Chronic toxicity of nitrate to Pacific white shrimp, Litopenaeus vannamei: Impacts on survival, growth, antennae length, and pathology

Chronic toxicity of nitrate (NO 3 −) has not been well documented in the culture of penaeid shrimp. To interpret this problem, lab-scale research was conducted in recirculating aquaculture systems (RAS) to determine the long-term impacts of nitrate on shrimp growth, survival, total mass of shrimp pe...

Full description

Saved in:
Bibliographic Details
Published in:Aquaculture 2010-11, Vol.309 (1), p.109-114
Main Authors: Kuhn, David D., Smith, Stephen A., Boardman, Gregory D., Angier, Matthew W., Marsh, Lori, Flick, George J.
Format: Article
Language:English
Subjects:
Animal aquaculture
animal diseases
animal growth
Animal productions
Animal, plant and microbial ecology
antennae
Applied ecology
Aquaculture
Biological and medical sciences
Chronic
chronic toxicity
Ecotoxicology, biological effects of pollution
Experiments
Fundamental and applied biological sciences. Psychology
General aspects
gills
hepatopancreas
histopathology
length
Litopenaeus vannamei
liveweight gain
mortality
Nitrate
nitrate nitrogen
Nitrates
Pathology
Physical growth
Recirculating
recirculating aquaculture systems
salinity
Shellfish
Shrimp
shrimp culture
Survival analysis
Toxicity
Vannamei
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Chronic toxicity of nitrate (NO 3 −) has not been well documented in the culture of penaeid shrimp. To interpret this problem, lab-scale research was conducted in recirculating aquaculture systems (RAS) to determine the long-term impacts of nitrate on shrimp growth, survival, total mass of shrimp per system (shrimp biomass), antennae length, and tissue pathology. The first experiment, Trial (A), was performed over a six week period at 11 (ppt) salinity and consisted of a Control A (35 ppm nitrate-N), Treatment A1 (220 ppm nitrate-N), Treatment A2 (435 ppm nitrate-N), and Treatment A3 (910 ppm nitrate-N). No differences were observed between control A and treatment A1 in terms of shrimp survival, growth, shrimp biomass, and antennae length. Treatment A2 exhibited no significant differences compared to Control A in terms of survival and growth, but did exhibit significant negative impacts ( P < 0.05) on shrimp biomass and antennae length. Lastly, treatment A3 significantly and negatively impacted ( P < 0.05) survival, growth, total mass, and antennae length. Histopathology of shrimp from Trial A and all three groups of Treatments A1 through A3 demonstrated lesions in the hepatopancreas, and a few individuals from each of these three groups had gill abnormalities (e.g. fouling). A second experiment, Trial (B), was conducted over a five week period to evaluate the effects of elevated nitrate at various salinities. This trial consisted of Control B (9 ppt salinity, 18 ppm nitrate-N), Treatment B1 (9 ppt salinity, 440 ppm nitrate-N), Treatment B2 (2 ppt salinity, 440 ppm nitrate-N), and Treatment B3 (18 ppt salinity, 440 ppm nitrate-N). When compared to Control B, Treatments B1 through B3 exhibited significantly negative effects ( P < 0.05) on shrimp survival, growth, and shrimp biomass, irrespective of salinity. Even though all treatment groups with 440 ppm nitrate-N exhibited negative responses to elevated nitrate, there was evidence ( P < 0.05) that an increase in salinity significantly ( P < 0.05) improved survival and shrimp biomass.
ISSN:0044-8486
1873-5622
DOI:10.1016/j.aquaculture.2010.09.014