Growth Rate and Chemical Muscle Composition of Oreochromis niloticus Fish Cultured in Drainage Water and Fed Antioxidant Supplemented Diet

Abstract

Irrigation of fish farms with agricultural drainage water may affect cultured fish species. So, the present study utilizes antioxidants supplemented diet to overcome deterioration of drainage water and its negative effect on fish. The studied groups are fish cultured in dechlorinated tap water as control group or drainage water and fed commercial basal diet. While, the other studied groups represented by Oreochromis niloticus fish cultured in drainage water and fed either commercial diet supplemented with vitamin C (5 g/kg diet) or fennel (5 g/kg diet) for 12 weeks. Results of the water physico-chemical parameters of all studied treatments revealed deterioration of the drainage water with a decrease in dissolved oxygen and an increase in pH, total hardness, total alkalinity, salinity, ammonia, nitrite and heavy metals (Cu, Pb and Cd) with significant differences (P ≤ 0.01) in comparison to that of the control dechlorinated tap water group. Data clarified also that Oreochromis niloticus cultured in drainage water showed a decrease in growth rate accompanied by deterioration of fish meat quality. However, fish reared in the same drainage water for the same exposure period and fed vitamin C or fennel supplemented basal diet (5 g/kg diet) recorded values of the studied parameters more or less similar to that of control group fish. Data of the present study, empowered aquaculturist to supplement fish rations with fennel or vitamin C as antioxidants to improve fish growth rate, meat quality as well as protect fish against heavy metals toxicity that could threat Human Being.

Share and Cite:

Zaghloul, K. , Abdel-Salam, S. , Aljilaney, S. and El-Dash, H. (2023) Growth Rate and Chemical Muscle Composition of Oreochromis niloticus Fish Cultured in Drainage Water and Fed Antioxidant Supplemented Diet. Natural Resources, 14, 149-160. doi: 10.4236/nr.2023.149011.

1. Introduction

Fish farms play an important role as an alternative solution for increasing fish yield. But, due to the regulation rules for use of water resources, fish farms which mainly established around El-Bats and El-Wadi drainage canals at Fayoum governorate, Egypt are allowed only to use water from the drainage network around [1] . Thus, these fish farms using agricultural drainage water may face the danger of negative effects on their cultured fish species [2] - [7] .

This drainage water is loaded with salts, nutrients, wastes, heavy metals and pesticides [5] [8] [9] [10] [11] and this may affect fish production, either directly or indirectly through their damaging effect on the vital organs of the body which in turn affect growth and meat quality [5] [6] [7] [12] [13] .

Hence application of an external source of antioxidants may offer some protection against oxidative stress. The term antioxidant refers to a wide spectrum of compounds, which are able to donate electrons and neutralize free radicals, resulting in the prevention of cell injuries [14] [15] [16] . In consequence, the search for effective, nontoxic, natural compounds with antioxidant activity has been intensified in recent years [17] [18] [19] [20] [21] .

Since, deterioration of drainage water used for fish culture without prior treatment is considered as a serious threat to aquatic life and hence become threaten to human being. So, the aim of present study is to follow up possible ameliorative effect of fish food additive antioxidants, fennel and vit C, for fish culture in drainage water. The main goal of the present investigation could be achieved by investigating quality of the drainage water and determine the concentrations of the most abundant heavy metals. Moreover, stand on the biological status including growth rate of Oreochromis niloticus fish fed normal commercial diet and that supplemented with the studied antioxidant (vit C or fennel). Furthermore, the study concerned with estimating meat quality of fish reared in the different studied treatments.

2. Materials and Methods

Experimental Design:

One hundred and eighty healthy Nile tilapia, Oreochromis niloticus, weighing about 50 g each, were retrieved from a fish farm in the Egyptian governorate of Fayoum. Fish were transported to the wet lab at the institute of fisheries and Oceanography, El-Fayoum station. Fish were distributed in twelve concrete aquaria with a 1000-liter capacity at a rate of fifteen fish per aquarium, divided into four groups of 45 fish each. To prevent metabolite buildup, water was replaced twice weekly. Fish were exposed to the following treatments for 12 weeks in order to monitor the effects of the drainage water on fish culture and possible ameliorative effect of diet supplementation with vitamin C or fennel as antioxidants.

