Collaborative trial of the direct epifluorescent filter technique (DEFT), a rapid method for counting bacteria in milk

The direct epifluorescent filter technique (DEFT) is a new rapid method which uses membrane filtration and epifluorescent microscopy for counting bacteria in milk. A collaborative trial of the DEFT was conducted between six laboratories. Each laboratory obtained a highly significant relationship between the DEFT count and plate count with a correlation coefficient generally > 0.9 but there were significant differences between these relationships. The repeatability of the DEFT, although ca 1·5 times worse than that of the plate count, was of a level acceptable in practice. Reproducibility of the DEFT was ca 3 times that of the plate count. This poor reproducibility was probably mainly due to counting errors. Possible reasons for this and ways of reducing counting errors are discussed.     

A modified direct epifluorescent filter technique for the detection and enumeration of yeast in yoghurt

A modified direct epifluorescent filter technique (DEFT) for the detection and enumeration of visible yeast in fruit-flavoured yoghurt is described. The method involves an initial enrichment in oxytetracycline glucose yeast peptone broth (OGYP, 30C/24, 48 h), prefiltration prior to DEFT and use of the vital stain Viablue 1. Additional yoghurt samples were subjected to prolonged incubation at 12C or spiked with Kluyveromyces fragilis . When DEFT was compared with the plate count, regression and correlation coefficients of 1.12 and 0.85 respectively were obtained for values above the sensitivity threshold of DEFT (10³ cells/ml). The use of an enrichment stage (OGYP, 30C/24 h) enabled, by calculation, a theoretical minimum yeast contamination level of 7 yeast cells/g in the original yoghurt to be detected assuming the cells exhibit no lag phase of growth.     

The direct epifluorescent filter technique (DEFT): increased selectivity, sensitivity and rapidity

With the direct epifluorescent filter technique (DEFT), differentiation of bacteria was achieved by a modified Gram-staining procedure using acridine orange as the counterstain. The method enumerated viable Gram-negative and all Gram-positive bacteria. Counts of clumps of orange fluorescent cells (Gram-negative DEFT count) correlated well with colony counts of Gram-negative bacteria in samples of raw milk ( r = 0·94). The use of stainless steel membrane filter supports and the addition of citrate-NaOH buffer (0·1 M, pH 3·0) during filtration enabled 10 ml samples of milk to be filtered, thereby increasing the sensitivity of the DEFT five-fold. The relationship between colony and DEFT counts with 10 ml samples was better ( r = 0·90) than that using standard 2 ml samples ( r = 0·88). Alternatively, these modifications in procedure allowed the preincubation time for 2 ml milk samples to be reduced from 10 to 2 min. Sonication was successful in dispersing bacterial clumps in both pure cultures and in raw milk samples to yield a bacterial count by DEFT which should give a better indication of the hygienic status and keeping quality of a product, than counts of colony forming units.     

Use of the direct epifluorescent filter technique for the enumeration of yeasts

The ability of the direct epifluorescent filter technique (DEFT) to enumerate the viable numbers of various species of yeasts was evaluated. A DEFT count could be made in less than 10 min and the DEFT counts of non-heat-treated samples agreed well with plate counts. The DEFT was unsuitable for the enumeration of yeasts in heat-treated samples because non-viable cells fluoresced orange. A double staining technique using Janus Green B and acridine orange was developed to overcome this problem. The modified DEFT enabled viable and non-viable yeasts to be differentiated in heat-treated samples of pure cultures and improved the relationship between the DEFT count and plate count. The method proved to be of little value, however, for use with beverage products because of unreliable staining patterns.     

