The influence of fish cage culture on
                        δ<sup>13</sup>C and δ<sup>15</sup>N of filter-feeding Bivalvia
                    (Mollusca)

Benedito, E.; Figueroa, L.; Takeda, A.M; Manetta, GI.

doi:10.1590/S1519-69842013000400009

Abstracts

The objective of this study was to evaluate the effect of Oreochromis niloticus cage culture promoted variations in the δ¹³C and δ¹⁵N in Corbicula fluminea (Mollusca; Bivalvia) and in the sediment of an aquatic food web. Samples were taken before and after net cage installation in the Rosana Reservoir (Paranapanema River, PR-SP). Samples of specimens of the bivalve filterer C. fluminea and samples of sediment were collected using a modified Petersen grab. All samples were dried in an oven (60 °C) for 72 hours, macerated to obtain homogenous fine powders and sent for carbon (δ¹³C) and nitrogen (δ¹⁵N) isotopic value analysis in a mass spectrometer. There were significant differences in the δ¹³C and δ¹⁵N values of the invertebrate C. fluminea between the beginning and the end of the experiment. There were no differences between the δ¹³C and δ¹⁵N values of sediment. These results indicate that the installation of fish cage culture promoted impacts in the isotopic composition of the aquatic food web organisms, which could exert influence over the native species and the ecosystem.

Corbicula fluminea ; sediment; stable isotopes

O objetivo deste estudo foi avaliar o efeito do cultivo de Oreochromis niloticus em tanques rede sobre os valores de δ¹³C e δ¹⁵N em tecidos Corbicula fluminea (Mollusca; Bivalvia) e no sedimento da cadeia alimentar aquática. As amostragens foram realizadas em períodos prévios e posteriores a instalação de tanques redes no reservatório de Rosana (Rio Paranapanema, PR-SP). As amostras de espécimes de bivalves filtradores exóticos e as de sedimento foram coletadas utilizando uma versão modificada do pegador tipo Petersen. Todas as amostras foram secas em estufa (60 °C) durante 72 horas, maceradas até obtenção de pó fino e homogêneo e enviadas para determinação do carbono (¹³C) e do nitrogênio (¹⁵N) em espectrofotômetro de massa. Houve diferenças significativas nos valores δ¹³C e δ¹⁵N do invertebrado C. fluminea entre o início e o fim do experimento. Entretanto, não foram evidenciadas diferenças nos valores δ¹³C e δ¹⁵N presente no sedimento. Estes resultados demonstram que a instalação dos tanques rede promoveram impactos na composição isotópica do invertebrado, que podem influenciar as espécies nativas e o ecossistema.

1.

Introduction

In recent years, some reservoirs have been used for fish farming using net cages. This activity has been growing on a large scale in Brazil (Agostinho et al., 2007AGOSTINHO, AA., GOMES, LC. and PELICICE, FM., 2007. Ecologia e manejo de recursos pesqueiros em Reservatórios do Brasil. Maringá: EDUEM. 501p.). However, several studies have shown that the installation of fish cage cultures promotes changes, of varying intensity, to the environment due to the eutrophication processes that they generate (Tundisi and Henry, 1986TUNDISI, JG. and HENRY, R., 1986. Effects of enrichment on the summer surface phytoplanktonic community in a stratified tropical lake. Brasilian Journal of Biology, vol. 46, no. 1, p. 231-237.; Agostinho et al., 2007AGOSTINHO, AA., GOMES, LC. and PELICICE, FM., 2007. Ecologia e manejo de recursos pesqueiros em Reservatórios do Brasil. Maringá: EDUEM. 501p.), causing variations in the quantity and availability of food in the ecosystem (Strictar-Pereira et al., 2010STRICTAR-PEREIRA, L., AGOSTINHO, AA. and GOMES, LC., 2010. Cage culture with tilapia induces alteration in the diet of natural fish populations: the case of Auchenipterus osteomystax. Brasilian Journal of Biology, vol. 70, no. 4, p. 1021-1030.). Cage cultures can to promote intensification of nutrient input, from both uneaten feed and the release of faeces and ammonia excretion (Troell and Berg 1997TROELL, M. and BERG, H., 1997. Cage fish farming in the tropical lake Kariba, Zimbabwe: impacts and biogeochemical changes in sediments. Aquaculture Research, vol. 28, 527-544.), leading to proliferation of algae in adjacent areas and, therefore, changes in various communities, such as zoo-plankton (Dias et al., 2012DIAS, JD., SIMÕES, NR, and BONECKER, CC., 2012. Zooplankton community resilience and aquatic environmental stability on aquaculture practices: a study using net cages. Brazilian Journal of Biology, vol. 72, p. 1-11.) and zoobenthos (Guo and Li, 2003GUO, L. and LI, LZ., 2003. Effects of nitrogen and phosphorus from fish cageculture on the communities of a shallow lake in middle Yangtze basin of China. Aquaculture, vol. 226, p. 201-212.).

