The Sawyer Bucket Filter was tested according to EPA standards and found to reduce three types of microorganisms (Raoultella terrigena, Bacillus subtilis, and Micrococcus luteus) by 6 log units or more in all trials, meeting the EPA requirement. The filter consistently provided 6 log unit reductions or greater even when some bacteria passed through during testing. Additional testing showed the filter acts as an effective barrier through back flushing.
Methods to detect potability of water samplevimala rodhe
Water is precious and it is the base for living, Several disease causing pathogens are transmitted through water. There are various methods to detect the presence of pathogens in drinking water samples.Some of the methods to detect microbiological quality of water are discussed.
Microbial analysis of water system and endotoxin estimationashapatel676
In Pharmaceutical different grades of waters are used and they all must be tested firest before using it for manufacturing any products. Products sometimes get contaminated because of presence of endotoxins so they mus be checked by performing BET test
Enumeration is counting of microorganisms present in a sample.
This is done to know the intense of presence of the spoilers in the spoiled food.
To detect which type of organism is responsible for the spoilage.
Mostly this is done two important methods.
Viable count
Total count
VIABLE COUNT:
A viable cell count allows one to identify the number of actively growing or dividing cells in a sample.
The plate count method or spread plate method relies on bacteria growing a colony on a nutrient medium.
Number of colonies can be counted.
Plate count agar is used for general count
MacConkey agar is used for Gram negative organisms.
TOTAL COUNT:
The initial analysis is done by mixing serial dilution of sample in liquid nutrient agar which is then poured into bottles.
The bottles are then sealed and laid on their sides to produce a slopping agar surface.
The colonies are then counted by eye.The total number of colonies are said as Total Viable Count. The initial analysis is done by mixing serial dilution of sample in liquid nutrient agar which is then poured into bottles.
The bottles are then sealed and laid on their sides to produce a slopping agar surface.
The colonies are then counted by eye.The total number of colonies are said as Total Viable Count.
Pour plate method:
The same procedure is done for this till serial dilution.
The serially diluted sample is then mixed with the molten nutrient agar.
Then poured onto the sterile petridish.
Incubated under appropriate temperature amd the colonies where counted.
ConclusionThe enumeration of these spoiled food samples are important to encounter the type of microbe is causing the spoilage.
And hence this is used to prevent the same type of spoilage.
This can be avoided by making the environmental changes which inhibits the organism which is responsible for the spoilage.
Microbiological inspection of mineral water by redox-potential measurement Olivér Reichart
MicroTester as a validated method is suitable for rapid microbiological testing of mineral water, carbonated water, tank and running drinking water and other types of water. The time needed for a reliable detection of microorganisms is of key importance: in water industry the real-time (or at least as fast as possible) monitoring of the microbiological properties of the production is indispensable; in public water supply the essential basis of the epidemiological and public health measures is the fast and reliable result of the microbiological inspection. Beside the most important and most widely inspected microbiological contaminants the most relevant disturbing flora was involved to the validation process as well.
Methods to detect potability of water samplevimala rodhe
Water is precious and it is the base for living, Several disease causing pathogens are transmitted through water. There are various methods to detect the presence of pathogens in drinking water samples.Some of the methods to detect microbiological quality of water are discussed.
Microbial analysis of water system and endotoxin estimationashapatel676
In Pharmaceutical different grades of waters are used and they all must be tested firest before using it for manufacturing any products. Products sometimes get contaminated because of presence of endotoxins so they mus be checked by performing BET test
Enumeration is counting of microorganisms present in a sample.
This is done to know the intense of presence of the spoilers in the spoiled food.
To detect which type of organism is responsible for the spoilage.
Mostly this is done two important methods.
Viable count
Total count
VIABLE COUNT:
A viable cell count allows one to identify the number of actively growing or dividing cells in a sample.
The plate count method or spread plate method relies on bacteria growing a colony on a nutrient medium.
Number of colonies can be counted.
Plate count agar is used for general count
MacConkey agar is used for Gram negative organisms.
TOTAL COUNT:
The initial analysis is done by mixing serial dilution of sample in liquid nutrient agar which is then poured into bottles.
