Total Coliform Bacteria
Reading AssignmentRead Chapter 30 in Simplified Procedures for Water Examination.
There are a wide variety of disease-causing organisms which can live in water and one of the primary responsibilities of the water treatment plant operator is to ensure that none of these pathogens reach the consumer in their drinking water. However, testing for the presence of each of these disease-causing organisms individually would be prohibitively expensive and time-consuming. Instead, operators usually test for the presence of coliform bacteria. Coliform bacteria do not cause disease, but they are reliable indicators of the presence of disease-causing organisms.
A special group of coliform bacteria, known as fecal coliform bacteria, live in the intestinal tracts of warm-blooded animals. Fecal coliform bacteria are usually present in water only when human or animal wastes have come in contact with the water. The number of fecal coliform bacteria present in a sample is a good indicator of the amount of animal pollution present in the water. Since most waterborne disease-causing organisms originate in human or animal bodies and are discharged as part of body wastes, water with a large quantity of fecal coliform bacteria is likely to contain disease-causing organisms and is not safe to drink.
Photo Credit: Virginia Department of Health
This lab introduces one of the two methods which can be used to test for total coliform, which is the amount of fecal coliform and other coliform bacteria found in water. Both the membrane filter technique used here and the multiple-tube fermentation technique use a special growing medium and a specific temperature to encourage the growth of coliform bacteria while discouraging the growth of other types of bacteria.
Regulations require that coliform bacteria be completely absent from 95% of the water samples at a water treatment plant. If a sample is found to contain coliform bacteria, then the operator must test for fecal coliform, which is a separate test not outlined in this lab. If fecal coliform are found to be present in the water, then both the state and the public must be notified. Coliform bacteria testing is also often used in public swimming areas, although in these areas a larger concentration of coliform bacteria is allowable.
All of the bottles, pipets, and graduated cylinders used in this lab must be made of sterilizable glass or plastic. They must not release any substances which are toxic to bacteria during sterilization. None of the equipment can have broken tips or mouths.
The specific glassware needed for this procedure includes:
In addition, the following equipment is needed:
- Sample bottles.
- Dilution bottles.
- Pipets and graduated cylinders.
- Containers for culture medium. (Erlenmeyer flasks with metal caps, metal foil covers, or screw caps are preferred.)
- Culture dishes. (These can be glass or plastic petri dishes of any appopriate size.)
- 1-L filtering flask with side tube.
- Filtration units. (This should include a seamless funnel fastened to a base by a locking device or by magnetic force. Funnels with deep scratches on the inner surface or with chipped surfaces should be discarded.)
- Vacuum line, electric vacuum pump, filter pump operating on water pressure, or hand aspirator.
- Membrane filters. (These filters must have a pore diameter which will retain all coliform bacteria. The filters must also be non-toxic to bacteria and must not influence the pH. The membranes should be grid-marked in a manner which neither inhibits nor stimulates bacterial growth along the grid-marks.)
- Absorbent pads. (These disks of filter paper should not be toxic to bacteria and should not influence the pH. Absorbent pads are only required if liquid medium is used instead of agar.)
- Forceps. (These should be smooth and flat without corrugations on the inner sides of the tips.)
- Incubators. (The incubators must provide a temperature of 35+O.5°C and a humidity of 60%.)
- Microscope and light source. (The microscope should have a magnification of 10 to 15 diameters. Binocular wide-field dissecting microscopes are preferred. The light should be a cool white fluorescent.)
- Culture media. (Commercial, dehydrated media are preferred, but Standard Methods explains how to produce culture media if commercial media is not available. Dehydrated media should be stored in a desiccator.)
- Sterile distilled water.
2. Prepare petri dishes.
Following the manufacturer's directions, or the procedure in Standard Methods, fill sterilized petri dishes with media.
3. Choose an appropriate sample size.
An ideal sample size will result in 20 to 80 coliform colonies per dish. The table below gives suggested sample sizes for a variety of water sources.4. Set up the filtration apparatus as shown below:
Sample size (mL)
Wells and springs
10, 50, or 100
Lakes and reservoirs
10, 50, or 100
Water supply intake
0.1, 1, or 10
0.1, 1, or 10
0.001, 0.01, 0.1, or 1
0.001, 0.01, 0.1, or 1
0.0001, 0.001, 0.01, or 0.1
Once an appropriate sample size has been chosen, carefully collect a representative water sample and record the sample size in the Data section. You should collect enough water from each source to run three separate samples through the filtration apparatus.
First, place the membrane filter in the bottom piece of the filtration unit, as shown above. The grid side of the filter should be facing up. Sterile forceps should be used whenever you handle the membrane filter to prevent contamination and damage to the filter.
Next, place bottom of the filtration unit in the mouth of the filtering flask. Then place the top of the tiltration unit onto the bottom. The stopper should seal the bottom of the filtration unit into the flask and the magnet in the filtration apparatus should seal the top and bottom together.
