Aquaculture up and down the food web

Roger S. V. Pullin

doi:10.1017/CBO9780511920943.009

7 - Aquaculture up and down the food web

Published online by Cambridge University Press: 05 June 2012

Roger S. V. Pullin

Edited by

Villy Christensen and

Jay Maclean

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Roger S. V. Pullin: Affiliation:
7A Legaspi Park View, Philippines
Villy Christensen: Affiliation:
University of British Columbia, Vancouver
Jay Maclean: Affiliation:
Fisheries Consultant

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Summary

INTRODUCTION

This chapter celebrates the author's long association with Daniel Pauly, as a colleague in the International Center for Living Aquatic Resources Management (ICLARM) from 1979 to 1999, and as a firm friend and collaborator in aquatic science thereafter. Daniel's prolific contributions to fisheries science have included many that pertain, directly or indirectly, to aquaculture. Growth and reproduction of all fish, wild and farmed, are determined by the same natural laws and this has provided perfect “Pauly territory” for fundamental research and development of new methods.

Daniel and his many collaborators and disciples have also taken concepts and methods developed for capture fisheries management and ecology and have adapted and/or applied them to important areas in aquaculture research and development, for example, fish egg development (Pauly and Pullin, 1988, 1997), food consumption of fishes (Palomares and Pauly, 1996), growth of farmed fish (Pauly and Hopkins, 1983; Hopkins et al., 1988; Pauly et al., 1988; Mair and Pauly, 1993; Prein et al., 1993; Prein and Pauly, 1993; Van Dam and Pauly, 1995; Moreau and Pauly, 1999), industrial fisheries that provide ingredients for fish feeds (Pauly and Tsukayama, 1987; Pauly et al., 1989; Pauly et al., 2005); invasive alien species (Pullin et al., 1997), mortality estimations (Hopkins and Pauly, 1993), predator–prey relationships (Hopkins et al., 1982), tilapia biology and farming (Peters, 1983; Pullin et al., 1996) and trophic modeling (Lightfoot et al., 1993; Ruddle and Christensen, 1993; Van Dam et al., 1993).

Type: Chapter
Information: Ecosystem Approaches to Fisheries
A Global Perspective
, pp. 89 - 119

DOI: https://doi.org/10.1017/CBO9780511920943.009 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2011

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References

,ADB (2005) An Evaluation of Small-scale Freshwater Rural Aquaculture Development for Poverty Reduction. Manila, Philippines: Asian Development Bank.Google Scholar

,Anon. (2006) Diet and the unborn child. The omega point. The Economist, January 19, 2006.

Asche, F. and Tveterås, S. (2004) On the relationship between aquaculture and reduction fisheries. Journal of Agricultural Economics, 55, 245–265.CrossRef Google Scholar

Bayvel, A. C. D. (2005) Animals in science and agriculture: a global perspective. Biologist, 52, 339–344.Google Scholar

Benetti, D. D., Brand, L., Collins, J., Orhun, R., Benetti, A., O'Hanlon, B., Danylchuk, A., Alston, D., Rivera, J. and Cabarcas, A. (2006) Can offshore aquaculture of carnivorous fish be sustainable? World Aquaculture, 37, 44–47.Google Scholar

Bharadwaj, A. S., Brignon, W. R., Gould, N. L., Brown, P. B. and Wu, Y. V. (2002) Evaluation of meat and bone meal in practical diets fed to juvenile hybrid striped bass Morone chrysops × M. saxatilis. Journal of the World Aquaculture Society, 33, 448–457.CrossRef Google Scholar

Bowen, S. H. (1980) Detrital non-protein amino acids are the key to rapid growth of tilapia in Lake Valencia, Venezuela. Science, 207, 1216–1218.CrossRef Google Scholar

Bowen, S. H. (1987) Composition and nutritive value of detritus. In Moriarty, D. J. W. and Pullin, R. S. V., eds., Detritus and Microbial Ecology in Aquaculture. Manila, Philippines: ICLARM.Google Scholar

Bozynski, C. (1998) Interactions between growth, sex, reproduction, and activity levels in control and fast-growing strains of Nile tilapia (Oreochromis niloticus). MSc thesis, Department of Zoology, University of British Columbia, Vancouver, Canada.