The bottles are then sealed and laid on their sides to produce a slopping agar surface.
The colonies are then counted by eye.The total number of colonies are said as Total Viable Count. The initial analysis is done by mixing serial dilution of sample in liquid nutrient agar which is then poured into bottles.
The bottles are then sealed and laid on their sides to produce a slopping agar surface.
The colonies are then counted by eye.The total number of colonies are said as Total Viable Count.
Pour plate method:
The same procedure is done for this till serial dilution.
The serially diluted sample is then mixed with the molten nutrient agar.
Then poured onto the sterile petridish.
Incubated under appropriate temperature amd the colonies where counted.
ConclusionThe enumeration of these spoiled food samples are important to encounter the type of microbe is causing the spoilage.
And hence this is used to prevent the same type of spoilage.
This can be avoided by making the environmental changes which inhibits the organism which is responsible for the spoilage.
Microbiological inspection of mineral water by redox-potential measurement Olivér Reichart
MicroTester as a validated method is suitable for rapid microbiological testing of mineral water, carbonated water, tank and running drinking water and other types of water. The time needed for a reliable detection of microorganisms is of key importance: in water industry the real-time (or at least as fast as possible) monitoring of the microbiological properties of the production is indispensable; in public water supply the essential basis of the epidemiological and public health measures is the fast and reliable result of the microbiological inspection. Beside the most important and most widely inspected microbiological contaminants the most relevant disturbing flora was involved to the validation process as well.
Presentation based on a research article published in the journal scientific reports in 2017, entitled as "A Novel Pathogen Capturing Device for Removal and Detection"
The primary productivity of phytoplankton, macroalgae, and seagrasses forms the base of marine ecosystem structuring in aquatic environments. Primary productivity is affected by various environmental factors and ecological processes that usually interact in a complex manner. The rate of primary production usually governs the overall ecosystem health and ecological productivity of a water body, and any observed trends may reveal the occurrence of potential stresses on existing ecosystems. Along the Saudi Gulf coast, primary productivity monitoring may help provide the basis for identifying the potential stressors to the coastal marine environments. Foremost among the considerations is the potential adverse effect of excessive anthropogenic nutrient loadings, which may lead to eutrophication events that can adversely impact on ecosystem health. In addition, high nutrient loads from man-made activities may trigger the excessive growth of some toxic phytoplankton species, potentially resulting in harmful algal blooms (HABs) with serious human health risks and negative economic impacts.
This study is geared towards monitoring the primary productivity levels in selected areas of the Saudi Gulf waters to identify areas of concern as regards hyper-nutrification, ecological disturbance, and potential hot spots for HAB events. Nutrient loadings and the identification of potential HAB organisms will form a special focus of the investigations.
Pharmacological activity of the methanolic extract of sea urchins against esc...Innspub Net
This study elucidated the pharmacological potential of sea urchins using methanol as extracting medium. The antibacterial potential was evaluated using the paper disc method and zone of inhibition against Escherichia coli and Staphylococcus aureus was measured. Antioxidant properties of sea urchins were evaluated using DPPH radical scavenging assay. Three species of sea urchin randomly collected along the intertidal zone of Diguisit, Baler Aurora were identified using diagnostic keys by the National Museum of the Philippines and they were identified as follows; Echinothrix diadema, Echinometra mathaei, and Echinometra oblonga. E. diadema recorded the highest diameter zone of inhibition against E. coli and S. aureus after 24 hours of incubation with 11.03 ± 1.75mm and 13.52 ± 1.13mm respectively while E. mathaei only inhibited S. aureus with zone of inhibition of 9.27 ± 2.06mm in 24 hours of incubation as well. As the zone of inhibition prolongs, the zone of inhibition decreases as observed in 48 hours of incubation. E. oblonga did not show inhibitoy effect, however it recorded the highest radical scavenging activity with 64.46% among the three species of sea urchins. This was followed by E. mathaei (51.52%) and E. diadema (37.38%). All collected species manifested antioxidant potential. Based on the results, the collected species of sea urchins has a pharmacological potential.