Corbicula fluminea (Müller, 1774) (Mollusca; Bivalvia) is an exotic species from Southeast Asia. This invertebrate species was chosen because it is a filter-feeding mollusc that strongly influences the aquatic ecosystem, since it obtains its energy directly from primary producers, transferring it to other links of the trophic chain, including some species of fishes, aquatic birds and mammals (McMahon, 2000MCMAHON, RF., 2000. Characteristics invasives of the freshwater bivalve, Corbicula fluminea. In CLAUDI, R. and Leach, JH. (Eds.). Nonindigenous Freswater organisms: vectors, biology and impacts. New York: Lewis Publisher. p. 315-346.).

The use of stable isotopes in ecological studies is an important tool for tracing the path of organic matter, and its variation, through food webs (Vander Zanden et al., 2003VANDER ZANDEN, MJ., CHANDRA, S., ALLEN, B., REUTER, JE. and GOLDMAN, CR., 2003. Historical Food web structure and restoration of native aquatic communities in the Lake Tahoe (California-Nevada) basin. Ecosystems, vol. 6, p. 274-288., Schmidt et al., 2007SCHMIDT, SN., OLDEN, JD., SOLOMON, CT. and VANDER ZANDEN, MJ., 2007. Quantitative approaches to the analysis of stable isotope food web data. Ecology, vol. 88, no. 11, p. 2793-2802.). The carbon stable isotope ratio (δ¹³C) of an organism reflects the small enrichments that occur along the food chain (from 0.2 to 1‰ for each trophic level), and is used to identify the carbon sources of the consumers (De Niro and Epstein, 1981DE NIRO, ML. and EPSTEIN, S., 1981. Influence of diet on the distribution of nitrogen isotopes in animals. Geochimica et Cosmochimica Acta, vol.45, p. 341-351.). The nitrogen (δ¹⁵N) stable isotope ratio undergoes an enrichment of about 3-4‰ between the tissues of the prey and predator, reflecting the preferential excretion of the lighter isotope during metabolisation and providing a means of measuring consumer trophic position (Minagawa and Wada, 1984MINAGAWA, M. and WADA, E., 1984. Stepwise enrichment of 15N along food chains: further evidence and the relation between δ15N and animal age. Geochimica et Cosmochimica Acta, vol. 48, p. 1135-1140.).

Fish cage cultures could influence the energy sources and affect the trophic structures of their ecosystems through the addition of organic waste. Within this context, the objective of this study was to assess whether the fish cage culture promoted variations in the δ¹³C and δ¹⁵N on the filter-feeding species Corbicula fluminea (Mollusca, Bivalvia) and in the sediment of an aquatic food web.

2.

Material and Methods

2.1.