The direct epifluorescent filter technique (DEFT): increased selectivity, sensitivity and rapidity

With the direct epifluorescent filter technique (DEFT), differentiation of bacteria was achieved by a modified Gram-staining procedure using acridine orange as the counterstain. The method enumerated viable Gram-negative and all Gram-positive bacteria. Counts of clumps of orange fluorescent cells (Gram-negative DEFT count) correlated well with colony counts of Gram-negative bacteria in samples of raw milk (r = 0.94). The use of stainless steel membrane filter supports and the addition of citrate-NaOH buffer (0.1 M, pH 3.0) during filtration enabled 10 ml samples of milk to be filtered, thereby increasing the sensitivity of the DEFT five-fold. The relationship between colony and DEFT counts with 10 ml samples was better (r = 0.90) than that using standard 2 ml samples (r = 0.88). Alternatively, these modifications in procedure allowed the preincubation time for 2 ml milk samples to be reduced from 10 to 2 min. Sonication was successful in dispersing bacterial clumps in both pure cultures and in raw milk samples to yield a bacterial count by DEFT which should give a better indication of the hygienic status and keeping quality of a product, than counts of colony forming units.     

A bacteriostatic mixture for milk samples and its effect on bacteriological, cytological and chemical compositional analysis

Of the bacteriostats tested, that comprising boric acid, glycerol, potassium sorbate and nystatin was the most suitable in preventing the multiplication of bacteria, yeasts and moulds in milk whilst causing least change in the Direct Epifluorescent Filter Technique (DEFT) count of bacteria and somatic cells. The DEFT and plate count of bacteria and the DEFT count of somatic cells were reduced after preservation and storage. The relationships between the plate count of fresh milk samples and the DEFT count and plate count of the same samples after preservation and storage for 3 d at room temperature (20–22°C) had correlation coefficients ( r ) of 0.80 and 0.85, respectively. The relationship between the Coulter count of somatic cells in fresh milk and the DEFT count of somatic cells in stored preserved milk had a correlation coefficient of 0.90. The addition of the bacteriostatic mixture to milk affected the determination of protein by the Milkoscan and lactose by the Infra Red Milk Analyser. It did not affect the estimation of the other milk components (fat, protein or lactose) by either instrument.     

Use of the Direct Epifluorescent Filter Technique for predicting the keeping quality of pasteurized milk within 24 hours

The keeping quality (KQ) of pasteurized milk stored at 5 degrees C and 11 degrees C was predicted within 24 h by pre-incubating samples and counting bacteria by the Direct Epifluorescent Filter Technique (DEFT). For samples from 5 degrees C storage, 0.03% (w/v) benzalkonium chloride and 0.002% (w/v) crystal violet (final concentration) were added to inhibit the growth of Gram positive bacteria during pre-incubation. The samples from milk stored at 11 degrees C were pre-incubated without the addition of inhibitors. After pre-incubation there was a satisfactory relationship between the DEFT count and the KQ of milks at both 5 degrees C and 11 degrees C. The DEFT count following pre-incubation correctly classified greater than 80% of pasteurized milks on the basis of KQ.     

Semi-automated counting of bacteria and somatic cells in milk using epifluorescence microscopy and television image analysis

An epifluorescent microscope fitted with a 'Chalnicon' closed circuit television camera linked to an Optomax System III image analyser was used to count bacteria and somatic cells on membrane filters prepared from milk by the direct epifluorescent filter technique (DEFT). For both bacteria and somatic cells, the semi-automated DEFT count of low count milk exceeded the visual DEFT count but this difference became proportionately less as the count increased. There was close agreement between the semi-automated and visual DEFT counts over the range 10⁵-5 times 10⁶/ml for bacteria and 3 times 10⁵-5 times 10⁶/ml for somatic cells. The semi-automated DEFT count of bacteria and somatic cells correlated well with the plate count and Coulter count respectively, with correlation coefficients of 0.83 and 0.81.     

Use of the Direct Epifluorescent Filter Technique for predicting the keeping quality of pasteurized milk within 24 hours

The keeping quality (KQ) of pasteurized milk stored at 5°C and 11°C was predicted within 24 h by pre-incubating samples and counting bacteria by the Direct Epifluorescent Filter Technique (DEFT). For samples from 5°C storage, 0.03% (w/v) benzalkonium chloride and 0.002% (w/v) crystal violet (final concentration) were added to inhibit the growth of Gram positive bacteria during pre-incubation. The samples from milk stored at 11°C were pre-incubated without the addition of inhibitors. After pre-incubation there was a satisfactory relationship between the DEFT count and the KQ of milks at both 5°C and 11°C. The DEFT count following pre-incubation correctly classified > 80% of pasteurized milks on the basis of KQ.     