Brewer, D. J. and Friedman, R. F. (1989) Fish and Fishing in Ancient Egypt. Cairo, Egypt: American University in Cairo Press.Google Scholar

Brook, A. J. (1993) The Rev. William Buckland, the first palaeoecologist. Biologist, 40, 149.Google Scholar

Brugère, C. and Ridler, N. (2004) Global Aquaculture Outlook in the Next Decades: an Analysis of National Aquaculture Production Forecasts to 2030. FAO Fisheries Circular. Rome: FAO.Google Scholar

Bureau, D. P. (2000) Fish feeds: Use of rendered animal protein ingredients. International Aquafeed, July 2000, 30–34.

Cagauan, A. G. and Pullin, R. S. V. (1994) Azolla in aquaculture: past, present and future. In Cagauan, A. G., Pullin, R. S. V., Muir, J. F. and Roberts, R. J., eds., Recent Advances in Aquaculture. Oxford, UK: Blackwell Science.Google Scholar

Casal, C. M. V. (2006) Global documentation of fish introductions: the growing crisis and recommendations for action. Biological Invasions, 8, 3–11.CrossRef Google Scholar

Chau, G. T. H. and Sadovy, Y. (2005) The use of mixed fish feed in Hong Kong's mariculture industry. World Aquaculture, 36, 6–13.Google Scholar

Costa-Pierce, B., Desbonnet, A., Edwards, P. and Baker, D. (2005) Urban Aquaculture. Wallingford, UK: CABI Publishing.CrossRef Google Scholar

Costa-Pierce, B. A. (1987) Aquaculture in ancient Hawaii. Bioscience, 37, 320–331.CrossRef Google Scholar

Costa-Pierce, B. A. (2002) Ecological Aquaculture: The Evolution of the Blue Revolution. Oxford, UK: Blackwell Science.CrossRef Google Scholar

Silva, S., Maitipe, P. and Cumaranatunge, R. (1984) Aspects of the biology of the euryhaline Asian cichlid, Etroplus suratensis. Environmental Biology of Fishes, 10, 77–87.CrossRef Google Scholar

Silva, S. S., Nguyen, T. T. T.Abery, N. W. and Amarasinghe, U. S. (2006) An evaluation of the role and impact of alien fish in Asian inland aquaculture. Aquaculture Research, 37, 1–17.CrossRef Google Scholar

Delgado, C. L., Wada, N., Rosegrant, M. W., Meijer, S. and Ahmed, M. (2003) Fish to 2020: Supply and Demand in Changing Global Markets. Washington DC: International Food Policy Research Institute.Google Scholar

Disney, J. G., Hoffman, A., Olley, J., Clucas, I. J., Barranco, A. and Francis, B. J. (1978) Development of a fish silage/carbohydrate animal feed for use in the tropics. Tropical Science, 20, 129–144.Google Scholar

Duray, M. N. (1998) Biology and Culture of Siganids. Tigbauan, Iloilo, Philippines: Aquaculture Department, Southeast Asian Fisheries Development Center.Google Scholar

Eaton, S. B., Konner, M. J., and Shostak, M. (1996) An evolutionary perspective enhances understanding of human nutritional requirements. The Journal of Nutrition (US), 126, 1732–1740.CrossRef Google Scholar PubMed

Edwards, P. (1980) Food potential of aquatic macrophytes. ICLARM Studies and Reviews. Manila, Philippines: ICLARM.Google Scholar

Edwards, P. (2004) Traditional Chinese aquaculture and its impact outside China. World Aquaculture, 35, 24–27.Google Scholar

Edwards, P. (2005) Development status of, and prospects for, wastewater-fed aquaculture in urban environments. In Costa-Pierce, B. A., Desbonnet, A., Edwards, P. and Baker, D., eds., Urban Aquaculture. Wallingford, UK: CABI Publishing.Google Scholar

Edwards, P. and Allen, G. (2004) Fish feeds and feeding in countries of the lower Mekong Basin. World Aquaculture, 35, 30–32.Google Scholar

Edwards, P., Little, D. C. and Demaine, H. (2002) Rural Aquaculture. Wallingford, UK: CABI Publishing.CrossRef Google Scholar