Studied treatments:

Group I: Control group, fish reared in dechlorinated tap water and fed on

commercial basal diet

Group II: Fish reared in drainage water and fed commercial diet.

Group III: Fish reared in drainage water and fed vitamin c supplemented

commercial basal diet (5 g/kg diet)

Group IV: Fish reared in drainage water and fed fennel supplemented

commercial basal diet (5 g/kg diet).

Diet formulation:

The experimental fish ration was formulated according to Abdel-Tawwab and Abbass [18] . The main constituent of fish ration is crude protein, all diets contained 32% crude protein. The diet supplemented with 5 g vitamin C or 5 g fennel obtained from a local market for each kilogram diet.

Fish were fed twice daily at a rate of 3% of live body weight. Every two weeks, fish were weighed in order to monitor their rate of growth and alter their feed intake. At the end of experimental period (12 weeks), after which fish were sacrificed to acquire organ samples, and their muscles were chemically analyzed to determine their protein, lipid, ash, and moisture contents.

1) Physicochemical analysis of water

The water samples of the different studied treatments were subjected to a number of physicochemical analyses as mentioned later:

*Water pH and dissolved oxygen were measured in the field using Corning Checkmate II multi-parameter meter.

· Salinity was measured by using a salinity-conductivity meter (model, YSI 58).

· Total hardness and total alkalinity were measured by titration method according to the American Public Health Association standard methods [22] .

· Ammonia (NH3) was determined colorimetrically using Nessler’s solution as described by Sauter and Stoup [23] .

· Nitrite concentrations in water samples were measured by ion chromatography (IC) (model DX-600, USA) according to APHA [22] .

Figure 1. Experimental fish, Nile tilapia Oreochromis niloticus.

· Heavy metal (Copper, Lead, and Cadmium) concentrations in water were determined by atomic absorption spectrophotometer (Model, Perkin Elmer-2280) according to APHA [22] .

2) Growth indices

To optimize the artificial feed rate, fish body weights were measured to the nearest gram and total body length to the nearest 0.1 cm for the various study groups. The following growth indices were established at the end of exposure period (12 weeks).

*Specific growth rate:

Specific growth rate (growth rate/day) was determined according to the equation postulated by Allen and Wooton [24] :

S . G . R . = L n W f L n W o T f T o × 100

where:

Wf: The final weight of fish in g.

Wo: The initial weight of fish in g.

(Tf − To): Time between the final and initial weight in days.

*Condition factor (k):

K factor was calculated for individual fish from the formula recommended by Schreck and Moyle [25] :

K = W L 3 × 100

where:

W: is the wet weight in g., L: is the total length in cm.

3) Chemical muscle composition

a) Muscle water content

Sidwell et al., [26] method for determining muscle water content was used.

b) Muscle total protein

According to Josyln [27] , the semi-microkjeldahl method was used to assess muscle total protein.

c) Muscle total lipids

The common method described in A.O.A.C. [28] was used to determine the total lipid content of fish muscle.

d) Muscle ash

The samples were burned for 16 hours at 650˚C in a muffle furnace to estimate the amount of muscle ash [26] .

4) Statistical analysis

The results were statistically analyzed using analysis of variance (F-test) followed by Duncan's multiple range test to determine differences in means using Statistical Analysis Systems, Version 6.2 [29] .

3. Results and Discussion

Current population growth rates call into question humanity's ability to continue to ensure food security. With catches from natural fisheries stabilizing or even declining, aquaculture development projects are being initiated as part of the solution to meet growing protein demand. Fish farms play an important role as an alternative solution to increase fish production. Due to regulation of water use in El-Fayoum province, fish farms can only use water from the surrounding drainage network [1] . Therefore, these fish farms using agricultural drainage may be at risk of negative impacts on their farmed fish [2] [3] [4] . High concentrations of organic compounds, inorganic salts, and heavy metals from agricultural emissions may be responsible for the decreased dissolved oxygen content in the effluent in this study (Table 1). Hypoxia impairs fish survival and leads to fish death [30] [31] [32] . Spillage of organic matter decomposition into the water column can lead to severe dissolved oxygen depletion. In addition, microbial overgrowth in polluted water consumes more oxygen during respiration and may be caused by phytoplankton blooms [1] .