Finally, attach a hose to the side arm of the filtering flask. Attach the other end of the hose to the vacuum pump. The completed setup is shown below:
5. Filter the sample water.
Pour your water sample into the top of the filtration unit and turn on the vacuum pump. All of the water should pass through the filter and into the flask.
Rinse the interior surface of the funnel by filtering three 20 or 30 mL portions of sterile distilled water through the unit. Once the water has passed through the filter, turn off the vacuum pump.
6. Place the membrane filter in a petri dish.
Take off the top of the filtraton apparatus, exposing the membrane filter. Then, using sterile forceps, remove the membrane filter.
Place the membrane filter on the medium in a petri dish using a rolling motion to avoid entrapment of air. The grid side of the membrane filter should be up.
Pour a small amount of sample water into the petri dish on top of the membrane filter. The sample water will prevent the bacteria on the filter from going into shock.
Place the lid back onto the petri dish. Seal the dish by placing two pieces of tape around the dish. The tape should go from the top of the dish to the bottom of the dish, like the ribbon on a present. Placing the tape around the edge of the dish will prevent air flow into the dish and will kill the bacteria.
You should repeat steps 4 through 6 until you have filtered three samples from the same source.
7. Incubate the petri dishes.
Invert each dish and place the dishes inside an incubator at 35+O.5°C for 24 hours. This allows the bacteria captured by the filter to grow and form a visible colony.8. Count the number of colonies found on each filter.
After the incubation period has been completed, take each petri dish out of the incubator and remove the lid from the dish. The surface of the medium should have growths of both coliform and other bacteria present.
Chemicals present in the media will normally reduce the number of non-coliform colonies present to a minimum. In addition, colonies of coliform bacteria will have turned a pink or dark red color with a metallic surface sheen. You should count only bacteria with this coloring and sheen to ensure that you do not count other types of bacteria. (Some commercial media cause the coliform bacteria to turn other colors, so you should always read the instructions before counting coliform colonies.)
Set the dissecting microscope to a 10 to 15x magnification and use the microscope to help count the number of colonies found in the petri dish. The figure below illustrates one method of counting colonies which should insure that all areas of the filter are observed:
Once you have counted the number of colonies found on the filter, record the number in the Data section. Filters which show a growth over the entire surface of the filter with no individually identifiable colonies should be recorded as "confluent growth." Filters which show a very high number of colonies (greater than 200) should be recorded as "too numerous to count."
If the number of colonies counted is greater than 80 or less than 20 per filter, then an incorrect sample size was chosen. You should choose a larger or smaller sample size and repeat the above procedure. (When sampling drinking quality water, you can disregard the lower limit of 20 colonies per sample.)
9. Calculate the coliform density of each filter using the following formula and record the results in the Data section.
10. Calculate the average coliform density from all three samples.
When calculating the average coliform density, operators usually use a geometric mean rather than an arithemetic mean. A geometric mean, unlike an arithmetic mean, tends to dampen the effect of very high or very low values which might be the result of an improper procedure. A geometric mean can be calculated using either of the two methods outlined below. These methods are also often used to calculate the average coliform density over time.
The nth Root Method
The general formula for calculating the Geometric Mean using the nth root method is:
Where:X1, X2, Xn are coliform densities
n is the number of densities being averaged
This formula means that you multiply all of the data points together and then take the nth root of this product. To take the nth root, you will need a scientific calculator with a "yx" or "y^x" key.
Let's consider an example to show you how to make these calculations. The table below shows the coliform density found in four separate samples:
5 col/100 mL 2 7 col/100 mL 3
90 col/100 mL 4
1,000 col/100 mL
The following calculations are used to calculate the mean:
In the second step of the calculations above, you would insert the following values on your calculator in order to take the 4th root:
You should attempt this calculation on your own calculator to ensure that you understand the procedure.
Logarithmic Averaging Method
The logarithmic averaging method is another method that can be used to calculate the geometric mean. In order to use this method, you will need a scientific calculator with a "log" and a "10x" key. Using the same data that we used for the nth root method, we will calculate the logarithmic mean:
The first step is to calculate the logarithm of each data point. To do so, type the coliform density value into your calculator and push the "log" button. The logarithm of each data point is shown in the table below:
Logarithm 5 0.69897 7 0.84510 90 1.95424 1,000 3.00000
Next, we have added up the logarithm values. As the table above shows, the sum of the logarithm values is 6.49831.
Finally, we calculate the logarithmic mean as follows:
Notice that we first divided the sum of the logarithms by the number of data points. Then we took the antilogarithm of this value. To take the antilogarithm of a value, first type the value into your calculator, then hit the "10x" key.
Sample size (mL)
Number of coliform colonies Coliforms/100 mL
Average coliform density: ________________________________
American Public Health Association, American Water Works Association, and Water Environment Federation. 1998. Standard Methods for the Examination of Water and Wastewater. American Public Health Association, Washington, D.C.