Edwards, P., Pullin, R. S. V. and Gartner, J. A. (1988) Research and education for the development of integrated crop-livestock-fish farming systems in the tropics. ICLARM Studies and Reviews, 16, 53.Google Scholar

Elvevoll, E. O. and James, D. G. (2000) Potential benefits of fish for maternal, foetal and neonatal nutrition: a review of the literature. Food, Nutrition and Agriculture, 27, 28–39.Google Scholar

,European Commission (2003) The use of Fish By-products in Aquaculture. Report of the Scientific Committee on Animal Health and Animal Welfare. Health and Consumer Protection Directorate-General. Brussels, Belgium: European Commission.Google Scholar

,FAO (1995) Code of Conduct for Responsible Fisheries. Rome: FAO.Google Scholar

,FAO (1997) Aquaculture Development. FAO Technical Guidelines for Responsible Fisheries. Rome: FAO.Google Scholar

,FAO (2002) Aquaculture Development and Management: status, issues, and prospects. Sub-Committee on Aquaculture, Committee on Fisheries. Rome: FAO.Google Scholar

,FAO (2005) APFIC Regional workshop on low value and “trash fish” in the Asia Pacific Region. Bangkok, Thailand, Regional Office for Asia and the Pacific, FAO.

,FAO (2006) Appendix G, Conference Declaration: Report of the International Conference on Agrarian Reform and Rural Development, Porto Alegre, Brazil. Rome: FAO.Google Scholar

,FAO (2008) The State of World Fisheries and Aquaculture 2008. Rome: FAO.Google Scholar

Fast, A. W. and Menasveta, P. (2003) Mangrove forest recovery in Thailand. World Aquaculture, 34, 6–9.Google Scholar

,FIN (1998) Fishmeal deserves a fair deal: there are no grounds for a ban. No problem feeding fishmeal to farmed fish, says SEAC. Fishmeal Information Network. Peterborough, UK: FIN, The Chamberlain Partnership.

Folke, C. (1988) Energy economy of salmon aquaculture in the Baltic Sea. Environmental Management, 12, 525–537.CrossRef Google Scholar

Folke, C. and Kautsky, N. (1992) Aquaculture with its environment: prospects for sustainability. Ocean and Coastal Management, 17, 5–24.CrossRef Google Scholar

Forster, J. (1999) Aquaculture chickens, salmon: a case study. World Aquaculture, 30, 33–40/69–70.Google Scholar

Froese, R. and Pauly, D. (2000) FishBase 2000: Concepts, Designs and Data Sources. Los Baños, Laguna, Philippines: ICLARM.Google Scholar

Funge-Smith, S., Lindebo, E., and Staples, D. (2005) Asian Fisheries Today: the Production and Use of Low Value/Trash Fish from Marine Fisheries in the Asia-Pacific Region. Bangkok: FAO.Google Scholar

Gardner-Thorpe, C. (2001) Who was … Frank Buckland? Biologist (London, England), 48, 187–188.Google Scholar

Gerking, S. D. (1994) Feeding Ecology of Fish. San Diego, CA: Academic Press.Google Scholar

Gill, C. (2005) World feed panorama: disease takes toll, but feed output bounces back. Feed International, 26, 4–9.Google Scholar

Goodland, R. (1997) Environmental sustainability in agriculture: diet matters. Ecological Economics, 23, 189–200.CrossRef Google Scholar

Halver, J. E. (1989) Fish Nutrition. New York: Academic Press.Google Scholar

Hasan, M. R. (2001) Nutrition and feeding for sustainable aquaculture development in the third millennium. In Subasinghe, R. P., Bueno, P., Phillips, M. J., et al., eds., Aquaculture in the Third Millenium (Technical Proceedings of the Conference on Aquaculture in the Third Millenium, Bangkok, Thailand, 20–25 February 2000). Rome: Network of Aquaculture Centres in Asia-Pacific, Bangkok and the Food and Agriculture Organization of the United Nations.Google Scholar

Hepher, B. (1988) Nutrition of Pond Fishes. Cambridge, UK: Cambridge University Press.CrossRef Google Scholar

Heras, H., Mcleod, C. A. and Ackman, R. G. (1994) Atlantic dogfish silage vs. herring silage in diets for Atlantic salmon (Salmo salar): growth and sensory evaluation of fillets. Aquaculture, 125, 93–106.CrossRef Google Scholar