High ranges of drainage water ammonia and nitrite determined inside the current evaluation of water samples are in step with the ones of Lim et al. [33] , who observed extended ammonia and nitrite concentrations due to the release of

Table 1. Quality of water of the different studied treatments.

Data are represented as means of six samples ± S.E. N.D. = Not detectable. P.l. = Permissible level in water according to WHO (199). Means with the same letter for each parameter are not significantly different, otherwise they do, Duncan multiple range test (SAS, 2000). **Highly Significant difference (P < 0.01).

energetic pollutants from sewage, agricultural, and commercial effluents which have now not passed through enough and former remedy.

The ecological damage of the environment due to anthropogenic elements in addition to the presence of hazardous agents might also have an effect on fish subculture as well as its customers. Among the diverse poisonous pollutants, heavy metals represent a very thrilling group of elements because of their strong impact on balance of aquatic ecosystems, bioaccumulation in living organisms [34] [35] , toxicity patience and tendency to build up in water and sediments [36] .

Data concerning growth rates (fish weight gain percentage, specific growth rate and condition factor) of the studied Nile tilapia; Oreochromis niloticus revealed that fish fed commercial basal diet and cultured in the drainage water exhibited the lowest growth rate in comparison with the control group fish. However, the highest growth rates were recorded in fish fed 5 g fennel /kg diet followed by that of fish fed 5 g vit. C/kg diet.. Moreover, fish reared in drainage water and fed antioxidants supplemented diet revealed more or less growth rates similar to that of control group (Table 2).

The poisonous results of the various heavy metals in water samples may be the reason of the decrease values of the condition factor “k” of Oreochromis niloticus cultured within the drainage water and fed commercial basal diet. The same locating was previously made concerning fish that have been not able to thrive in infected aquatic environments [31] [32] [37] ; and/or low densities of both phytoplankton and zooplankton that may have been related to the decline in water quality, previously mentioned by way of Shaaban et al. [38] . However, high k

Table 2. Growth parameters of the Nile tilapia; Oreochromis niloticus reared in drainage water fed commercial basal diet and diet supplemented with vitamin C or fennel for 12 weeks.

Data are represented as means of fourty five fish ± S.E. Means within the same column, with the same letter for each parameter are not significantly different, otherwise they do (Duncan’s multiple range test, SAS 2000). **Highly significant difference (P < 0.01).

values helps the findings of Kheir et al. [39] , who connected the upward thrust in fish circumstance thing to more food intake introduced on with the aid of an expanded metabolism, reduced oxygen intake, and an increase in hormones.

Additionally, fish might need to detoxicate the metal and consequently require more energy, which might be a reason for fish weight reduction [40] . Furthermore, Carvalho et al. [41] demonstrated a correlation between decreased fish weight and the activation of metal detoxing mechanisms, inclusive of an increase in metallothionien ranges. Lanno, et al. [42] claimed that rainbow trout exposed to sublethal concentrations of copper skilled lack of appetite, which resulted in stunted boom.

According to Bonga and Lock [43] , water-born toxicants have an effect on the gills via making the gill epithelium extra permeable to water and ions and via inhibiting the chloride cells’ potential to trade ions. Reduced growth will take place from the fish’s compensatory responses, which might dramatically boom the strength had to hold water and ion balance.