The detection of irradiated foods using the Direct Epifluorescent Filter Technique

A method was evaluated which has the potential to detect a food sample which has been irradiated. The technique will give an indication of the total number of viable micro-organisms present before irradiation. It is based on the comparison of an aerobic plate count (APC) with a count obtained using the Direct Epifluorescent Filter Technique (DEFT). When the APC of an irradiated sample was compared with the DEFT count on the same sample, the APC was considerably lower than that obtained by DEFT. The count of orange fluorescing cells after irradiation, however, correlated well with an APC of the same sample before irradiation. For the samples examined the DEFT count determined the viable microbial population in the sample before irradiation. The difference between the APC and the DEFT count gave the number of organisms rendered non-viable by the process.     

Detection of low numbers of osmophilic yeasts in creme fondant within 25 h using a pre-incubated DEFT count

The results presented show that the direct epifluorescent filter technique (DEFT) can be used to detect low numbers of osmophilic yeasts in creme fondant after pre-incubation, or high numbers without pre-incubation, and within 30 min. Pretreatment with trypsin and Triton X-100 was necessary to achieve efficient filtration of the fondant. The detection limits for osmophilic yeasts in the pre-incubated DEFT count, as extrapolated from the initial plate count, were approximately 1/g after 25 h and 1/10 g after 49 h.     

Use of the direct epifluorescent filter technique for the enumeration of yeasts

The ability of the direct epifluorescent filter technique (DEFT) to enumerate the viable numbers of various species of yeasts was evaluated. A DEFT count could be made in less than 10 min and the DEFT counts of non-heat-treated samples agreed well with plate counts. The DEFT was unsuitable for the enumeration of yeasts in heat-treated samples because non-viable cells fluoresced orange. A double staining technique using Janus Green B and acridine orange was developed to overcome this problem. The modified DEFT enabled viable and non-viable yeasts to be differentiated in heat-treated samples of pure cultures and improved the relationship between the DEFT count and plate count. The method proved to be of little value, however, for use with beverage products because of unreliable staining patterns.     

The use of direct epifluorescent microscopy (DEM) and the direct epifluorescent filter technique (DEFT) to assess microbial populations on food contact surfaces

Two rapid methods, direct epifluorescent microscopy (DEM) and the direct epifluorescent filter technique (DEFT) on swab resuspension fluids, were compared with the traditional total viable count (TVC) on swab resuspension fluids for their ability to enumerate surface populations of attached bacteria. The degree of error in estimating surface populations was shown to be significantly less with DEM than DEFT followed by TVC. DEM estimated populations in the range 3 x 10(3) to 5 x 10(7) colonies/cm2 whilst DEFT enumerated populations above 3 x 10(4) colonies/cm2 and TVC above 3 x 10(5) colonies/cm2 (as measured by DEM). Swabbing was shown to remove a constant proportion of organisms from the surface populations tested, although below 3 x 10(5) colonies/cm2 most of the organisms remained in the cotton matrix and were difficult to resuspend. DEFT was more able to enumerate swab resuspension fluids obtained from surface populations below 3 x 10(5) colonies/cm2 than was TVC.     

The use of direct epifluorescent microscopy (DEM) and the direct epifluorescent filter technique (DEFT) to assess microbial populations on food contact surfaces

Two rapid methods, direct epifluorescent microscopy (DEM) and the direct epifluorescent filter technique (DEFT) on swab resuspension fluids, were compared with the traditional total viable count (TVC) on swab resuspension fluids for their ability to enumerate surface populations of attached bacteria. The degree of error in estimating surface populations was shown to be significantly less with DEM than DEFT followed by TVC. DEM estimated populations in the range 3 times 10³ to 5 times 10⁷ colonies/cm² whilst DEFT enumerated populations above 3 times 10⁴ colonies/cm² and TVC above 3 times 10⁵ colonies/cm² (as measured by DEM). Swabbing was shown to remove a constant proportion of organisms from the surface populations tested, although below 3 times 10⁵ colonies/cm² most of the organisms remained in the cotton matrix and were difficult to resuspend. DEFT was more able to enumerate swab resuspension fluids obtained from surface populations below 3 times 10⁵ colonies/cm² than was TVC.     