Hong, W. S. and Zhang, Q. Y. (2001) The status of marine fish culture in China. World Aquaculture, 32, 18–20/67.Google Scholar

Hopkins, K. D., Hopkins, M. L. and Pauly, D. (1988) A multivariate model of fish growth, applied to tilapia seawater culture in Kuwait. In Pullin, R. S. V., Bhukasawan, T., Tonguthai, K., and MacLean, J. L., eds., Proceedings of the Second International Symposium on Tilapia in Aquaculture, 16–20 March 1987, Bangkok, Thailand. ICLARM Conference Proceedings 15. Manila, Philippines: ICLARM, pp. 29–39.Google Scholar

Hopkins, K. D. and Pauly, D. (1993) Instantaneous mortalities and multivariate models: applications to tilapia culture in saline water. Multivariate Methods in Aquaculture Research: Case Studies of Tilapias in Experimental and Commercial Systems. ICLARM Studies and Reviews. Manila, Philippines: ICLARM.Google Scholar

Hopkins, K., Pauly, D., Cruz, E. M. and Weerd, J. H. (1982) Recruitment control: an alternative to predator-prey ratios. Berichte der Deutschen Wissenschaftlichen Kommission für Meeresforschung, 29, 125–135.Google Scholar

Horn, M. H. (1989) Biology of marine herbivorous fishes. Oceanography and Marine Biology Annual Review, 27, 167–272.Google Scholar

,ICLARM–FAO (1999) Consensus Statement. In Pullin, R. S. V., Bartley, D. M. and Kooiman, J., eds., Towards Policies for Conservation and Sustainable Use of Aquatic Genetic Resources. Manila, Philippines: ICLARM, p. 253.Google Scholar

Jacinto, G. S., Azanza, R. V., Velasquez, L. B. and Siringan, F. P. (2006) Manila Bay: environmental challenges and opportunities. In Wolanski, E., ed., The Environment in Asia Pacific Harbours. Dordrecht, The Netherlands: Springer, pp. 309–328.CrossRef Google Scholar

Jystad, P. T. (2001) Fishmeal and oil or vegetable alternatives: will high volume production spoil premium fish production? IntraFish Industry Report.

Larsson, J., Folke, C. and Kautsky, N. (1994) Ecological limitations and appropriation of ecosystem support by shrimp farming in Colombia. Environmental Management, 18, 663–676.CrossRef Google Scholar

Lassen, T. J. (1997) Environmental extremes versus sustainable policies in aquaculture. World Aquaculture, 28, 49–51.Google Scholar

Lightfoot, C., Roger, P. A., Cagauan, A. G. and Dela Cruz, C. R. (1993) Preliminary steady-state nitrogen models of a wetland ricefield ecosystem with and without fish. In Christensen, V. and Pauly, D., eds., Trophic Models of Aquatic Ecosystems. ICLARM Conference Proceedings, 26. Manila, Philippines: ICLARM, pp. 56–64.Google Scholar

Lo, K. V., Liao, P. H., Bullock, C. and Jones, Y. (1993) Silage production from salmon farm mortalities. Aquaculture Engineering, 12, 37–45.CrossRef Google Scholar

Lubchenco, J. (2003) The blue revolution: a global ecological perspective. World Aquaculture, 34, 8–10.Google Scholar

Mair, G. C. and Pauly, D. (1993) A multivariate analysis of growth in juvenile tilapia (Oreochromis aureus and O. niloticus; Cichlidae) reared in recirculating systems. In Prein, M., Hulata, G. and Pauly, D., eds., Multivariate Methods in Aquaculture Research: Case Studies of Tilapias in Experimental and Commercial Systems. ICLARM Studies and Reviews. Manila, Philippines: ICLARM, pp. 97–104.Google Scholar

Martino, R. C., Trugo, L. C., Cyrino, E. P. and Portz, L. (2003) Use of white fat as a replacement for squid liver oil in practical diets for suribim, Pseudoplatystoma coruscans. Journal of the World Aquaculture Society, 34, 192–202.CrossRef Google Scholar

Mathias, J., Charles, A. T. and Bao-Tong, H. (1994) Integrated Fish Farming. Boca Raton, FL: CRC Press LLC.Google Scholar