The meat quality of fish cultured in agricultural drainage water deteriorated in the present investigation (Table 3). There were considerable increase inside the muscle’s water content and ash, in addition to considerable declines in the total protein and lipid content of the muscle. These findings corroborated the ones recognized by Zaghloul [44] and Elghobashy, et al. [45] , who recorded a decrease in muscle proteins and lipids of African catfish (Clarias gariepinus) and Nile tilapia (Oreochromis niloticus) subjected to high concentrations of heavy metals. Exposure of fish to high levels of heavy metals in the present study may be

Table 3. Meat quality of the Nile tilapia; Oreochromis niloticus reared in drainage water fed commercial basal diet and diet supplemented with vitamin C or fennel for 12 weeks.

Data are represented as means of six samples ± S.E. Means within the same column with the same letter for each parameter are not significantly different, otherwise they do (Duncan’s multiple range test, SAS 2000). **Highly Significant difference at P < 0.01.

responsible for the decrease in total protein and total lipids in the muscles of fish exposed to agricultural drainage water. According to earlier research by Reader et al., [46] these metals induce damage to the gill structure and a decrease in oxygen consumption, both of which result in a dramatic decrease in metabolic rate.

In the present study, fish cultured in drainage water and fed commercial basal diet supplemented with vitamin C or fennel (5 g/kg diet) restore growth rate and meat quality of Oreochromis niloticus to values more or less similar to that of the control group fish that cultured in dechlorinated tap water.

Hence utility of an external supply of antioxidants may additionally offer a few protection in opposition to oxidative stress. The term antioxidant refers to a huge spectrum of compounds, that are capable of donate electrons and neutralize loose radicals, ensuing inside the prevention of cellular injuries [14] [47] . In consequence, the look for powerful, secure, natural compounds with antioxidant activity has been intensified in current years [17] [21] [48] [49] .

In particular, fennel and vitamin c (Dietary supplemented antioxidants) have beneficial health effects that studied and established by the scientific community. However, there is little information about their protective roles against noxious effects caused by exposure to heavy metals, including those related to hepatic damage as well as other physiological status disturbances as previously reported [3] [5] [35] . The ameliorative effect of the studied antioxidants against heavy metals toxicity was very obvious in our study. This effect can be attributed to its scavenging ability of free radicals [50] [51] [52] [53] , as well as the reductive metabolites produced [54] .

Therefore, it may be concluded that Fish culture in drainage water induce reduction in growth rate and meat quality. Fennel or vitamin c individually improved and restore the biological status of fish, changes their ability to scavenge the toxic heavy metals and some reactive species, regenerate other antioxidants for protection.

Moreover, Data of the present study spot light on the role that should be taken by responsible authorities to follow up water quality irrigating fish farms. Moreover, empowered aquaculturist to supplement fish diet with antioxidants, fennel or vitamin C, that improve fish growth rate and meat quality as well as protect fish against heavy metals toxicity that could threat Human Being.

Conflicts of Interest

The authors declare no conflicts of interest regarding the publication of this paper.

