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Books on the topic 'Larval growth and pupation'

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Author: Grafiati

Published: 4 June 2021

Last updated: 20 February 2023

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1

M, Wenner Adrian, ed. Larval growth. Rotterdam, Netherlands: A.A. Balkema, 1985.

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2

McKenney, Charles L. Influence of an insect growth regulator on larval development of a marine crustacean. Gulf Breeze, FL: U.S. Environmental Protection Agency, Environmental Research Laboratory, 1988.

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3

Brunson, Ronald E. Larval razorback sucker and bonytail survival and growth in the presence of nonnative fish in the Baeser floodplain wetland of the middle Green River: Final report. Vernal, UT: Utah Division of Wildlife Resources, 2005.

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4

Wenner, Adrian M. Crustacean Growth: Larval Growth (Crustacean Issues). CRC, 1985.

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5

Wenner, Adrian. Crustacean Issues 2: Larval Growth. CRC Press LLC, 2017.

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6

Wenner, Adrian. Crustacean Issues 2: Larval Growth. CRC Press LLC, 2017.

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7

Wenner, Adrian. Crustacean Issues 2: Larval Growth. CRC Press LLC, 2017.

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8

Wenner, Adrian. Crustacean Issues 2: Larval Growth. Taylor & Francis Group, 2017.

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9

Wenner, Adrian. Crustacean Issues 2: Larval Growth. CRC Press LLC, 2017.

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10

Test No. 241: The Larval Amphibian Growth and Development Assay (LAGDA). OECD, 2015. http://dx.doi.org/10.1787/9789264242340-en.

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11

(Canada), Environment Canada, ed. Biological test method: Test of larval growth and survival using fathead minnows. Ottawa, Ont., Canada: Environment Canada, 1992.

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12

Jaeckle, William, ed. Physiology of Larval Feeding. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786962.003.0009.

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The functional properties of marine invertebrate larvae represent the sum of the physiological activities of the individual, the interdependence among cells making up the whole, and the correct positioning of cells within the larval body. This chapter examines physiological aspects of nutrient acquisition, digestion, assimilation, and distribution within invertebrate larvae from an organismic and comparative perspective. Growth and development of larvae obviously require the acquisition of “food.” Yet the mechanisms where particulate or dissolved organic materials are converted into biomass and promote development of larvae differ and are variably known among groups. Differences in the physiology of the digestive system (secreted enzymes, gut transit time, and assimilation) within and among feeding larvae suggest the possibility of an underappreciated plasticity of digestive physiology. How the ingestion of seawater by and the existence of a circulatory system within larvae contribute to larval growth and development represent important topics for future research.

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13

Hendig, Paul Theodore. Larval population structure, growth, and foraging habits of the northwestern salamander in a lowland permanent pond. 1997.

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14

The influence of an insect growth regulator on the larval development of the mud crab Rhithropanopeus harrisii. [Washington, D.C.?: Environmental Protection Agency, 1994.

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15

Center for Environmental Research Information (U.S.) and Environmental Research Laboratory (Narragansett, R.I.), eds. Supplemental report for the sheepshead minnow and inland silverside larval survival and growth toxicity tests: Training videotape. Washington, DC: U.S. Environmental Protection Agency, Office of Research and Development, 1990.

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16

Wong, Christine Jaye. Insulin-like growth factor I (IGF I) in the red spotted newt, Notophthalmus viridescens: Description of larval limb development; localization of IGF I in larval and adult newt limbs; and effects of IGF I on epimorphic regeneration of an adult newt appendage in vitro. 2004.

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17

Ecology of larval and juvenile burbot (Lota lota): Abundance and distribution patterns, growth, and an analysis of diet and prey selection. Ottawa: National Library of Canada = Bibliothèque nationale du Canada, 1991.

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18

Pineda, Jesús, and Nathalie Reyns, eds. Larval Transport in the Coastal Zone: Biological and Physical Processes. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786962.003.0011.

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Larval transport is fundamental to several ecological processes, yet it remains unresolved for the majority of systems. We define larval transport, and describe its components, namely, larval behavior and the physical transport mechanisms accounting for advection, diffusion, and their variability. We then discuss other relevant processes in larval transport, including swimming proficiency, larval duration, accumulation in propagating features, episodic larval transport, and patchiness and spatial variability in larval abundance. We address challenges and recent approaches associated with understanding larval transport, including autonomous sampling, imaging, -omics, and the exponential growth in the use of poorly tested numerical simulation models to examine larval transport and population connectivity. Thus, we discuss the promises and pitfalls of numerical modeling, concluding with recommendations on moving forward, including a need for more process-oriented understanding of the mechanisms of larval transport and the use of emergent technologies.

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19

Pechenik, Jan A., ed. Latent Effects: Surprising Consequences of Embryonic and Larval Experience on Life after Metamorphosis. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198786962.003.0014.

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The coming years will apparently bring increases in seawater temperatures, salinity fluctuation, and ocean acidity, along with increasing pollution levels and increasing incidences of coastal hypoxic events. We can also expect to see shifting patterns of phytoplankton abundance and nutritional quality. Many such stresses experienced early in development—even among brooded embryos—have been found to influence growth rates, survival, and other fitness characteristics following metamorphosis, sometimes for months, both in laboratory studies and in those in which juveniles were transplanted to the field. The effects are usually negative, but have been seemingly positive in a few studies. Vulnerability can vary among species, and even among the offspring from different parents. The mechanisms through which such “latent effects” are mediated are unclear: energy-balance issues and epigenetic factors—in which gene expression patterns are altered without any changes in DNA sequences—seem to be involved.

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20

Sheppard, Charles R. C., Simon K. Davy, Graham M. Pilling, and Nicholas A. J. Graham. Reef fish. Oxford University Press, 2018. http://dx.doi.org/10.1093/oso/9780198787341.003.0006.

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This chapter discusses factors that have led to reef fish diversity. Geographic drivers for fish diversity, ranging from global historical events to local-scale drivers, are examined. Age and growth in reef fish are explored, followed by larval fish ecology. Colour diversity in modern reef fish is examined, along with mechanisms that have developed to enhance feeding success or predation avoidance. Different ecological feeding niches of coral reef fish are described and examples are given to illustrate the wide range of feeding mechanisms. The science around the abundance, biomass and trophic interactions of reef fish assemblages is examined. The range of fish feeding habits is detailed and functional roles of fish explored. Finally, the implications of changes in the reef fish community through fishing and habitat degradation are examined, highlighting the cascade effect of impacts on reefs, and how the influences of different disturbances interact to influence coral reef fish.

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