Biological filters are typically used in aquaculture to control ammonia and nitrite. Three categories of factors affect biological filters: the biological community, the water physico-chemistry and the physical design.

Biological Community — Control of ammonia and nitrite in biological filters is accomplished by nitrifying bacteria.

Nitrifying bacteria are very sensitive to environmental conditions; this is particularly true for Nitrobacter. Many factors can inhibit these bacteria. The active area of the biological filter should be in the dark; light is inhibitory. Excess organic material inhibits nitrifiers. A balanced population of heterotrophic bacteria is essential to control levels of soluble organic pollutants.

Water Physico-Chemistry — Ammonia and nitrite are only sources of nitrogen for the bacteria. Other nutrients including carbon, phosphorus and trace elements are also essential. Carbon must be inorganic and is measured as carbonate alkalinity. Sodium bicarbonate (baking soda) is commonly used to add carbonate alkalinity. Water with more than 100 mg carbonate alkalinity/L is normally adequate; lack of carbonate alkalinity will stop nitrification.

The alkalinity provides pH buffering. The optimal pH for nitrification is near 8.0. Values outside of 6.0 — 8.5 can be expected to reduce nitrification efficiency. Nitrosomonas produces acid during its growth; the pH must be monitored and adjusted.

Nitrifying bacteria absolutely require adequate oxygen. Water exiting a biological filter should always contain at least 4 ppm oxygen. The optimal temperature for nitrification is about 30°C; the rate can be expected to be cut in half for every decrease of 10°C. Thus a filter working at 30°C may remove the same amount of ammonia as one twice as large but operating at 20°C.

Physical Design — The role of all biological filters (trickle filters, RBCs or fluidized beds etc.) is to provide a home for the microorganisms. More surface area allows for the development of larger bacterial populations. Surface area, however, must be balanced against open area within the filter. Biological filtration results in the growth of bacterial biomass; filters with inadequate surface area block rapidly.

A well designed biofilter should be virtually self-cleaning. The nature of the physical substrate can also affect start-up time. Slippery surfaces are more difficult for the bacteria to colonize than rough ones. Water flow patterns are very important. An adequate flow is essential to assure that the pollution or food reaches the bacteria, which are immobile. They use the nutrients around them, sufficient water movement is essential for good growth and performance. All water should be physically filtered or clarified to remove solids before the biological filter; these solids should be removed from the system as quickly as possible. Inadequate water flow combined with solids accumulation can be the cause of major headaches. Anoxic zones will develop where there can be a synthesis of ammonia and nitrite even in the biofilter. Nitrite is produced not only as a by-product of ammonia removal but also from the partial denitrification of nitrate.

The Bacta-Pur System

The Bacta-Pur System for biological filters consists of:
• Bacta-Pur N3000 — a balanced community of nitrifiers and selected heterotrophs;
• Bacta-Pur Pre-starter 1 — nitrite plus growth enhancers for Nitrobacter,
• Bacta-Pur Pre-starter 2 — ammonia and essential nutrients.
• Bactivator — automatic system to activate Bacta-pur products

Once the population of Nitrobacter has been established, Bacta-Pur Pre-starter 2 is added to feed the Nitrosomonas. Bacta-Pur Pre-starter 2 is also used to maintain biological filters when biomass is low or before sudden increases in stock.

Symptoms biofilter difficult or slow to start high ammonia and/or nitrite fluctuating loads Treatment Benefits start biofilters rapidly bring ammonia and nitrite to safe levels stabilize filter performance

Maintaining Filters with Fluctuating Loads — The ideal way to handle fluctuating loads is to use multiple or modular biological filters where a portion of the physical substrate, on which the bacteria grow, can be isolated from the rest of the system. The isolated section can be fed artificially by adding Bacta-Pur Pre-starter 2. Ammonia is monitored and more Bacta-Pur Pre-sterter 2 is added as needed. When the new load of biomass arrives the isolated section of the filter can be drained of liquid to remove residual ammonia and/or nitrite and then returned into operation.

All water sterilization equipment should be turned off during start-up of a biological filter.

Dose Rates Starting a Biological Filter with Animals Present — Add 100 mL Bacta-Pur N-3000 / 1000 L of tank water. Continue additions of half this dose daily until filter activity has stabilized. Starting a Biological Filter without Animals Present — Step 1: add 100 mL Bacta-Pu N-3000 / 1000 L of tank water (continue additions of half this dose daily until filter activity has stabilized) and 1 kg Bacta-Pur Pre-sterter 1 / 4000 L tank water. Step 2: monitor nitrite, and when it is less than 1 ppm add 1 kg Bacta-Pur Pre-sterter 2 / 4000 L tank water. Step 3: monitor ammonia and nitrite, and add animals when safe levels are reached. Step 4: switch to ‘Maintaining a Biological Filter’. Maintaining a Biological Filter — Add weekly 100 mL Bacta-Pur N-3000 / 1000 L of tank water. Small cold water systems, such as for lobster tanks, should have weekly additions of 100 mL Bacta-Pur N-3000 / 200 L of tank water. Maintaining a Biological Filter with Fluctuating Loads — Add to each 100 L water containing isolated sections of biofilter 100 g Pre-starter 2 and 100 mL Bacta-Pur N-3000. Monitor ammonia, and add more Bacta-Pur Pre-staerter 2 as necessary.

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