References

[1] Konsowa, A.H. (2007) Ecological Studies on Fish Farms of El-Fayoum Depression (Egypt). The Egyptian Journal of Aquatic Research, 33, 290-300.
[2] Ali, M.H.H. and Abdel-Satar, A.M. (2005) Studies of Some Heavy Metals in Water, Sediment, Fish and Fish Diets in Some Fish Farms in El-Fayoum Province, Egypt. The Egyptian Journal of Aquatic Research, 31, 261-273.
[3] Zaghloul, K.H., Said, A.A., El-Sayad, S.M. and Ali, G.S. (2016) Role of Heavy Metals Bioaccumulation on Some Physiological and Histopathological Changes in the Cultured Oreochromis niloticus and Mugil cephalus at El-Fayoum Governorate, Egypt. Egyptian Journal of Zoology, 66, 167-188.
https://doi.org/10.12816/0034716
[4] Goher, M.E., Abdo, M.H., Bayoumy, W.A. and Mansour El-Ashkar, T.Y. (2017) Some Heavy Metal Contents in Surface Water and Sediment as a Pollution Index of El-Manzala Lake, Egypt. Journal of Basic and Environmental Sciences, 2, 210-225.
[5] Abdel-Khalek, A.A., Zayed, H.S., Elsayad, S.M. and Zaghloul, K.H. (2020) Assessment of Metal Pollution Impacts on Tilapia zillii and Mugil cephalus Inhabiting Qaroun and Wadi El-Rayan Lakes, Egypt, Using Integrated Biomarkers. Environmental Science and Pollution Research, 27, 26773-26785.
https://doi.org/10.1007/s11356-020-09095-3
[6] Briffa, J., Sinagra, E. and Blundell, R. (2020) Heavy Metal Pollution in the Environment and Their Toxicological Effects on Humans. Heliyon, 6, 24-26.
https://doi.org/10.1016/j.heliyon.2020.e04691
[7] Garai, P., et al. (2021) Effect of Heavy Metals on Fishes: Toxicity and Bioaccumulation. Journal of Clinical Toxicology, 11, 1-10.
[8] Abdel-Malek, S.A. and Khalil, M.T. (1994) Aquatic Habitat Diversity, 2. Lake Qaroun. In: Bishai, H.M., Ed., Biological Diversity of Egypt, UNEP and EEAA, National Biodiversity Unit, Cairo, Egypt, CF/6105-92-02-2205, 60.
[9] Javed, M. and Usmani, U. (2012) Uptake of Heavy Metals by Channa punctatus from Sewage-Fed Aquaculture Pond of Panethi, Aligarh. Global Journal of Researches in Engineering Chemical Engineering, 12, 27-34.
[10] Ali, H., Khan, E. and IIahi, I. (2019) Trophic Transfer, Bioaccumulation, and Biomagnification of Non-Essential Hazardous Heavy Metals and Metalloids in Food Chains/Webs—Concepts and Implications for Wildlife and Human Health. Human and Ecological Risk Assessment: An International Journal, 25, 1353-1376.
https://doi.org/10.1080/10807039.2018.1469398
[11] Hefmi, R., Baigo, H. and Alianto, A. (2019) Assessment of Water Quality and Pollution Index in Coastal Waters of Mimika, Indonesia. Journal of Ecological Engineering, 20, 87-94.
https://doi.org/10.12911/22998993/95266
[12] Kamel, S.A. and Fathalla, M.M. (1995) Histological Observations on the Gills, Livers and Ovaries of Some Fish Species in Lake Qaroun. Journal of Union of Arab Biologists, 4, 67-86.
[13] Abdel-Meguid, N., Kheirallah, A.M., Abou-Shabana, K.A. and Abdel-Moneim, A. (2002) Histochemical and Biochemical Changes in Liver of Tilapia zilii G. as a Consequence of Water Pollution. OnLine Journal of Biological Sciences, 2, 224-229.
https://doi.org/10.3923/jbs.2002.224.229
[14] Lobo, V., Patil, A., Phatak, A. and Chandra, N. (2010) Free Radicals, Antioxidants and Functional Foods: Impact on Human Health. Pharmacognosy Reviews, 4, 118-126.
https://doi.org/10.4103/0973-7847.70902
[15] Li, L.M., Zhang, Z.P. and Huang, Y.F. (2020) Integrative Transcriptome Analysis and Discovery of Signaling Pathways Involved in the Protective Effects of Curcumin against Oxidative Stress in Tilapia Hepatocytes. Aquatic Toxicology, 224, Article ID: 105516.