Area of study

This study was conducted along with the experimental cage production of tilapia Oreochromis niloticus (Linnaeus, 1758) in the Corvo streams (22°38′19″ S and 52°47′16″ W), in the Rosana Reservoir, low Paranapanema River, one of the main tributaries from the left margin of the Paraná River (Figure 1). Corvo streams show the margins with grasses and initial stages of reforestation, have banks of aquatic macrophytes and are greatly affected by wind. The abiotic factors that had the greatest influence during the experiment were nitrate, organic matter, ammonia and total nitrogen.

Figure 1 -
Map of the Rosana Reservoir, indicating the location of the net cages in the Corvo River (•).

Fifteen net cages were used in the experimental design, each one 2 × 2 × 1.7 m, resulting in a volume of 6 m³. The average stocking density of the Oreochromis niloticus was 150 fish per m^–3. The initial amount of fish food was estimated at 10% of the total biomass of the net cage and was established by the technique of providing ad libidum. This was regulated by observations of the consumption of all the food in the first hour after offered. Fishes were fed twice a day at 10:00 and 16:00 h, with commercial extruded fish food containing crude soybean protein, in which the isotopic values of carbon and nitrogen, previously analysed, were -19.9‰ ± 0.3 and 4.5 ± 0.1‰, respectively.

Invertebrate samples and sediment were taken in April 2006, before the beginning of the experiment and in the end of the experiment in August 2006. Ten samples of specimens of filter-feeding bivalve Corbicula fluminea (Müller, 1774) were taken in each period from the sediment below the cages using a modified Petersen grab (0.018 m² area); samples were collected below the culture cages. The bodies were separated from the valves in the laboratory. Three samples of sediment were also taken using a modified Petersen grab.

Invertebrate samples and sediment were dried in an oven (60 °C) for 72 hours, macerated to obtain homogeneous fine powders and were sent to the Center for Stable Isotopes (CIE), at the State University Paulista (UNESP) in Botucatu, for carbon (δ¹³C) and nitrogen (δ¹⁵N) isotopic value analysis using a mass spectrometer.

2.2.

Data analysis

To test possible differences in the values of δ¹³C and δ¹⁵N at the beginning and the end of the farming period, the isotope values were submitted to a Mann-Whitney non parametric test for independent samples. Statistica for Windows 7.1 (Statsoft Inc. 2005) was used to carry out the analysis. The sediment could not be tested due to the low number of samples.

3.

Results

The Mann-Whitney test evidenced that there were significant differences in the δ¹³C values of the invertebrate C. fluminea (Z = - 2.39; p < 0.016) between the beginning and the end of the experiment, with enrichments in δ¹³C values. There were no differences between the δ¹³C values of sediment (Figure 2).

Figure 2 -
Bi-plot showing the mean values and standard deviation of δ¹³C and δ¹⁵N in April (A) and August (B). Where Cf = C. fluminea; Se = Sediment, R = Fish food.

Corbicula fluminea also showed significant variability in the δ¹⁵N values between the two sampling periods (Z = 2.39; p < 0.016), increasing from 9.3 to 11.7‰, while the sediment did not present differences for this element.

4.

Discussion

This study identified changes in the δ¹³C values of the organisms between the beginning and end of the experiment period: environmental changes due to the installation of net cages (Penczak et al., 1982PENCZAK, T., GALICKA, W., MOLINSKI, M., KUSTO, E. and ZALEWSKI, M., 1982. The enrichment of a mesotrophic lake by carbon, phosphorus and nitrogen from the cage aquaculture of rainbow trout, Salmo gairdneri. Journal of Applied Ecology, vol. 19, p. 371-393.). Considering that this invertebrate C. fluminea is filter-feeding and that phytoplankton show the most depleted values among the producers (Araujo-Lima et al., 1986ARAUJO-LIMA, CARM., FORSBERG, BR., VICTORIA, RL. and MARTINELLI, L., 1986. Energy sources for detritivorous fishes in the Amazon. Science, vol. 234, p. 1256-1258.; Manetta et al., 2003MANETTA, GI., BENEDITO-CECILIO, E. and MARTINELLI, LA., 2003. Carbon sources and trophic position of the main species of fishes of Baía river, Paraná river floodplain. Brazilian Journal of Biology, vol. 63, no. 2, p. 283-290., Lopes and Benedito-Cecilio, 2002LOPES, CA. and BENEDITO-CECILIO, E., 2002. Variabilidade isotópica (δ13C e δ15N) em produtores primários terrestres e de água doce. Acta Scientiarum, vol. 24, no. 2, p. 303-312.), it is assumed that the negative isotopic values of C. fluminea at the beginning of the experiment were related to the use of phytoplankton as a source of energy. However, at the end of the experiment, it was found that C. fluminea showed high isotopic variation, with significant enrichment in δ¹³C values (∼6‰). This change in the isotopic compositions could be related to the influence of allochthonous material in the trophic web in the river and with the soybean content of the commercial fish food as responsible for the enrichment in δ¹³C values.

