Title of Invention

A TEST MEDIUM SUITABLE FOR DETECTING,QUANTIFYING OR DIFFERENTIATING GENERAL COLIFORMS,E.COLI,AEROMONAS AND SALMONELLA

Abstract A test medium and method for detecting, quantifying, identifying and differentiating up to four (4) separate biological materials in a test sample. A test medium is disclosed which allows quantifying and differentiating under ambient light aggregates of biological entities producing specific enzymes, which might include general coliforms, E. coli, Aeromonas, and Salmonella in a single test medium. A new class of nonchromogenic substrates is disclosed which produce a substantially black, non-diffusible precipitate. This precipitate is not subject to interference from other chromogenic substrates present in the test medium. In one embodiment, the substrates are selected such that E. coli colonies present in the test medium show as substantially black, general coliforms colonies show in the test medium as a blue-violet color, Aeromonas colonies present in the test medium show as a generally red- pink color, and Salmonella colonies show as a generally teal-green color. Other microorganisms and color possibilities for detection and quantification thereof are also disclosed. An inhibitor and method for making a test medium incorporating the inhibitor are disclosed.
Full Text WO 2006/107583 PCT/US2006/010177
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TEST MEDIA AND QUANTITATIVE OR QUALITATIVE METHOD
FOR IDENTIFICATION AND DIFFERENTIATION
OF BIOLOGICAL MATERIALS IN A TEST SAMPLE
Background of the Invention
The present invention relates to a test medium and method for the
detection, quantification, identification and/or differentiation of biological
materials in a sample, which may contain a plurality of different biological
materials.
Bacteria are the causative factor in many diseases of humans, higher
animals and plants, and are commonly transmitted by carriers such as water,
beverages, food and other organisms. The testing of these potential carriers of
bacteria is of critical importance and generally relies on "indicator organisms."
Borrego et al., Microbiol. Sem. 13:413-426, (1998). For example, Escherichia
coli (E. coli) is a gram negative member of the family Enterobacteriaceae
which is part of the normal intestinal flora of warm blooded animals, and its
presence indicates fecal contamination {e.g., raw sewage). Even though most
strains of E. coli are not the actual cause of disease, their presence is a strong
indication of the possible presence of pathogens associated with intestinal
disease, such as cholera, dysentery, and hepatitis, among others.
Consequently, E. coli has become a prime indicator organism for fecal
contamination, and as a result, any method which differentiates and identifies
E. coli from other bacteria is very useful.
Others members of the family Enterobacteriaceae, commonly referred
to as "general coliforms," especially the genera Citrobacter, Enterobacter and
Klebsiella, are also considered to be significant indicator organisms for the
quality of water, beverages and foods. Therefore, tests to identify and
differentiate general coliforms from E. coli are also very useful. Also, various
species of the genus Aeromonas have been shown to not only be potential
pathogens, but to have a correlation to other indicator organisms (Pettibone et
al., J Appl. Microbiol 85:723-730 (1998)). Current test methods to identify,
separate and enumerate Aeromonas spp. from the very similar
Enterobacteriaceae have been lacking and most of the current methods

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utilizing enzyme substrates do not separate Aeromonas spp. from
Enterobacteriaceae due to their almost identical biochemical profiles. Any
method that depends upon the identification of general coliforms by means of
a β-galactosidase substrate either does not differentiate Aeromonas spp. from
general coliforms or eliminates Aeromonas from the sample by the use of
specific inhibitors (antibiotic such as cefsulodin). Brenner et al., Appl. Envir.
Microbio. 59:3534-44 (1993). They do not differentiate, identify and
enumerate Aeromonas along with E. coli and general coliforms. Landre et al.,
Letters Appl Microbiol. 26:352-354(1998). Improved test methods to
effectively identify, separate and enumerate such bacterial types are needed,
and there is a continuing search for faster, more accurate, easier to use and
more versatile test methods and apparatus in this area.
Numerous test methods have been utilized to determine, identify and
enumerate one or more indicator organisms. Some of these test methods only
indicate the presence or absence of the microorganism, while others also
attempt to quantify one or more of the particular organisms in the test sample.
For example, a qualitative test referred to as the Presence/Absence (or P/A)
test, may be utilized to determine the presence or absence of coliforms and£.
coli in a test sample. A test medium including the β-galactosidase substrate O-
nitrophenyl--β-galactopyranoside (ONPG), and the β-glucuronidase
substrate 4-methyl-umbrelliferyl-β-D-glucuronide (MUG), is inoculated with
the test sample. To differentiate the general coliforms from E. coli, this test
relies on the fact that generally all coliforms produce |3-galactosidase, whereas
only E. coli also produces β-glucuronidase in addition to β- galactosidase. If
any coliforms are present (including E. coli), the broth medium turns a yellow
color due to the activity of the galactosidase enzyme on the ONPG material,
causing the release of a diffusible yellow pigment. If E. coli is present, the
broth medium will demonstrate a blue fluorescence when irradiated with
ultraviolet rays, due to the breakdown of the MUG reagent with the release of
the fluorogenic dye caused by the production of the glucuronidase enzyme.
These reactions are very specific, and allow the presence of both coliforms in
general, as well as E. coli to be identified in a single sample. A disadvantage