https://doi.org/10.1016/j.aquatox.2020.105516
[16] Ming, J.H., Ye, J.Y., Zhang, Y.X., Xu, Q.Y., Yang, X., Shao, X.P., Qiang, J. and Xu, P. (2020) Optimal Dietary Curcumin Improved Growth Performance, and Modulated Innate Immunity, Antioxidant Capacity and Related Genes Expression of NF-κB and Nrf2 Signaling Pathways in Grass Carp (Ctenopharyngodon idella) after Infection with Aeromonas hydrophila. Fish & Shellfish Immunology, 97, 540-553.
https://doi.org/10.1016/j.fsi.2019.12.074
[17] Negrette-Guzmán, M., Sara, H., Omar, N., Zyanya, L., Rogelio, H., Ismael, T., Edilia, T. and José, P. (2013) Sulforaphane Attenuates Gentamicin-Induced Nephrotoxicity: Role of Mitochondrial Protection. Evidence-Based Complementary and Alternative Medicine, 2013, Article ID: 135314.
https://doi.org/10.1155/2013/135314
[18] Abdel-Tawwab, M. and Abbass, E.F. (2017) Turmeric Powder, Curcuma longa L., in Common Carp, Cyprinus carpio L., Diets: Growth Performance, Innate Immunity, and Challenge against Pathogenic Aeromonas hydrophila Infection. Journal of the World Aquaculture Society, 48, 303-312.
https://doi.org/10.1111/jwas.12349
[19] Yonar, E.N., Yonara, S.M., İspirb, ü. and Ural, M.Ş. (2019) Effects of Curcumin on Haematological Values, Immunity, Antioxidant Status and Resistance of Rainbow Trout (Oncorhynchus mykiss) against Aeromonas. Fish and Shellfish Immunology, 89, 83-90.
https://doi.org/10.1016/j.fsi.2019.03.038
[20] Abd El-Hakim, Y.M., El-Houseinyb, W., EL-Murrb, A.E., Ebraheimc, L.L.M., et al. (2020) Melamine and Curcumin Enriched Diets Modulate the Haemato-Immune Response, Growth Performance, Oxidative Stress, Disease Resistance, and Cytokine Production in Oreochromis Niloticus. Aquatic Toxicology, 220, Article ID: 105406.
https://doi.org/10.1016/j.aquatox.2020.105406
[21] Kumari, P. and Paul, D.K. (2020) Bioremedial Effect of Turmeric (Curcuma longa) on Haematological and Biochemical Parameters against Fenvalerate Induced Toxicity in Air-Breathing Fish Clarias batrachus. International Journal of Aquaculture and Fishery Sciences, 6, 56-60.
https://doi.org/10.17352/2455-8400.000057
[22] APHA (2005) Standard Methods for the Examination of Water & Wastewater. American Public Health Association, Washington DC.
[23] Sauter, A. and Stoup, K. (1990) Waters and Salt. In: Helrich, K., Ed., AOAC Official Methods of Analysis, 15th Edition, Association of Official Analytical Chemists (AOAC) Inc., Arlington, Virginia, 1298 p.
[24] Allen, J.R.M. and Wootton, R.J. (1982) The Effect of Ration and Temperature on the Growth of the Three Spined Stickleback Gstrosteus aculeatus. Journal of Fish Biology, 20, 409-422.
https://doi.org/10.1111/j.1095-8649.1982.tb03934.x
[25] Schreck, C.B. and Moyle, P.B. (1990) Methods of Fish Biology. American Fisheries Society, Bethesda.
https://doi.org/10.47886/9780913235584
[26] Sidwell, V.D., Stillings, B.R. and Knobl, G.M. (1970) The Fish Protein Concentration. 10-Nutritional Quality and Use in Foods. Journal of Food Technology, 14, 40-46.
[27] Joslyn, M.A. (1950) Methods in Food Analysis. Academic Press, New York, Chapter 20.
[28] AOAC (Association of Official Agricultural Chemists) (1970) Official Methods of Analyses. Association Official Agricultural Chemists, Washington DC.
[29] SAS (2000) Statistical Analysis, SAS/STAT User’s Guide, Version 6.2. SAS Institute Inc., Cary.