The sediment, in turn, consists of organic matter derived from C₃ (perifiton and macrophytes) and C₄ plants. However, in this study, the δ¹³C isotopic compositions of sediment showed no variations between the two periods of study. Thus, although there is a constant input of enriched carbon isotope, due to the fish food, the absence of changes in the isotopic compositions sediment could be related with the current of the river that must have taken the feed or diluted it, not interfering in the sediment isotope values.

With respect to the δ¹⁵N values, it was found that the specie C. fluminea had depleted final values compared to those found at the beginning of the experiment. It can be assumed that the producers of the ecosystem assimilated much lighter isotope nitrogen from the fish food. Producers that assimilate nitrate show more enriched δ¹⁵N values than those that use NH₄ (Pennock et al., 1996). This is because nitrate is exposed to fractionation for less time (Robinson, 2001ROBINSON, D., 2001. δ15N as an integrator of the nitrogen cycle. Trends in Ecology Evolution, vol. 16, no. 3, p. 153-162.). Furthermore, the fish cage culture changes the water conditions due to the input of nutrients, which raises the levels of certain compounds, such as NH₄ (Beveridge, 1987BEVERIDGE, MCM., 1987. Cage aquaculture. Oxford: Fishing News Books.; Troell and Berg, 1997TROELL, M. and BERG, H., 1997. Cage fish farming in the tropical lake Kariba, Zimbabwe: impacts and biogeochemical changes in sediments. Aquaculture Research, vol. 28, 527-544.). High levels of NH₄ can alter the isotopic values of producers, such as C₃ plants. This, in turn, could alter the isotopic values of the other taxonomic groups, as was observed in this study. According to Grey et al. (2001)GREY, J., JONES, RI. and SLEEP, D., 2001. Seasonal changes in the importance of the source of organic matter to the diet of zooplankton in Loch Ness, as indicated by stable isotope analysis. Limnology and Oceanography, vol. 46, no. 3, p. 505-513., changes in the isotopic compositions of organisms may also be related to seasonal changes in diet and the input of allochthonous sources to the system. These factors affect the determination of the extent of isotopic fractionation and, consequently, the isotopic variability of the organisms.

As for sediment, no differences were found between the δ¹⁵N isotopic compositions for the two periods of study, although a tendency of depletion was observed. This lack of variation, as mentioned above for δ¹³C, may be due to the great influence of allochthonous material.

Thus, it can be concluded that the input of organic material and nutrient in areas of caging aquaculture, produce variations in the river food web indirectly, through fish food, promoting differences in the carbon and nitrogen isotopic compositions of C. fluminea. In this sense, for the expansion of aquaculture, it is important to ensure healthy freshwater ecosystems, and the fish cultivation in net cages in reservoirs should be subject of suitable management, permanent monitoring and more studies that evaluate impacts of net cages (Borges et al., 2010BORGES, PAF., TRAIN, S., DIAS, JD. and BONECKER, CC., 2010. Effects of fish farming on plankton structure in a Brazilian tropical reservoir. Hydrobiologia, vol. 649, p. 279-291.).

