Se presenta una técnica para la estimación de laboratorio de eficiencia de transferencia trófica neto de bifenilos policlorados (PCB) congéneres para los peces piscívoros de sus presas. Para maximizar la aplicabilidad de los resultados de laboratorio al campo, los peces piscívoros se debe alimentar peces presa que normalmente se come en el campo.
Una técnica para la estimación de la eficiencia de laboratorio red trófica de transferencia (γ) de bifenilos policlorados (PCB) congéneres para los peces piscívoros de sus presas se describe en este documento. Durante un experimento de laboratorio de 135 días, nos alimentamos bloater (Coregonus hoyi) que habían sido capturados en el Lago Michigan para la trucha de lago (Salvelinus namaycush) mantenido en ocho tanques de laboratorio. Bloater es una presa natural para la trucha de lago. En cuatro de los tanques, se utilizó una velocidad de flujo relativamente alta para asegurar una actividad relativamente alta por la trucha de lago, mientras que se utilizó un caudal bajo en los otros cuatro tanques, lo que permite una baja actividad trucha de lago. Sobre una base del tanque por tanque, se registró la cantidad de alimento ingerido por la trucha de lago en cada día del experimento. Cada trucha de lago se pesó al comienzo y al final del experimento. Cuatro a nueve trucha de lago de cada uno de los ocho tanques fueron sacrificados al inicio del experimento, y todo trucha 10 lago que queda en cada uno de los tanques fueron euthanzado al final del experimento. Se determinó la concentración de 75 congéneres de PCB en la trucha de lago en el inicio del experimento, en la trucha de lago, al final del experimento, y en bloaters alimentamos a la trucha de lago durante el experimento. En base a estas mediciones, γ se calculó para cada uno de 75 congéneres de PCB en cada uno de los ocho tanques. Significan γ se calculó para cada uno de los 75 congéneres de PCB para la trucha de lago activa e inactiva. Debido a que el experimento se repitió en ocho tanques, el error estándar de decir γ podría estimarse. Los resultados de este tipo de experimentos son útiles en los modelos de evaluación de riesgo para predecir el riesgo futuro de los seres humanos y la vida silvestre que comen peces contaminados en diversos escenarios de la contaminación ambiental.
Of all of the factors affecting the rate at which fish accumulate contaminants, the efficiency with which fish retain contaminants from the food that they eat is one of the most important1-3. Risk assessment models have been developed to predict future risks to both people and wildlife eating contaminated fish under various scenarios of environmental contamination, and the reliability of these predictions critically depends on the accuracy of the estimates of the efficiency at which fish retain contaminants from their food4.
The efficiency with which the contaminant in the food ingested by the predator is transported through the gut wall is known as gross trophic transfer efficiency5. A portion of the quantity of the contaminant transported through the gut wall of the predator may eventually be lost through depuration and/or metabolic transformation. The efficiency with which the contaminant in the food ingested by the predator is retained by the predator, including any losses due to elimination and metabolic transformation, is known as net trophic transfer efficiency6.
Gross trophic transfer efficiency of organic contaminants to fish from their prey appears to vary with the contaminant’s chemical properties, including lipid affiliation as measured by the octanol-water partition coefficient, Kow3,7. According to an empirical relationship developed by Thomann3, gross trophic transfer efficiency is relatively high when log Kow is equal to a value between 5 and 6. Gross trophic transfer efficiency declines exponentially at a rate of 50% per unit of log Kow as log Kow increases from 6 to 10, according to the Thomann3 relationship.
Nevertheless, the gross and net trophic transfer efficiencies of polychlorinated biphenyl (PCB) congeners to fish from their prey do not appear to follow the Thomann3 relationship in most cases. Although the trophic transfer efficiencies of PCB congeners to lake whitefish (Coregonus clupeaformis) from its food followed the relationship proposed by Thomann8, trophic transfer efficiencies of PCB congeners were either just weakly related or not related at all to log Kow for Atlantic salmon (Salmo salar)9, rainbow trout (Oncorhynchus mykiss)10, coho salmon (Oncorhynchus kisutch)11, and northern pike (Esox lucius)11.
