Growth And Survival Of The White Leg Shrimp (Litopenaeus Vannamei) Reared Intensively In The Brackish Water Of The Israeli Negev Desert

Appelbaum, Samuel; Garada, J.; Mishra, Jeet K.

doi:10.46989/001c.20313

Cited by 7 publications

(4 citation statements)

References 5 publications

(2 reference statements)

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“…These results are in agreement with Arambul‐Muñoz et al (2019), Gao et al (2017), Yu et al (2009) and Williams et al (1996). Similar observations have been reported for studies of L. vannamei and P. setiferus (Araneda et al, 2008; Williams et al, 1996) Consistent results have also observed similar patterns measuring different independent factors such as salinity and temperature (Appelbaum et al, 2002; Davis & Arnold, 1998; Roy et al, 2020; Samocha et al, 2004; Van Wyk et al, 1999; Williams et al, 1996).…”

Section: Discussionsupporting

confidence: 82%

Growth and population modelling based on density of the Pacific white shrimp intensively cultured in freshwater

Araneda

Hernández

Vela

et al. 2022

Aquaculture Research

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Mathematical representation of the growth of organisms in aquaculture systems is a key factor to perform optimal production. Here, we analysed five growth sigmoidal models based on density of previous and current models described in literature (Gompertz, Bertalanffy, Potential and Pütter). These models were fitted to data of Pacific white shrimp cultured in freshwater, with 90, 130, 180, 230, 280 and 330 shrimp/m 2 as initial stocking density of culture. Goodness of fit and statistic validation of the density-dependent model modified from Gompertz proved to display the growth curve that best-described data of shrimp grown between 90 and 180 densities, whereas the growth model modified from Potential proved to best describe higher stocking densities . The population dynamics was also modelled using a density-dependent function. The implications of modelling and their importance in the management of fisheries are discussed.

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Section: Discussionsupporting

confidence: 82%

Growth and population modelling based on density of the Pacific white shrimp intensively cultured in freshwater

Araneda

Hernández

Vela

et al. 2022

Aquaculture Research

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“…This result can be explained by density effects on survival, as in our study, shrimps were cultured at a lower density than the rearing density in previous work (Amaya et al, 2007). Indeed, previous studies have shown that the culturing density of L. vannamei negatively correlates with survival (Appelbaum et al, 2002). Moreover, survival might be affected by lower main ion concentrations such as potassium, which was not the case in our study.…”

Section: The Survival and Yield Of Pl-55contrasting

confidence: 67%

Additive biocomponents from catfish by-products enhance the growth of shrimp Litopenaeus vannamei

Nam,

Hich,

Hoa

et al. 2023

Fish Aquat Sci

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The rapid expansion of shrimp production requires a huge amount of protein sources from soybeans and wild-caught fishmeal; both are becoming a shortage. Meanwhile, catfish production and processing is a giant industry in Vietnam, which produce hundred thousand tonnes of protein-and lipid-rich by-products, annually. Using catfish by-products to gradually replace the traditional protein sources in shrimp aquaculture may bring triple benefits: 1) reducing pressure on wild fish exploitation for fishmeal, 2) reducing the environmental impacts of catfish by-products, and 3) increasing the value and sustainability of aquaculture production. In this study, we used catfish by-products to produce fish protein hydrolysate (FPH) and nano-hydroxyapatite (HA) as additives in feed for Pacific white shrimp (Litopenaeus vannamei). The supplement mixture of FPH and HA was added into the commercial diet (Charoen Pokphand Group [CP], 38% protein, and 6.5% lipid) to reach 38%, 38.5%, 40%, 43%, and 44% of the crude protein content. The survival and growth of shrimps were weekly assessed to day 55. The results showed that the shrimp growth was highest at 43% crude protein content in the feed as indicated by an increase of 124% and 112% in shrimp weight and length, respectively, compared to the commercial reference diet. No negative effects of adding the mixture of FPH and HA on the water quality were observed. Vibrio density was lower than 6.5 × 10 3 CFU/mL, which is the lowest Vibrio density negatively affecting the shrimp growth and development. These findings indicate that the mixture of FPH and HA are promising additive components in feed for post-larval shrimp L. vannamei diets.

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“…Electrodialysis experiments were performed with a mixed solution of 1000 ppm Na + (as Na 2 SO 4 , ≥99% purity, Merck) and 100 ppm Mg 2+ (as MgSO 4 ·7H 2 O, ≥99.5% purity, Merck) dissolved in deionized water (18.2 MΩ cm)—concentrations that are similar to those found in the brackish water of the Israel Negev region. 32 ED was conducted at a constant current density of 2.5 mA cm −2 , applied using a Lion LE 305D DC laboratory power supplier. A single cell-pair was used in the following configuration (illustrated in Fig.…”

Section: Methodsmentioning

confidence: 99%

Low-resistance monovalent-selective cation exchange membranes prepared using molecular layer deposition for energy-efficient ion separations

2021

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Growth And Survival Of The White Leg Shrimp (Litopenaeus Vannamei) Reared Intensively In The Brackish Water Of The Israeli Negev Desert

Cited by 7 publications

References 5 publications

Growth and population modelling based on density of the Pacific white shrimp intensively cultured in freshwater

Growth and population modelling based on density of the Pacific white shrimp intensively cultured in freshwater

Additive biocomponents from catfish by-products enhance the growth of shrimp Litopenaeus vannamei

Low-resistance monovalent-selective cation exchange membranes prepared using molecular layer deposition for energy-efficient ion separations

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