Moffit, C. M. (2005) Environmental, economic and social aspects of animal protein production and the opportunities for aquaculture. Fisheries, 30, 36–38.Google Scholar

Moreau, J. and Pauly, D. (1999) A comparative analysis of growth performance in aquaculture of tilapia hybrids and their parent species. Asian Fisheries Science, 12, 91–103.Google Scholar

Moriarty, D. J. W. (1998) Control of luminous Vibrio species in penaeid aquaculture ponds. Aquaculture, 164, 351–358.CrossRef Google Scholar

Moriarty, D. J. W. and Pullin, R. S. V. (1987) Detritus and Microbial Ecology in Aquaculture. Manila, Philippines: ICLARM.Google Scholar

Msiska, O. V. and Costa-Pierce, B. A. (1993) History, Status and Future of Common Carp (Cyprinus carpio L.) in Malawi. Manila, Philippines: ICLARM.Google Scholar

Munro, J. L. and Heslinga, G. (1983) Prospects for the commercial cultivation of giant clams (Bivalvia: Tridachnidae). Proceedings of the Gulf and Caribbean Fisheries Institute, 35, 122–134.Google Scholar

Nandeesha, M. C. (2001) Farmers as scientists. Andra Pradesh fish farmers go into revolutionary carp research. Aquaculture Asia, VI, 29–32.Google Scholar

,National Renderers Association (NRA) (n.d.)The True Story of Meat and Bone Meal, Poultry Byproduct Meal, Feather Meal, Tallow, Poultry Fat, Yellow Grease. Hong Kong: Asian Regional Office, National Renderers Association, Inc.

,National Renderers Association (NRA) (2005) Pocket Information Manual. A Buyer's Guide to Rendered Products. Alexandria, VA: National Renderers Association, Inc.Google Scholar

,National Research Council (1977) Nutrient Requirements of Poultry. Washington DC: National Academy of Sciences.Google Scholar

Naylor, R. L., Goldburg, R. J., Primavera, J. H., Kautsky, N., Beveridge, M. C. M., Clay, J.Folke, C., Lubchenco, J., Mooney, H. and Troell, M. (2000) Effect of aquaculture on world fish supplies. Nature, 405, 1017–1024.CrossRef Google Scholar PubMed

New, M. B. (2002) Trends in Freshwater and Marine Aquaculture Production Systems. Production Systems in Fishery Management. Fisheries Centre Research Report. Vancouver, Canada: Fisheries Centre, University of British Columbia.Google Scholar

New, M. B., Tacon, A. G. J. and Csavas, I. (1993) Farm-made aquafeeds. Proceedings of the Regional Expert Conference on Farm-Made Aquafeeds. Bangkok, Thailand, Regional Office for Asia and the Pacific, Food and Agriculture Organization of the United Nations, and the ASEAN-EEC Aquaculture Development and Coordination Programme (AADCP).

Palomares, M. L. D. and Pauly, D. (1996) Models for estimating the food consumption of tilapias. In Pullin, R. S. V., Lazard, J., Legendre, M., Amon Kothias, J. B. and Pauly, D., eds., Proceedings of the Third International Conference on Tilapia in Aquaculture. Manila, Philippines: ICLARM, pp. 211–222.Google Scholar

Pauly, D. (1974) Report on the US Catfish Industry: Development, Research, Production Units, Marketing and Associated Industries. Neue Erkenntnisse auf dem Gebiet der Aquakultur. Arbeiten des Deutschen Fischereiverbandes, Heft.

Pauly, D. (1976) The biology, fishery and potential for aquaculture of Tilapia melanotheron in a small West African lagoon. Aquaculture, 7, 33–49.CrossRef Google Scholar

Pauly, D. (1981) The relationships between gill surface area and growth performance in fish: a generalization of von Bertalanffy's theory of growth. Berichte der Deutschen Wissenschaftlichen Kommission für Meeresforschung, 28, 251–282.Google Scholar

Pauly, D. (1994) Growth performance in fishes: descriptions and comparisons. On the Sex of Fish and the Gender of Scientists (Collected Essays in Fisheries Science). London: Chapman and Hall, pp. 61–66.Google Scholar