The authors would like to thank PRONEX and the Ecology of Continental Aquatic Ecosystems Program of the State University of Maringa (UEM) for financial and logistical support, Anna Christina Esper Amaro de Faria and Angelo Antonio Agostinho for valuable suggestions, Jaime Luiz Lopes Pereira for drawing the map and CNPq.

References

AGOSTINHO, AA., GOMES, LC. and PELICICE, FM., 2007. Ecologia e manejo de recursos pesqueiros em Reservatórios do Brasil. Maringá: EDUEM. 501p.
ARAUJO-LIMA, CARM., FORSBERG, BR., VICTORIA, RL. and MARTINELLI, L., 1986. Energy sources for detritivorous fishes in the Amazon. Science, vol. 234, p. 1256-1258.
BEVERIDGE, MCM., 1987. Cage aquaculture. Oxford: Fishing News Books.
BORGES, PAF., TRAIN, S., DIAS, JD. and BONECKER, CC., 2010. Effects of fish farming on plankton structure in a Brazilian tropical reservoir. Hydrobiologia, vol. 649, p. 279-291.
DE NIRO, ML. and EPSTEIN, S., 1981. Influence of diet on the distribution of nitrogen isotopes in animals. Geochimica et Cosmochimica Acta, vol.45, p. 341-351.
DIAS, JD., SIMÕES, NR, and BONECKER, CC., 2012. Zooplankton community resilience and aquatic environmental stability on aquaculture practices: a study using net cages. Brazilian Journal of Biology, vol. 72, p. 1-11.
GREY, J., JONES, RI. and SLEEP, D., 2001. Seasonal changes in the importance of the source of organic matter to the diet of zooplankton in Loch Ness, as indicated by stable isotope analysis. Limnology and Oceanography, vol. 46, no. 3, p. 505-513.
GUO, L. and LI, LZ., 2003. Effects of nitrogen and phosphorus from fish cageculture on the communities of a shallow lake in middle Yangtze basin of China. Aquaculture, vol. 226, p. 201-212.
LOPES, CA. and BENEDITO-CECILIO, E., 2002. Variabilidade isotópica (δ13C e δ15N) em produtores primários terrestres e de água doce. Acta Scientiarum, vol. 24, no. 2, p. 303-312.
MANETTA, GI., BENEDITO-CECILIO, E. and MARTINELLI, LA., 2003. Carbon sources and trophic position of the main species of fishes of Baía river, Paraná river floodplain. Brazilian Journal of Biology, vol. 63, no. 2, p. 283-290.
MINAGAWA, M. and WADA, E., 1984. Stepwise enrichment of 15N along food chains: further evidence and the relation between δ15N and animal age. Geochimica et Cosmochimica Acta, vol. 48, p. 1135-1140.
MCMAHON, RF., 2000. Characteristics invasives of the freshwater bivalve, Corbicula fluminea. In CLAUDI, R. and Leach, JH. (Eds.). Nonindigenous Freswater organisms: vectors, biology and impacts. New York: Lewis Publisher. p. 315-346.
PENNOCK, JR, VELINSKY, DJ., LUDLAM, JM., SHARP, JH. and FOGEL, ML., 1996. Isotopic fractionation of ammonium and nitrate during uptake by Skeletonema costatum: implications for δ15N dynamics under bloom conditions. Limnology and Oceanography, vol. 32, p. 1195-1213.
PENCZAK, T., GALICKA, W., MOLINSKI, M., KUSTO, E. and ZALEWSKI, M., 1982. The enrichment of a mesotrophic lake by carbon, phosphorus and nitrogen from the cage aquaculture of rainbow trout, Salmo gairdneri. Journal of Applied Ecology, vol. 19, p. 371-393.
ROBINSON, D., 2001. δ15N as an integrator of the nitrogen cycle. Trends in Ecology Evolution, vol. 16, no. 3, p. 153-162.
SCHMIDT, SN., OLDEN, JD., SOLOMON, CT. and VANDER ZANDEN, MJ., 2007. Quantitative approaches to the analysis of stable isotope food web data. Ecology, vol. 88, no. 11, p. 2793-2802.
STRICTAR-PEREIRA, L., AGOSTINHO, AA. and GOMES, LC., 2010. Cage culture with tilapia induces alteration in the diet of natural fish populations: the case of Auchenipterus osteomystax. Brasilian Journal of Biology, vol. 70, no. 4, p. 1021-1030.
STATSOFT, 2005. STATISTICA (data analysis software system), version 7.1. Available from: www.statsoft.com.
» www.statsoft.com
TROELL, M. and BERG, H., 1997. Cage fish farming in the tropical lake Kariba, Zimbabwe: impacts and biogeochemical changes in sediments. Aquaculture Research, vol. 28, 527-544.
TUNDISI, JG. and HENRY, R., 1986. Effects of enrichment on the summer surface phytoplanktonic community in a stratified tropical lake. Brasilian Journal of Biology, vol. 46, no. 1, p. 231-237.
VANDER ZANDEN, MJ., CHANDRA, S., ALLEN, B., REUTER, JE. and GOLDMAN, CR., 2003. Historical Food web structure and restoration of native aquatic communities in the Lake Tahoe (California-Nevada) basin. Ecosystems, vol. 6, p. 274-288.

