Ammonia is the primary waste byproduct of protein me
-
tabolism in fish and it rapidly attains toxic concentrations
in the confines of an aquarium.
It exists as a mixture of
free ammonia (NH
3
) and ionized ammonia (NH
4
+
) in
equilibrium. This does not mean that they are present in
equal proportion, but that they are converted from one to
the other at an equal rate.
The concept of equilibrium is fundamental to under
-
standing ammonia. The siphon is a familiar and useful
metaphor. If two containers of equal size and at equal
level are connected by a siphon, the level and amount of
water in each will be the same. If one container is low
-
ered or made larger, then the water level in that con
-
tainer will begin to fall, but the siphon will
compensate and the levels will be
-
come the same again, but now the
amount of water will be less in the
higher or smaller container than in
the lower or larger container. The
total amount of water does not change, but its
distribution between compartments is altered. Ammonia
in equilibrium behaves the same way: as the pH falls, the
ammonia equilibrium shifts in the direction of ionized
ammonia. As with our container metaphor, total ammo
-
nia does not change, but the amount in each compart
-
ment shifts. At pH of 8.3, free ammonia makes up about
10% of the total. At a pH of 7.0, free ammonia makes up
less than 0.5% of the total.
Free ammonia is uncharged and is a gas dissolved in
water. It can pass unimpeded through membranes such
as fish gills. This allows it to interfere with the normal
excretion of ammonia and is believed to account for its
toxicity. Ionized ammonia is a charged particle and does
not exist as a gas. It cannot pass through membranes and
is, therefore, relatively nontoxic. It does, however, func
-
tion as a proton donor, like the hydrogen ion, and, in
high concentrations, produces external burns that are
identical to acid burns. This is often seen in crowded gold
fish ponds and shipping containers. The external “burn
-
ing” properties of ammonia in high concentration at low
pH should not be confused with the respiratory toxicity
of free ammonia.
Ammonia can be removed from an aquarium by deplet
-
ing either free or ionized ammonia. Since it is in equilib
-
rium, removing either component will ultimately remove
both components. Picture this as adding another siphon
to either of our containers. This second siphon will drain
one of the compartments. As we drain one compartment,
the water level falls, but this will be compensated by the
first siphon. This is fundamental to what a siphon does
and fundamental to what equilibrium does. If we
continue to drain from one compartment,
we will ultimately drain both com
-
partments.
The biological filter removes ionized
ammonia, and, provided it works effi
-
ciently, does so to the extent that free ammonia is
virtually undetectable. It is often overlooked that free
ammonia is toxic to nitrifying bacteria and that high
ammonia concentration is a major cause of difficulty in
establishing a biological filter.
Ion exchangers remove ionized ammonia, but only in
freshwater. The presence of even low concentrations of
salts in freshwater interferes significantly with ammonia
removal by ion exchange. The most prevalent material
used for this is zeolite, a natural mineral, more com
-
monly recognized as cat litter.
The classical reaction of ammonia with formaldehyde to
form methenamine is the principal of most ammonia
removing conditioners. It may be used either directly or
as a bisulfite complex. The bisulfite formaldehyde com
-
plex has the advantage of odor control, enhanced reac
-
tion time, and improved methenamine stability.