The detection of irradiated foods using the Direct Epifluorescent Filter Technique

A method was evaluated which has the potential to detect a food sample which has been irradiated. The technique will give an indication of the total number of viable micro-organisms present before irradiation. It is based on the comparison of an aerobic plate count (APC) with a count obtained using the Direct Epifluorescent Filter Technique (DEFT). When the APC of an irradiated sample was compared with the DEFT count on the same sample, the APC was considerably lower than that obtained by DEFT. The count of orange fluorescing cells after irradiation, however, correlated well with an APC of the same sample before irradiation. For the samples examined the DEFT count determined the viable microbial population in the sample before irradiation. The difference between the APC and the DEFT count gave the number of organisms rendered non-viable by the process.     

Rapid enumeration of microorganisms in foods by the direct epifluorescent filter technique.

Filtration of "stomachered" food suspensions through nylon filters (pore size, 5 microns) removed most of the food debris without affecting the recovery of microorganisms. Two to ten milliliters of these prefiltered suspensions could be filtered in the direct epifluorescent filter technique (DEFT). The technique takes less than 30 min to complete and has a lower sensitivity of less than 60,000 microorganisms per g for all products examined. Vegetative bacterial cells, spores, fungal hyphae, and yeasts could be distinguished with the technique. For fresh meat and fish, the DEFT count of prefiltered suspensions agreed well with the plate count of unfiltered suspensions over the range of 10(4) to 10(10)/g (correlation coefficient of 0.91). For frozen meat and fish and frozen vegetables, the two counting methods had correlation coefficients of 0.87 and 0.66, respectively. The poor correlation for frozen vegetables was due to the inclusion in the DEFT count of nonviable bacteria killed by the blanching process used to inactivate enzymes. Good agreement was obtained between the prefiltered DEFT count and unfiltered plate count for cooked meats, cream doughnut, and whole peppers. Possible reasons for the poor agreement between the DEFT count and plate count for certain products are discussed.     

Analysis of high-quality pharmaceutical grade water by a direct epifluorescent filter technique microcolony method

A modified direct epifluorescent filter technique (DEFT) was used to assess the microbial quality of water. Sterile, pharmaceutical grade water was inoculated with Pseudomonas cepacia. Microcolonies were grown and counted with a Bio-Foss System 3 DEFT apparatus. In this way it was possible to achieve a sensitivity of 10 cfu per 100 ml. Results were obtained within 1 working day.     

Rapid Enumeration of Bacteria in Heat-treated Milk and Milk Products Using a Membrane Filtration-Epifluorescent Microscopy Technique

A rapid direct epifluorescent filter technique (DEFT), taking ca. 20 min to complete, was used to enumerate bacteria in heat-treated milk and milk-products. The DEFT count could detect as few as 5750 bacteria/ml in pasteurized and skim milk, pasteurized cream, whey and sweet cream butter and was in agreement with the standard plate count. The technique was also used to determine the sterility of cartoned ultra heat-treated milk after incubation at 37°C. The agreement between the DEFT and plate count was poor for evaporated and condensed milks, some reconstituted skim milk powders, pasteurized whey and ripened cream butter. Possible reasons for this are discussed.     

Detection of irradiated deep-frozen foodstuffs by comparison of DEFT and APC counts

The suitability of a microbiological method based on the comparison of an aerobic plate count (APC) with a count obtained with the direct epifluorescent filter technique (DEFT) for the detection of irradiation of deep-frozen foodstuffs was evaluated. The study was carried out on parsley, mechanically deboned poultry meat (MDPM) and liquid egg white. The foodstuffs were stored at—18°C and examined after storage for 0, 4 and 12 months.
The results showed that this method is discriminating during the whole storage period. Nevertheless, it has been observed that for non-irradiated liquid egg white the difference between DEFT and APC tends to increase with the time of storage. This phenomenon which did not limit the interest of the test, was not observed for the other products tested.