Pauly, D. (2010) Gasping Fish and Panting Squids: Oxygen, Temperature and the Growth of Water-breathing Animals. In Kinne, O., ed., Excellence in Ecology, 22. Oldendorf/Luhe, Germany: International Ecology Institute.Google Scholar

Pauly, D. and Christensen, V. (1995) Primary production required to sustain global fisheries. Nature, 374, 255–257.CrossRef Google Scholar

Pauly, D. and Hopkins, K. D. (1983) A method for the analysis of pond growth experiments. ICLARM Newsletter, 6 (1), 10–12.Google Scholar

Pauly, D., Moreau, J. and Palomares, M. L. (1988) Detritus and energy consumption and conversion efficiency of Sarotherodon melanotheron (Cichlidae) in a West African lagoon. Journal of Applied Ichthyology, 4, 150–153.CrossRef Google Scholar

Pauly, D., Muck, P., Mendo, J. and Tsukayama, I. (1989) The Peruvian Upwelling System: dynamics and interactions. Manila, Philippines: ICLARM.Google Scholar

Pauly, D. and Pullin, R. S. V. (1988) Hatching time in spherical, pelagic, marine fish eggs in response to temperature and egg size. Environmental Biology of Fishes, 22, 261–271.CrossRef Google Scholar

Pauly, D. and Pullin, R. S. V. (1997) The Egg Dev Table. FishBase ‘97. Concepts, Design and Data Sources. Manila, Philippines: ICLARM, pp. 154–158.Google Scholar

Pauly, D. and Tsukayama, I. (1987) The Peruvian anchoveta and its upwelling system: three decades of change. ICLARM Studies and Reviews, 15, 351.Google Scholar

Pauly, D. and Wade-Pauly, S. (1981) An annotated bibliography of slipmouths (Pisces: Leiognathidae). ICLARM Bibliographies. Manila, Philippines: ICLARM.Google Scholar

Pauly, D., Watson, R. and Alder, J. (2005) Global trends in world fisheries: impacts on marine ecosystems and food security. Philosophical Transactions of the Royal Society B, 360, 5–12.CrossRef Google Scholar PubMed

Peters, H. M. (1983) Fecundity, egg weight and oocyte development in tilapias (Cichlidae, Teleostei). Translated by Pauly, D.ICLARM Translations, 2, 28.

Popkin, B. M., Horton, S. H. and Kim, S. (2001) The Nutrition Transition and Prevention of Diet-related Diseases in Asia and the Pacific. Manila, Philippines: Asian Development Bank.Google Scholar

Prein, M., Hulata, G. and Pauly, D. (1993) On the use of multivariate statistical methods in aquaculture research. In Prein, M., Hulata, G. and Pauly, D., eds., Multivariate Methods in Aquaculture Research: Case Studies of Tilapias in Experimental and Commercial Systems. ICLARM Studies and Reviews. Manila, Philippines: ICLARM, pp. 1–11.Google Scholar

Prein, M. and Pauly, D. (1993) Two new approaches for examining multivariate aquaculture growth data: the “extended Bayley Plot” and path analysis. In Prein, M., Hulata, G., and Pauly, D., eds., Multivariate Methods in Aquaculture Research: Case Studies of Tilapias in Experimental and Commercial Systems. ICLARM Studies and Reviews. Manila, Philippines: ICLARM, pp. 32–49.Google Scholar

Pullin, R. S. V. (1986) Culture of herbivorous tilapias. In Chan, H. H., Ang, K. J., Law, A. T., Mohamed, M. I. H. and Omar, I. H., eds., Development and Management of Tropical Living Aquatic Resources. Selangor, Malaysia: Universiti Pertanian Malaysia, pp. 145–149.Google Scholar

Pullin, R. S. V. (2007) Genetic resources for aquaculture: status and trends. In Bartley, D. M., Harvey, B. J. and Pullin, R. S. V., eds., Status and Trends in Aquatic Genetic Resources: a Basis for International Policy. Rome: FAO.Google Scholar

Pullin, R. S. V., Froese, R. and Pauly, D. (2007) Indicators for the sustainability of aquaculture. In Bert, T. M., ed., Ecological and Genetic Implications of Aquaculture. Dordrecht, The Netherlands: Kluwer Academic Publishers, pp. 53–72.CrossRef Google Scholar