1. Microbiological Testing of the Sawyer
Bucket Filter
Produced for
Sawyer Products
Prepared by
Jeff Erikson, Assistant Professor of Biology and Environmental Science
Janelle Veazey, Laura Ritenour, Holly Ross, Shaun Egolf Department of
Biological Science
Sarah Robitaille, Elliot Rossomme, Department of Chemistry and
Biochemistry
At
One College Ave Suite 3034
Mechanicsburg PA, 17055
USA
2. Page 1 of 7
Summary
The Sawyer Bucket Filter was tested for its ability to remove three microorganisms –
Raoultella terrigena, Bacillus subtilis, and Micrococcus luteus – using USEPA approved
procedures. The organisms were added to test water to reach a 107
– 108
initial
concentration. The test water followed the criteria set forth by the USEPA 1987,
following the conditions for “test water #3”. All of the three tested filters met the target
reduction of 6 log units, or 99.9999% for all runs. The Sawyer Bucket Filter meets the
USEPA standard for bacteria.
Table 1. Mean log removal values (LRV) with standard error for three Sawyer Bucket
filter tests. Water was collected and microbiologically analyzed after 100, 500 and 900
milliliters passed through the filter.
Passed through filter
Organism 100 500 900
M. luteus 8.554 (0.1455) 8.554 (0.1455) 8.554 (0.1455)
B. subtilis 8.778 (0.3653) 8.014 (0.5569) 8.124 (0.4618)
R. terrigena 10.168 (0.4070) 9.930 (0.1685) 9.746 (0.0155)
3. Page 2 of 7
Introduction
Filtration is “a pressure- or vacuum-driven separation process in which particulate matter
larger than 1µm is rejected by an engineered barrier primarily through a size exclusion
mechanism and which has a measureable removal efficiency of a target organism that can
be verified through the application of a direct integrity test” (40 CFR 141.2). The Sawyer
filters underwent challenge testing with specific microorganisms to determine if the filter
performed as a barrier. Standard United States Environmental Protection Agency
(USEPA) approved procedures were followed.
A minimum of three Sawyer Bucket filters were tested in triplicate. The filters were
conditioned with a 5% chlorine solution and sterile test water at 20 psi. The challenge
microorganism (Table 2) was mixed with test water to obtain a 107
cells/100 mL
concentration and was forced through the Sawyer filters at 10 psi. 100mL of filtrate was
collected in a sterile whirl pak after 100, 500 and 900 milliliters passed through the
Sawyer Bucket filter and analyzed for microbial growth using the membrane filtration
technique following Standard Methods 9222. (APHA et al., 2012).
Surrogate organisms of similar size, approved by the USEPA, were used in place of the
pathogenic target organisms to avoid unnecessary safety hazards.
Table 2. Challenge test organisms and USEPA approved surrogates (USEPA, 2005 and
NSF 2005)
Target Organism Surrogate Size range (µm)
Fecal Coliform (bacteria) Raoultella terrigena (ATCC 33628) 2-4
Cryptosporidium Bacillus subtilis 5-7
Giardia Micrococcus luteus 10-12
In the USEPA Guide Standard and Protocol for Testing Microbiological Water Purifiers
(1987), it states a minimum reduction for protozoan parasites of log 3 units and a
minimum of 6 log units for bacteria. All targeted log reductions for surrogates were set at
a 6 log units, or 99.9999% reduction.
4. Page 3 of 7
Methods
Stock cultures were quadrant streaked onto Trypticase soy agar (TSA) plates and
incubated at 32°C for 24 hours. A pure culture was selected from the plate. The pure
culture was inoculated into a 250ml flask containing 100ml of Trypticase soy broth
(TSB). The flask was placed on a multiplatform shaker and incubated at 32°C overnight
to grow the cells to stationary phase. The cells were counted using a Petroff-Hauser
counting chamber. The test water was inoculated to obtain a final density in the 107
-108
cells/100ml range.
Test Water and Solutions:
Test Water: The water used for testing was obtained from the Yellow Breeches Creek,
which is the source for municipal drinking water in Cumberland and York Counties in
Pennsylvania. Water was collected in a 20L carboy and autoclaved at 121°C (15 lb
pressure) for 35 minutes to obtain sterile test water. 1 L of the test water was aseptically
adjusted for the following conditions for “test water #3” (USEPA 1987).