Publication Dates

Publication in this collection
Nov 2013

History

Received
3 July 2012
Accepted
26 Oct 2012

This is an Open Access article distributed under the terms of the Creative Commons Attribution Non-Commercial License, which permits unrestricted non-commercial use, distribution, and reproduction in any medium, provided the original work is properly cited.

[1] AGOSTINHO, AA., GOMES, LC. and PELICICE, FM., 2007. Ecologia e manejo de recursos pesqueiros em Reservatórios do Brasil. Maringá: EDUEM. 501p.

[2] ARAUJO-LIMA, CARM., FORSBERG, BR., VICTORIA, RL. and MARTINELLI, L., 1986. Energy sources for detritivorous fishes in the Amazon. Science, vol. 234, p. 1256-1258.

[3] BEVERIDGE, MCM., 1987. Cage aquaculture. Oxford: Fishing News Books.

[4] BORGES, PAF., TRAIN, S., DIAS, JD. and BONECKER, CC., 2010. Effects of fish farming on plankton structure in a Brazilian tropical reservoir. Hydrobiologia, vol. 649, p. 279-291.

[5] DE NIRO, ML. and EPSTEIN, S., 1981. Influence of diet on the distribution of nitrogen isotopes in animals. Geochimica et Cosmochimica Acta, vol.45, p. 341-351.

[6] DIAS, JD., SIMÕES, NR, and BONECKER, CC., 2012. Zooplankton community resilience and aquatic environmental stability on aquaculture practices: a study using net cages. Brazilian Journal of Biology, vol. 72, p. 1-11.

[7] GREY, J., JONES, RI. and SLEEP, D., 2001. Seasonal changes in the importance of the source of organic matter to the diet of zooplankton in Loch Ness, as indicated by stable isotope analysis. Limnology and Oceanography, vol. 46, no. 3, p. 505-513.

[8] GUO, L. and LI, LZ., 2003. Effects of nitrogen and phosphorus from fish cageculture on the communities of a shallow lake in middle Yangtze basin of China. Aquaculture, vol. 226, p. 201-212.

[9] LOPES, CA. and BENEDITO-CECILIO, E., 2002. Variabilidade isotópica (δ13C e δ15N) em produtores primários terrestres e de água doce. Acta Scientiarum, vol. 24, no. 2, p. 303-312.

[10] MANETTA, GI., BENEDITO-CECILIO, E. and MARTINELLI, LA., 2003. Carbon sources and trophic position of the main species of fishes of Baía river, Paraná river floodplain. Brazilian Journal of Biology, vol. 63, no. 2, p. 283-290.