[30] El-Naggar, G.O., Zaghloul, K.H., Salah El-Deen, M.A. and Abo-Hegab, S. (1998) Studies on the Effect of Industrial Water Pollution along Different Sites of the River Nile on Some Physiological and Biochemical Parameters of the Nile tilapia, Oreochromis niloticus. 4th Veterinary Medicine Zagazig Congress, Hurghada, 26-28 August 1998, 713-735.
[31] Haggag, A.M., Marie, M.A.S. and Zaghloul, K.H. (1999) Seasonal Effects of the Industrial Effluents on the Nile Catfish Clarias gariepinus. Journal of the Egyptian-German Society of Zoology, 28, 365-391.
[32] Salah El Deen, M.A., Zaghloul, H.K., El Naggar, G.O. and AboHegab, S. (1999) Concentrations of Heavy Metals in Water, Sediment and Fish in the River Nile in the Industrial Area of Helwan. Egyptian Journal of Zoology, 32, 373-395.
[33] Lim, W.Y., Aris, A.Z. and Praveena, S.M. (2012) Application of the Chemometric Approach to Evaluate the Spatial Variation of Water Chemistry and the Identification of the Sources of Pollution in Langat River, Malaysia. Arabian Journal of Geosciences, 6, 4891-4901.
https://doi.org/10.1007/s12517-012-0756-6
[34] Mansouri, B. and Baramaki, R. (2011) Influence of Water Hardness and pH on Acute Toxicity of Hg on Fresh Water Fish Capoeta fusca. World Journal of Fish and Marine Sciences, 3, 132.
[35] Abdel-Khalek, A.A., Elhaddad, E., Mamdouh, S. and Marie, M.-A.S. (2016) Assessment of Metal Pollution around Sabal Drainage in River Nile and Its Impacts on Bioaccumulation Level, Metals Correlation and Human Risk Hazard Using Oreochromis niloticus as a Bioindicator. Turkish Journal of Fisheries and Aquatic Sciences, 16, 227-239.
https://doi.org/10.4194/1303-2712-v16_2_02
[36] Has-Schon, E., Bogut, I. and Strelec, I. (2006) Heavy Metal Profile in Five Fish Species Included in Human Diet, Domiciled in the End Flow of River Neretva (Croatia). Archives of Environmental Contamination and Toxicology, 50, 545-551.
https://doi.org/10.1007/s00244-005-0047-2
[37] Clark, E.R. and Fraser, J.A.L. (1983) The Survival and Growth of Six Species of Freshwater Fishes in Tap Water, Diluted and Undiluted Effluents from Sewage Percolating Filters. Journal of Fish Biology, 22, 431-445.
https://doi.org/10.1111/j.1095-8649.1983.tb04765.x
[38] Shaaban, M.T., Khallaf, E.A.H., Nagdy, Z.A. and El-Gammal, M.A. (1999) Variation of Biological Dynamics and Physicochemical Fluctuations in Water of Fish Ponds Due to Different (Organic and Inorganic) Fertilizers Applications. 6th International Conference of Union Arab Biologists, Vol. 8, 293-313.
[39] Kheir, M.T., Mechail, M.M. and Abo-Hegab, S. (1998) Growth of Adult and Newly Hatched Fry of Oreochromis niloticus Reared at Different Saline Concentrations. Egyptian Journal of Zoology, 30, 107-115.
[40] Marr, J.C.A., et al. (1996) Relationship between Copper Exposure Duration, Tissue Copper Concentration, and Rainbow Trout Growth. Aquatic Toxicology, 36, 17-30.
https://doi.org/10.1016/S0166-445X(96)00801-6
[41] Carvalho, C.D., de Araujo, H.S.S. and Fernandes, M.N. (2004) Hepatic Metallothionein in a Teleost (Prochilodus scrofa) Exposed to Copper at pH 4.5 and pH 8.0. Comparative Biochemistry and Physiology, 137, 225-234.
https://doi.org/10.1016/j.cbpc.2003.11.004
[42] Bonga, W. and Lock, R.A.C. (1993) Toxicants and Osmoregulation in Fish. Netherlands Journal of Zoology, 42, 478-493.
https://doi.org/10.1163/156854291X00469