• pH adjusted to 9 by using HCl or NaOH, SM 4500- H+
B
• Total Organic Carbon minimum of 10 mg/L adjusted with humic acid, SM 5310
C
• Turbidity 30 NTU (Nephelometric Turbidity Unit) or greater, adjusted with
Kaolin or Arizona Road dust, SM 2130B/Method 2
• Total dissolved solids were 1,500 mg/L ± 150 mg/L, TDS meter tested
• Temperature of test water was chilled to 4°C ± 1°C, SM 2550 B
Standard methods (APHA et al., 2012) were followed to ensure test water conditions.
1.1L of challenge test water was dispensed into 2L vacuum bottles (Nalgene) and
autoclaved at 121°C (15 lb pressure) for 30 minutes. The final pH was 9.0 ± 0.2, turbidity
100NTU, TOC 15.5 mg/L, and TDS 1400 mg/L. The challenge test water bottles were
placed in a refrigerator to attain a temperature of 4°C prior to testing.
Trypticase Soy Broth (TSB) (BD Diagnostic Systems)
Into 1 L of reagent grade distilled water, dissolved 30g dehydrated TSB. The media was
then dispensed in culture tubes and 250ml flasks, covered with caps/foil and autoclaved
at 121°C (15 lb pressure) for 15 minutes.
Trypticase Soy Agar (TSA) (BD Diagnostic Systems)
To 1 L of reagent grade distilled water, dissolved 40 g dehydrated TSA in a flask and
heated to boiling with stirring until the ingredients dissolved. The media was then
5. Page 4 of 7
autoclave at 121°C (15 lb pressure) for 15 minutes and cooled in a 50°C water bath. The
agar was then aseptically poured agar into 50x9mm petri dishes to 4-5mm depth (7 ml)
and allowed to solidify. The plates can be stored for up to two weeks in the refrigerator.
Bacterial Test Water Preparation
Saturated cultures of each bacterial strain were prepared by inoculating 10 mL of TSB
with the test organisms and incubated on a rollodrum overnight at 32o
C. The following
day the cultures were counted using a Petroff Hausser counting chamber and
appropriately diluted so that the final concentration of bacteria in the 1.1 L testing sample
was 1 x 107
– 108
cells/L.
Pressurizing device
All tubing, bottles, caps, and glassware were washed and autoclaved prior to each
trial. Initial conditioning of the Sawyer Bucket Filter was attained by passing 1 L of 5%
bleach solution followed by 2 L of test water (without organisms) through the filter at
20psi (Fig. 1). The last liter of test water was collected as negative controls at 100, 500
and 900 milliliters in sterile Whirl paks. Challenge test water (with organisms) were
forced through the Sawyer Bucket Filter at 10 psi. Collection of filtrate was performed at
100, 500, and 900 milliliters in sterile Whirl paks.
Figure 1. Pressurizing device for forcing challenge water through the Sawyer filter.
Microbiological analysis
Standard Methods 9222 (APHA et al. 2012) were followed, the following description
is abbreviated. Shake the 100ml sample vigorously. Pour 100ml of sample into the
funnel and apply vacuum. Filter the sample and rinse the funnel walls three times with
6. Page 5 of 7
20-30 ml sterile deionized distilled water. Turn off vacuum and lift off the funnel top.
Using sterile forceps, transfer the filter to the prepared petri dish. With a slight rolling
motion, place the filter grid side up on the agar surface. Make sure the filter touches the
entire agar surface. Incubate at 35 ± 0.5°C for 48 hours, count colonies at 24 and 48
hours.
Initial seed counts were confirmed by serial dilution, using 99ml sterile deionized
distilled water blanks. The final dilution for plating was 10-6
and 10-7
.
Calculations:
Colony forming units (cfu)
Cfu/100ml = 100 x (number of colonies)/ volume of sample filtered in mL
Log removal value (LRV), target is 6 log unit reduction.