[11] MINAGAWA, M. and WADA, E., 1984. Stepwise enrichment of 15N along food chains: further evidence and the relation between δ15N and animal age. Geochimica et Cosmochimica Acta, vol. 48, p. 1135-1140.

[12] MCMAHON, RF., 2000. Characteristics invasives of the freshwater bivalve, Corbicula fluminea. In CLAUDI, R. and Leach, JH. (Eds.). Nonindigenous Freswater organisms: vectors, biology and impacts. New York: Lewis Publisher. p. 315-346.

[13] PENNOCK, JR, VELINSKY, DJ., LUDLAM, JM., SHARP, JH. and FOGEL, ML., 1996. Isotopic fractionation of ammonium and nitrate during uptake by Skeletonema costatum: implications for δ15N dynamics under bloom conditions. Limnology and Oceanography, vol. 32, p. 1195-1213.

[14] PENCZAK, T., GALICKA, W., MOLINSKI, M., KUSTO, E. and ZALEWSKI, M., 1982. The enrichment of a mesotrophic lake by carbon, phosphorus and nitrogen from the cage aquaculture of rainbow trout, Salmo gairdneri. Journal of Applied Ecology, vol. 19, p. 371-393.

[15] ROBINSON, D., 2001. δ15N as an integrator of the nitrogen cycle. Trends in Ecology Evolution, vol. 16, no. 3, p. 153-162.

[16] SCHMIDT, SN., OLDEN, JD., SOLOMON, CT. and VANDER ZANDEN, MJ., 2007. Quantitative approaches to the analysis of stable isotope food web data. Ecology, vol. 88, no. 11, p. 2793-2802.

[17] STRICTAR-PEREIRA, L., AGOSTINHO, AA. and GOMES, LC., 2010. Cage culture with tilapia induces alteration in the diet of natural fish populations: the case of Auchenipterus osteomystax. Brasilian Journal of Biology, vol. 70, no. 4, p. 1021-1030.

[18] STATSOFT, 2005. STATISTICA (data analysis software system), version 7.1. Available from: www.statsoft.com.
» www.statsoft.com

[19] TROELL, M. and BERG, H., 1997. Cage fish farming in the tropical lake Kariba, Zimbabwe: impacts and biogeochemical changes in sediments. Aquaculture Research, vol. 28, 527-544.

[20] TUNDISI, JG. and HENRY, R., 1986. Effects of enrichment on the summer surface phytoplanktonic community in a stratified tropical lake. Brasilian Journal of Biology, vol. 46, no. 1, p. 231-237.

[21] VANDER ZANDEN, MJ., CHANDRA, S., ALLEN, B., REUTER, JE. and GOLDMAN, CR., 2003. Historical Food web structure and restoration of native aquatic communities in the Lake Tahoe (California-Nevada) basin. Ecosystems, vol. 6, p. 274-288.

Brasil

Brasil

The influence of fish cage culture on δ¹³C and δ¹⁵N of filter-feeding Bivalvia (Mollusca)

A influência dos tanques rede sobre o δ¹³C e δ¹⁵N de uma espécie filtradora Bivalvia (Mollusca)

Abstracts

Introduction

Material and Methods

Area of study

Data analysis

Results

Discussion

References

Publication Dates

History

Brasil

Brasil

The influence of fish cage culture on δ13C and δ15N of filter-feeding Bivalvia (Mollusca)

A influência dos tanques rede sobre o δ13C e δ15N de uma espécie filtradora Bivalvia (Mollusca)

Abstracts

Introduction

Material and Methods

Area of study

Data analysis

Results

Discussion

References

Publication Dates

History

The influence of fish cage culture on δ¹³C and δ¹⁵N of filter-feeding Bivalvia (Mollusca)

A influência dos tanques rede sobre o δ¹³C e δ¹⁵N de uma espécie filtradora Bivalvia (Mollusca)