The overall goal of this study was to present a laboratory technique for estimating the net trophic transfer efficiencies of PCB congeners to a piscivorous fish from its prey. Lake trout (Salvelinus namaycush) was chosen as the piscivorous fish for our experiment because lake trout are relatively easy to maintain in laboratory tanks. Bloater (Coregonus hoyi) was selected as the prey fish to be fed to the lake trout because bloater is eaten by lake trout in its natural setting12. In addition, we determined whether the net trophic transfer efficiencies for lake trout estimated from our laboratory experiment followed the Thomann3 relationship. We also determined whether the degree of activity by the lake trout had a significant effect on net trophic transfer efficiency (γ) of the PCB congeners. Activity by lake trout in the Laurentian Great Lakes is believed to have recently increased because changes in the food webs have caused lake trout to allocate more energy toward searching for food13. Lake trout were forced to exercise in one set of tanks by subjecting these lake trout to relatively high flow rates, whereas the other lake trout were permitted to remain relatively inactive by subjecting them to relatively low flow rates. Finally, the specific details of our laboratory procedure that need to be carefully followed to ensure the highest degree of accuracy in the γ estimates and to make the laboratory results applicable to the field are discussed, as well as future directions for research building on our laboratory technique. Net trophic transfer efficiency can be estimated both in the laboratory and in the field, and advantages and disadvantages are associated with both approaches. Accuracy in the estimate of γ depends on the accuracy of the estimate of food consumption. The amount of food eaten by fish in the laboratory can be accurately determined when proper protocols are followed, whereas the amount of food eaten by fish in the field is typically estimated via bioenergetics modeling. Use of bioenergetics modeling to derive the amount of food eaten has the potential to introduce a substantial amount of uncertainty into the estimates of food consumption. Fish bioenergetics models have been shown to estimate food consumption with no detectable bias for the case of lake trout14,15, but considerable bias in bioenergetics model estimates of food consumption has been detected for the case of lake whitefish15,16. On the other hand, estimates of net trophic transfer efficiency estimated in the laboratory may not be applicable to the field due to a difference in feeding rates between the laboratory and the field17. Evidence from both the laboratory and the field suggest that feeding rate can influence γ14,17.
The methodology used in the present study for estimating γ in the laboratory is applicable to situations where the predator fish is fed prey fish, and the amount of prey fish eaten by the predator can be accurately tracked. To accomplish this, the experimenter must weigh all of the food before placement in the tank; and the experimenter must be able to remove all of the uneaten food from the tank, and then weigh the uneaten food. In addition, an adequate suite of mixers and blenders should be available to obtain a sufficient degree of homogenization of the samples of both predator and prey fish. Finally, the gas chromatography – mass spectrometry instrumentation used to determine the PCB congener concentrations must be capable of detecting and quantifying individual PCB congeners at relatively low concentrations.
Para las estimaciones más exactas de γ, el experimentador debe ser capaz de rastrear con precisión tanto la cantidad de alimento colocado en cada uno de los tanques y la cantidad de alimento no consumido en cada uno de los tanques durante el curso del experimento. Para lograr esto, el experimentador debe ser capaz de eliminar todos los restos de comida de los tanques y determinar con precisión su peso. Además de un seguimiento preciso de la comida en realidad comido por el pez depredador, estimación precisa de γ …
The authors have nothing to disclose.
This work was funded, in part, by the Great Lakes Fishery Commission and the Annis Water Resources Institute. Use of trade, product, or firm names does not imply endorsement by the U. S. Government. This article is Contribution 1867 of the U. S. Geological Survey Great Lakes Science Center.
Name | Company | Catalog Number | Comments |
870-L fiberglass tanks | Frigid Units | RT-430-1 | |
2,380-L fiberglass tanks | Frigid Units | RT-630-1 | |
Tricaine methanesulfonate (Finquel) | Argent Chemical Laboratories, Inc. | C-FINQ-UE-100G | Eugenol could also be used as an anesthetic. |
Ashland chef knife | Chicago Cutlery | SKU 1106336 | |
Cutting board | Williams-Sonoma | 3863586 | |
Hobart verical mixer (40 quart) | Hobart Corporation | ||
1.9-L food processor | Robot Coupe, Inc. | RSI 2Y1 | |
Polyethylene bags (various sizes) | Arcan Inc. | ||
I-Chem jars | I-Chem | 220-0125 | |
Top-load electronic balance | Mettler Toledo | Mettler PM 6000 | |
Sodium sulfate, anhydrous – granular | EMD | SX0760E-3 | |
Glass extraction thimbles (45 mm x 130 mm) | Wilmad-Lab Glass | LG-7070-114 | |
Teflon boiling chips | Chemware | 919120 | |
Rapid Vap nitrogen sample concentrator | Labconco | 7910000 | |
N-Vap nitrogen concentrator | Organomation | 112 | |
Soxhlet extraction glassware (500 mL) | Wilmad-Lab Glass | LG-6900-104 | |
Hexane | Burdick & Jackson | Cat. 211-4 | |
Dichloromethane | Burdick & Jackson | Cat. 300-4 | |
Silica gel | BDH | Cat. BDH9004-1KG | |
Labl Line 5000 mult-unit extraction heater | Lab Line Instruments | ||
Agilent 5973 GC/MS with chemical ionization | Agilent | 5973N | |
Internal standard solution | Cambridge Isotope Laboratories | EC-1410-1.2 | |
PCB congener calibration standards | Accustandard | C-CSQ-SET | |
DB-XLB column (60m x 0.25mm, 0.25 micron) | Agilent/ J&W | 122-1262 |