coast of Turkey." Mediterranean Marine Science 5, no. 2 (December 1, 2004): 45. http://dx.doi.org/10.12681/mms.202.

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A new species of Salmoneus collected in Turkish waters is described. It appears to live in burrows associated with gobiid fish or thalassinidean decapods, as do other species in the genus. Previously, twenty Salmoneus species have been recognised worldwide, two of which are known from the Mediterranean. Some morphological features are discussed in order to determine their taxonomic value. A table summarises the geographical distribution of the 21 species currently recognised.
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Dissertations / Theses on the topic "Thalassinidean shrimp"

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Feldman, Kristine Ladyka. "Contrasting patterns of habitat-specific recruitment success in sympatric species of thalassinidean shrimp : effects of epibenthic bivalve shell with implications for population control in areas with commercial oyster culture /." Thesis, Connect to this title online; UW restricted, 2001. http://hdl.handle.net/1773/5321.

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Grigg, Nicola Jane, and nicky grigg@csiro au. "Benthic Bulldozers and Pumps: Laboratory and Modelling Studies of Bioturbation and Bioirrigation." The Australian National University. Centre for Resource and Environmental Studies, 2003. http://thesis.anu.edu.au./public/adt-ANU20060228.104425.

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Aquatic sediments are the recipients of a continual rain of organic debris from the water column. The decomposition reactions within the sediment and the rates of material exchange between the sediment and water column are critically moderated by the transport processes within the sediment. The sediment and solute movement induced by burrowing animals – bioturbation and bioirrigation – far exceed abiotic transport processes such as sedimentation burial and molecular diffusion. Thalassinidean shrimp are particularly abundant burrowing animals. Living in high density populations along coastlines around the world, these shrimp build complex burrow networks which they actively maintain and irrigate.¶ I used a laser scanner to map thalassinidean shrimp (Trypaea australiensis) mound formation. These experiments measured rapid two-way exchange between the sediment and depth. Subduction from the sediment surface proved to be just as important as sediment expulsion from depth, yet this is not detected by conventional direct entrapment techniques. The experiments demonstrated that a daily sampling frequency was needed to capture the extent of the two-way exchange.¶ I derived a one-dimensional non-local model accounting for the excavation, infill and collapse (EIC) of burrows. Maximum likelihood analyses were used to test the model against 210Pb and 228Th profiles taken from sediment cores in Port Phillip Bay, Melbourne. The maximum likelihood approach proved to be a useful technique for quantifying parameter confidence bounds and allowing formal comparison with a comparable biodiffusion model. The EIC model generally outperformed the biodiffusion model, and in all cases best EIC model parameter estimates required some level of burrow infill with surface material. The EIC model was expanded to two and three dimensions, which allowed the representation of lateral heterogeneity resulting from the excavation, infill and collapse of burrow structures. A synthetic dataset generated by the two-dimensional model was used to demonstrate the effects of heterogeneity and core sampling on the mixing information that can be extracted from one-dimensional sediment core data.¶ Burrow irrigation brings oxygenated water into burrow depths, and can affect the nitrogen cycle by increasing the rates of coupled nitrification and denitrification reactions. I modelled the nitrogen chemistry in the annulus of sediment surrounding an irrigated burrow using a radially-symmetrical diffusion model. The model was applied to three published case studies involving thalassinidean shrimp experiments and to field data from Port Phillip Bay. The results highlighted divergences between current theoretical understanding and laboratory and field measurements. The model further demonstrated potential limitations of measurements of burrow characteristics and animal behaviour in narrow laboratory tanks. Activities of burrowing animals had been hypothesised to contribute to high denitrification rates within Port Phillip Bay. Modelling work in this thesis suggests that the model burrow density required to explain these high denitrification rates is not consistent with the sampled density of thalassinidean shrimp in the Bay, although dense burrows of other animals are likely to be important. Limitations of one-dimensional representations of nitrogen diagenesis were explored via comparisons between one-dimensional models and the full cylinder model.
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Pinn, Eunice Helen. "Studies on the feeding biology of thalassinidean mud-shrimps." Thesis, Online version, 1995. http://ethos.bl.uk/OrderDetails.do?did=1&uin=uk.bl.ethos.294806.