Pullin, R. S. V., Lazard, J., Legendre, M., Amon Kothias, J. B. and Pauly, D. (1996) Proceedings of the Third International Conference on Tilapia in Aquaculture. ICLARM Conference Proceedings. Manila, Philippines: ICLARM.Google Scholar

Pullin, R. S. V., Palomares, M. L., Casal, C. V., Dey, M. M. and Pauly, D. (1997) Environmental impacts of tilapias. In Fitzsimmons, K., ed., Tilapia Aquaculture: Proceedings from the Fourth International Symposium on Tilapia in Aquaculture. New York: Northeast Regional Agricultural Engineering Service Cooperative Extension, pp. 554–570.Google Scholar

Pullin, R. S. V., Rosenthal, H. and Maclean, J. L. (1993) Environment and aquaculture in developing countries. ICLARM Conference Proceedings. Manila, Philippines: ICLARM.Google Scholar

Rathbone, C. K. and Babbitt, J. K. (2000) Whitefish offals make great fish feeds. World Aquaculture, 31, 20–22.Google Scholar

Ruddle, K. and Christensen, V. (1993) An energy flow model of the mulberry dike-carp pond farming system of the Zhuijiang Delta, Guandong Province, China. In Christensen, V. and Pauly, D., eds., Trophic Models of Aquatic Ecosystems. ICLARM Conference Proceedings, 26. Manila, Philippines: ICLARM, pp. 48–55.Google Scholar

Rumsey, G. L. (1994) History of early diet development in fish culture, 1000 BC to AD 1955. The Progressive Fish Culturist, 56, 1–6.2.3.CO;2>CrossRef Google Scholar

Sadovy, Y. J., Donaldson, T. J., Graham, T. R., McGilvray, F., Muldoon, G. J., Phillips, M. J., Rimmer, M. A., Smith, A. and Yeeting, B. (2003) While Stocks Last: The Live Food Reef Fish Trade. Manila, Philippines: Asian Development Bank.Google Scholar

Schroeder, G. L. (1987) Carbon pathways in aquatic detrital systems. In Moriarty, D. J. W. and Pullin, R. S. V., eds., Detritus and Microbial Ecology in Aquaculture. ICLARM Conference Proceedings. Manila, Philippines: ICLARM, pp. 217–236.Google Scholar

,Science Council (2005) Conservation of Livestock and Fish Genetic Resources. Rome, Italy, Joint Report of Two Studies Commissioned by the CGIAR Science Council Secretariat, Consultative Group on International Agricultural Research.Google Scholar

Sugiyama, S., Staples, D. and Funge-Smith, S. (2004) Status and Potential of Fisheries and Aquaculture in Asia and the Pacific. Bangkok, Thailand, Regional Office for Asia and the Pacific, Food and Agriculture Organization of the United Nations.Google Scholar

Tacon, A. G. J. (1993) Feed ingredients for warmwater fish: fish meal and other processed feedstuffs. FAO Fisheries Circular, 856, 64.Google Scholar

Tacon, A. G. J., Hasan, M. R. and Subasinghe, R. P. (2006) Use of fishery resources as feed inputs for aquaculture development: trends and policy implications. FAO Fisheries Circular, 1018, 105.Google Scholar

Dam, A. A.Chikafumbwa, F. J. K. T., Jamu, D. M. and Costa-Pierce, B. A. (1993) Trophic interactions in a Napier grass (Pennisetum purpureum) fed aquaculture pond in Malawi. In Christensen, V. and Pauly, D., eds., Trophic Models of Aquatic Ecosystems. ICLARM Conference Proceedings, 26. Manila, Philippines: ICLARM, pp. 65–68.Google Scholar

Dam, A. A. and Pauly, D. (1995) Simulation of the effects of oxygen on food consumption and growth of Nile tilapia, Oreochromis niloticus (L.). Aquaculture Research, 26, 427–440.CrossRef Google Scholar

Watson, R. and Pauly, D. (2001) Systematic distortions in world fisheries catch trends. Nature, 414, 534–536.CrossRef Google Scholar PubMed

Watts, G. and Kennett, C. (1995) The Broiler Industry. Poultry Tribune, Centennial Edition. Mt. Morris, IL, USA: Watt Publishing.Google Scholar

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