LRV= log (Cf) – log (Cp)
Cf =feed concentration (cfu/100ml)
Cp= filtrate concentration (cfu/100ml)
Results
All trials had comparable outcomes of zero or minimal cfu/100ml (Table 3). All trials
attained 6 log unit reduction or higher, even for trials where some bacteria passed through
the filter (Table 4).
Table 3. Challenge filtration test trials on the Sawyer Bucket HFM. Filtrate collected at
100, 500, and 900 milliliters underwent microbiological membrane filtration, values are
expressed as colony forming units per 100 milliliters (cfu/100ml).
Trial Organism Initial seed 100 500 900
1 M. luteus 1.13 x 108
0 0 0
B. subtilis 8.81 x 108
0 0 0
R. terrigena 4.04 x 1010
0 0 0
Negative control 0 0 0
2 M. luteus 2.56 x 108
0 0 0
B. subtilis 1.20 x 108
0 0 0
R. terrigena 5.77 x 109
0 0 0
Negative control 0 0 1
3 M. luteus 5.00 x 108
0 1 0
B. subtilis 2.05 x 109
1 196 92
R. terrigena 3.76 x 1010
0 3 7
Negative control 0 0 0
7. Page 6 of 7
Table 4. Log removal values (LRV) on the Sawyer Bucket HFM test trials. 6 log unit
reduction or greater was the target range.
Trial Organism 100 500 900
1 M. luteus 8.053 8.053 8.053
B. subtilis 8.945 8.945 8.945
R. terrigena 10.606 10.606 10.606
2 M. luteus 8.408 8.408 8.408
B. subtilis 8.079 8.079 8.079
R. terrigena 9.761 9.761 9.761
3 M. luteus 8.699 8.699 8.699
B. subtilis 9.311 7.019 7.347
R. terrigena 10.575 10.098 9.730
Back flushing was performed to demonstrate the effectiveness of the filter performing as
a barrier. Back flush recovery showed two log reduction after 1 liter of test water passed
through the filter (Table 5). This back flush test demonstrated that the Sawyer Bucket
HFM truly is a barrier.
Table 5. Back flush recovery test trials on the Sawyer Bucket HFM. Filtrate collected at
100, 500, and 900 milliliters underwent microbiological membrane filtration, values are
expressed as colony forming units per 100 milliliters (cfu/100ml).
.
Back flush
Trial Initial 100 500 900
1 4.405 x 108
5.00 x 109
4.35 x 109
9.69 x 107
2 1.043 x 109
1.91 x 109
2.34 x 108
3.50 x 108
3 2.027 x 1010
7.25 x 109
6.00 x 109
3.08 x 109
Discussion
All of the three Bucket Filters tested showed a 6 fold or greater reduction of the test
organisms, indicating the filters successfully remove the organisms from the challenge
water. If the surrogate organisms, M. luteus and B. subtilis, were held to the EPA
standard for Giardia and Cryptosporidium, respectively, then only a 3 log reduction
would be required. Thus, the filter would have met the EPA standard for both bacteria
and protozoans. These tests show that the Sawyer Bucket filter meets the USEPA
standard for bacterial removal.
8. Page 7 of 7
References
American Public Health Association (APHA), American Water Works Association
(AWWA), and Water Environment Federation (WEF) 2012. Standard Methods
for the Examination of Water and Wastewater. 22nd
ed. American Water Works
Association.
Federal Register 2012. National Primary Drinking Water Standards. 40 CFR 141.2
NSF International. 2005. EPA/NSF ETV Equipment Verification Testing Plan for the
Removal of Microbiological and Particulate Contaminants by Membrane
filtration. Ann Arbor, MI.
USEPA 1987. Guidance Manual for Compliance with the Filtration and Disinfection
Requirements for Public Water Systems Using Surface Water Sources Appendix
O: Guide Standards and Protocol for Testing Microbiological Water Purifiers.
Contract No. 68-01-6989 U. S. Environmental Protection Agency, Office of
Water and Office of Research and Development, Washington, DC.
USEPA 2005. Membrane Filtration Guidance Manual. EPA 815-R-06-009 U. S.
Environmental Protection Agency, Office of Water and Office of Research and
Development, Washington, DC.