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Itani, Gyo. "Ecology of crustaceans and bivalves symbiotic with thalassinidean shrimps." 京都大学 (Kyoto University), 2002. http://hdl.handle.net/2433/150029.

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Grigg, Nicola Jane. "Benthic Bulldozers and Pumps: Laboratory and Modelling Studies of Bioturbation and Bioirrigation." Phd thesis, 2003. http://hdl.handle.net/1885/47121.

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Aquatic sediments are the recipients of a continual rain of organic debris from the water column. The decomposition reactions within the sediment and the rates of material exchange between the sediment and water column are critically moderated by the transport processes within the sediment. The sediment and solute movement induced by burrowing animals – bioturbation and bioirrigation – far exceed abiotic transport processes such as sedimentation burial and molecular diffusion. Thalassinidean shrimp are particularly abundant burrowing animals. Living in high density populations along coastlines around the world, these shrimp build complex burrow networks which they actively maintain and irrigate.¶ I used a laser scanner to map thalassinidean shrimp mound formation. These experiments measured rapid two-way exchange between the sediment and depth. Subduction from the sediment surface proved to be just as important as sediment expulsion from depth, yet this is not detected by conventional direct entrapment techniques. The experiments demonstrated that a daily sampling frequency was needed to capture the extent of the two-way exchange.¶ ...
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林鳳嬌. "the Biology of the "Luk-Kong Mud-shrimp" Upogebia Edulis Ngoc-Ho & Chan, 1992 (Crustacea: Decapoda: Thalassinidea: Upogebiidae) From Western Taiwan." Thesis, 1995. http://ndltd.ncl.edu.tw/handle/56157234808311710481.

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Books on the topic "Thalassinidean shrimp"

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Axioidea of the world and a reconsideration of the Callianassoidea (Decapoda, Thalassinidea, Callianassida). Leiden: Brill, 2011.

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Sakai, Katsushi. Upogebiidae of the World (Decapoda, Thalassinidea) (Crustaceana Monographs). Brill, 2006.

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Callianassoidea Of The World (Decapoda, Thalassinidea) (Crustaceana Monographs). Brill Academic Publishers, 2005.

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W, Heard Richard, and United States. National Marine Fisheries Service. Scientific Publications Office., eds. A guide to the Thalassinidea (Crustacea: Malacostraca: Decapoda) of the South Atlantic Bight. Seattle, Wash: U.S. Dept. of Commerce, National Oceanic and Atmospheric Administration, National Marine Fisheries Service, 2007.

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Sakai, Katsushi. Axioidea of the World and a Reconsideration of the Callianassoidea (Decapoda, Thalassinidea, Callianassida). BRILL, 2011.

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Book chapters on the topic "Thalassinidean shrimp"

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Oliveira, Danielly Brito de, Fernando Araújo Abrunhosa, and Jussara Moretto Martinelli-Lemos. "The Thalassinidean Mud Shrimp Upogebia vasquezi: Life Cycle and Reproductive Traits on the Amazonian Coast, Brazil." In Theriogenology. InTech, 2017. http://dx.doi.org/10.5772/intechopen.68934.

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Pillay, Deena, and George Branch. "Bioengineering effects of burrowing thalassinidean shrimps on marine soft-bottom ecosystems." In Oceanography and Marine Biology. CRC Press, 2011. http://dx.doi.org/10.1201/b11009-5.

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"Aspects of the Physiology, Biology and Ecology of THalassinidean Shrimps in Relation to Their Burrow Environment." In Oceanography and Marine Biology, 183–220. CRC Press, 2005. http://dx.doi.org/10.1201/9781420037449-7.

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Taylor, Alan, and R. James A. Atkinson. "Aspects of the Physiology, Biology and Ecology of Thalassinidean Shrimps in Relation to Their Burrow Environment." In Oceanography and Marine Biology, 211–78. CRC Press, 2005. http://dx.doi.org/10.1201/9781420037449.ch5.

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