[43] Zaghloul, K.H. (2001) Usage of Zinc and Calcium in Inhibiting the Toxic Effect of Copper on the African Catfish, Clarias gariepinus. Journal of the Egyptian-German Society of Zoology, 35, 99-120.
[44] Lanno, R.P., Hickie, B.E. and Dixon, D.G. (1989) Feeding and Nutritional Considerations in Aquatic Toxicology. Hydrobiologia, 188, 525-531.
https://doi.org/10.1007/BF00027820
[45] Elghobashy, A.H., Zaghloul, K.H. and Metwally, M.A. (2001) Effect of Some Water Pollutants on the Nile tilapia; Oreochromis niloticus Collected from the River Nile and Some Egyptian Lakes. Egyptian Journal of Aquatic Biology and Fisheries, 5, 251-279.
https://doi.org/10.21608/ejabf.2001.1720
[46] Reader, J.P., Everall, N.C., Sayer, M.D.J. and Morris, R. (1989) The Effect of Eight Trace Metals in Acid Soft Water on Survival, Mineral Uptake and Skeletal Calcium Deposition in Yolk-Sac Fry of Brown Trout; Salmo trutta L. Journal of Fish Biology, 35, 187-197.
https://doi.org/10.1111/j.1095-8649.1989.tb02968.x
[47] Saeidnia, S. and Abdollahi, M. (2013) Toxicological and Pharmacological Concerns on Oxidative Stress and Related Diseases. Toxicology and Applied Pharmacology, 273, 442-455.
https://doi.org/10.1016/j.taap.2013.09.031
[48] Mişe Yonar, S., Yonar, M.E. and Ural, M.S. (2017) Antioxidant Effect of Curcumin against Exposure to Malathion in Cyprinus carpio. Cellular and Molecular Biology, 63, 68-72.
https://doi.org/10.14715/cmb/2017.63.3.13
[49] Xu, X.Y., Meng, X., Li, S., Gan, R.Y., Li, Y., et al. (2018) Bioactivity, Health Benefits, and Related Molecular Mechanisms of Curcumin: Current Progress, Challenges, and Perspectives. Nutrients, 10, Article No. 1553.
https://doi.org/10.3390/nu10101553
[50] Barros, L., Carvalho, A.M. and Ferreira, I.C. (2010) The Nutritional Composition of Fennel (Foeniculum vulgare): Shoots, Leaves, Stems and Inflorescences. LWT-Food Science and Technology, 43, 814-818.
https://doi.org/10.1016/j.lwt.2010.01.010
[51] Barros, M.M., Falcon, D.R., de Oliveira Orsi, R., Pezzato, L.E., Fernandes Jr., A.C., Guimaraes, I.G., Fernandes Jr., A., Padovani, C.R. and Sartori, M.M.P. (2014) Non-Specific Immune Parameters and Physiological Response of Nile tilapia Fed β-Glucan and Vitamin C for Different Periods and Submitted to Stress and Bacterial Challenge. Fish & Shellfish Immunology, 39, 188-195.
https://doi.org/10.1016/j.fsi.2014.05.004
[52] Gasco, L., Gai, F., Maricchiolo, G., Genovese, L., Ragonese, S., Bottari, T. and Caruso, G. (2018) Supplementation of Vitamins, Minerals, Enzymes and Antioxidants in Fish Feeds. In: Gasco, L., Gai, F., Maricchiolo, G., Genovese, L., Ragonese, S., Bottari, T. and Caruso, G., Eds., Feeds for the Aquaculture Sector: Current Situation and Alternative Sources, Springer International Publishing, Cham, 63-103.
https://doi.org/10.1007/978-3-319-77941-6_4
[53] Uzunhisarcikli, M. and Aslanturk, A. (2019) Hepatoprotective Effects of Curcumin and Taurine against Bisphenol A-Induced Liver Injury in Rats. Environmental Science and Pollution Research, 26, 37242-37253.
https://doi.org/10.1007/s11356-019-06615-8
[54] Pandey, A., Chaturvedi, M., Mishra, S., Kumar, P., et al. (2020) Reductive Metabolites of Curcumin and Their Therapeutic Effects. Heliyon, 6, 54-69.
https://doi.org/10.1016/j.heliyon.2020.e05469

Journals Menu
Follow SCIRP
Contact us
+1 323-425-8868
customer@scirp.org
WhatsApp +86 18163351462(WhatsApp)
Click here to send a message to me 1655362766
Paper Publishing WeChat

Copyright © 2024 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.