One of the major toxic effects of a

One of the major toxic effects of ammonia is that, as the ammonium ion, it can
substitute for potassium at vertebrate muscle and nerve membranes, thereby
compromising their function (Raabe and Lin, 1985; Randall and Tsui, 2002). Wright et
al. (1988) demonstrated that the distributions of NH4+ between extracellular and intracellular compartments could be used with the Nernst equation to calculate membrane
potential (EM) in fish. Beaumont et al. (1995b; 2000a,b) found that the relative plasma to white muscle (WM) ammonia distributions predicted a significant depolarisation of the
tissue in brown trout that were hyperammonemic following exposure to copper in acidic
water. Beaumont et al. (2000c) then made direct measurements of EM in WM of
hyperammonemic brown trout, and confirmed the depolarisation, presumably due to the
replacement of K+ with NH4+(Table I). Since then, in all studies investigating effects of ammonia on Ucrit performance in salmonids, application of the Nernst equation
consistently predicts a significant depolarisation of WM (Table I). The reduced WM EM
(Beaumont et al.,1995b; 2000a,b; Shingles et al. 2001; Wicks et al. 2002 McKenzie et al.
2003) was judged to be sufficient to cause a complete loss of electrical excitability in that tissue (Jenerick, 1956), such that it could not be recruited to power anaerobic burst swimming at the highest speeds