Page 937 - The Toxicology of Fishes
P. 937
The Effects of Polycyclic Aromatic Hydrocarbons in Fish from Puget Sound, Washington 917
Johnson, L. L., G. M. Ylitalo, M. R. Arkoosh, A. N. Kagley, C. L. Stafford, J. L. Bolton, J. Buzitis, B. F.
Anulacion, and T. K. Collier. (2007). Contaminant exposure in outmigrant juvenile salmon from Pacific
Northwest estuaries. Environ. Monit. Assess., 124, 167–194.
Jonsson, G., J. Beyer, D. Wells, and F. Ariese. (2003). The application of HPLC-F and GC-MS to the analysis
of selected hydroxy polycyclic hydrocarbons in two certified fish bile reference materials. J. Environ.
Monit., 5, 513–520.
Karickhoff, S. W. (1981). Semiempirical estimation of sorption of hydrophobic pollutants on natural sediments
and soil. Chemosphere, 10, 833–846.
Kennish, J. (1998). Pollution Impacts on Marine Biotic Communities. CRC Press, Boca Raton, FL.
Krahn, M. M., M. S. Myers, D. G. Burrows, and D. C. Malins. (1984). Determination of metabolites of
xenobiotics in bile of fish from polluted waterways. Xenobiotica, 14, 633–646.
Krahn, M. M., L. D. Rhodes, M. S. Myers, L. K. Moore, W. D. MacLeod, and D. C. Malins. (1986). Associations
between metabolites of aromatic compounds in bile and the occurrence of hepatic lesions in English sole
(Parophrys vetulus) from Puget Sound, Washington. Arch. Environ. Contam. Toxicol., 15, 61–67.
Krahn, M. M., D. G. Burrows, J. W. D. MacLeod, and D. C. Malins. (1987). Determination of individual
metabolites of aromatic compounds in hydrolyzed bile of English sole (Parophrys vetulus) from polluted
sites in Puget Sound, Washington. Arch. Environ. Contam., 16, 511–522.
Krahn, M. M., L. K. Moore, R. G. Bogar, C. A. Wigren, S.-L. Chan, and D. W. Brown. (1988). High-
performance liquid chromatographic method for isolating organic contaminants from tissue and sediment
extracts. J. Chromatogr., 437, 161–175.
Krahn, M. M., G. M. Ylitalo, J. Joss, and S.-L. Chan. (1991). Rapid, semi-quantitative screening of sediments
for aromatic compounds using sonic extraction and HPLC/fluorescence analysis. Mar. Environ. Res., 31,
175–196.
Krahn, M. M., G. M. Ylitalo, J. Buzitis, S.-L. Chan, and U. Varanasi. (1993). Rapid high-performance liquid
chromatographic methods that screen for aromatic compounds in environmental samples. J. Chromatogr.,
642, 15–32.
Krone, C. A., J. E. Stein, and U. Varanasi. (1992). Estimation of levels of metabolites of aromatic hydrocarbons
in fish tissues by HPLC/fluorescence analysis. Chemosphere, 24, 497–510.
Kubin, L. A. (1997). A Study of Growth in Juvenile English Sole Exposed to Sediments Amended with
Aromatic Compounds, M.S. thesis, Western Washington State University, Bellingham.
Kukkonen, J. B. K. and P. F. Landrum. (1998). Effect of particle-xenobiotic contact time on bioavailability
of sediment-associated benzo(a)pyrene to benthic amphipod, Diporeia spp. Aquat Toxicol., 42, 229–242.
Landahl, J. T., B. B. McCain, M. S. Myers, L. D. Rhodes, and D. W. Brown. (1990). Consistent associations
between hepatic lesions (including neoplasms) in English sole (Parophrys vetulus) and polycyclic aromatic
hydrocarbons in bottom sediment. Environ. Health Perspect., 89, 195–203.
Levings, C. D. and R. M. Thom. (1994). Habitat changes in Georgia Basin: implications for resource
management and restoration. Can. Tech. Rep. Fish. Aquat. Sci., 1948, 330–349.
Lin, E. L. C., T. W. Neiheisel, J. Flotemersch, B. Subramanian, D. E. Williams, M. R. Millward, and S. M.
Cormier. (2001). Historical monitoring of biomarkers of PAH exposure of brown bullhead in the reme-
diated Black River and the Cuyahoga River, Ohio. J. Great Lakes Res., 27, 191–198.
Lipnick, R. L. (1995). Structure–activity relationships, in Fundamentals of Aquatic Toxicology, 2nd ed., Rand,
G. M., Ed., Taylor & Francis, London, pp. 609–655.
Liu, T.-Y., S.-L. Cheng, T.-H. Ueng, Y.-F. Ueng, and C.-W. Chi. (1991). Comparative analysis of aromatic
32
DNA adducts in fish from polluted and unpolluted areas by the P-postlabeling analysis. Bull. Environ.
Contam. Toxicol., 47, 783–789.
Livingstone, D. R. (1991). Organic xenobiotic metabolism in marine invertebrates, in Advances in Comparative
and Environmental Physiology, Vol. 7, Gilles, R., Ed., Springer-Verlag, Heidelberg, pp. 46–185.
Livingstone, D. R. (2001). Contaminant-stimulated reactive oxygen species production and oxidative damage
in aquatic organisms. Mar. Pollut. Bull., 42, 656–666.
Long, E. R., M. Dutch, S. Aasen, K. Welch, and J. Hameedi. (2003). Chemical Contamination, Acute Toxicity
in Laboratory Tests, and Benthic Impacts in Sediments in Puget Sound: A Summary of Results of the Joint
1997–1999 Ecology/NOAA Survey 2003, Publ. No. 03-03-049, Washington State Department of Ecology,
Olympia, WA; NOAA Tech. Memo NOS-NCCOS-CCMA 163, National Oceanic and Atmospheric Ad-
ministration, Silver Spring, MD.