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of this test is that it is not directly quantitative for either bacterial type, since
both reagents produce diffusible pigments. A second disadvantage is that
there may a false positive coliform reaction if Aeromonas spp. are present in
the test sample. This has been shown to be possible even when there are
inhibitors present to supposedly prevent this from occurring (Landre et al.,
Letters Appl. Microbiol. 26:352-354 (1998)). The test also requires specific
equipment for producing the ultraviolet rays. Further, this test may only be
used to detect coliforms and E. coli. Other important microorganisms, such as
the strain E. coli 0157 which is glucuronidase negative, are not detected, nor
are other non-galactosidase-glucuronidase producing microorganisms.
The Violet Red Bile Agar (VRBA) method has been used to determine
the quantity of both coliform and E. coli in a test sample. The test medium
used in this method includes bile salts (to inhibit non-coliforms), lactose and
the pH indicator neutral red. As coliforms (including E. coli) grow in the
medium, the lactose is fermented with acid production, and the neutral red in
the area of the bacterial colony becomes a brick red color. The results of this
test are not always easy to interpret, and in order to determine the presence of
E. coli, confirming follow-up tests, such as brilliant green lactose broth
fermentation, growth in EC broth at 44.5°C and streaking on Eosin Methylene
Blue Agar (EMBA), must be performed.
The Membrane Filter (MF) method utilizes micropore filters through
which samples are passed so that the bacteria are retained on the surface of the
filter. This method is used most often when bacterial populations are very
small, and a large sample is needed to get adequate numbers. The filter is then
placed on the surface of a chosen medium, incubated, and the bacterial
colonies growing on the membrane filter surface are counted and evaluated.
This method is widely used and provides good results when combined with
proper reagents and media. A disadvantage of this method is that it is
expensive and time-consuming. It also does not work well with solid samples,
or samples with high particulate counts. The MF method can be used in
conjunction with the inventive method described in this application.

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The m-Endo method is also used to determine the quantity of E. coli
and general coliforms and is an official USEPA approved method for testing
water quality. The medium is commonly used with a membrane filter and E.
coli and general coliform colony forming units (CFU) grow as dark colonies
with a golden green metallic sheen. Due to a proven high rate of false positive
error, typical colonies must be confirmed by additional testing. Standard
Methodsfor the Examination of water and Wastewater, 20th Edition, 9-10 &9-
60(1998).
Other tests, such as the Most Probable Number (MPN), utilize lactose-
containing broths (LST, BGLB, EC) to estimate numbers of general coliforms
and E. coli, but have also been shown to have high rates or error as well as
being cumbersome and slow to produce results. Evans et al., Appl. Envir.
Microhiol. 41:130-138 (1981).
The reagent 5-bromo-4-chloro-3-indolyl-β-D-galactopyranoside
(X-gal) is a known test compound for identifying coliforms. When acted on
by the β-galactosidase enzyme produced by coliforms, X-gal forms an
insoluble indigo blue precipitate. X-gal can be incorporated into a nutrient
medium such as an agar plate, and if a sample containing coliforms is present,
the coliforms will grow as indigo blue colonies. X-gal has the advantage over
the compound ONPG, described above, in that it forms a water insoluble
precipitate rather than a diffusible compound, thereby enabling a quantitative
determination of coliforms to be made when the test sample is incorporated
into or onto a solidified medium, or when coliform colonies grow on the
surface of a membrane filter resting on a pad saturated with a liquid medium
, or on a membrane filter resting on a solid medium. Further, it does not require
the use of ultraviolet light.
A similar compound, 5-bromo-4-chloro-3-indolyl-β-D-glucuronide
(X-gluc) is a known test compound for identifying E. coli. When acted on by
the β-glucuronidase enzyme produced by most E. coli, X-gluc forms an
insoluble indigo blue precipitate. X-gluc has the advantage over the
compound MUG, described above, in that it forms a water insoluble
precipitate, rather than a diffusible compound, thereby enabling a quantitative

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determination of E. coli to be made when the test sample is incorporated into
or onto a solidified medium. X-gluc and its ability to identify E. coli are
described in Watkins, et al., Appl. Envir. Microbiol. 54:1874-1875 (1988). A
similar compound, indoxyl-β-D-glucuronide, which also produces sharp blue
colonies of E. coli, was described in Ley, et al., Can. J. Microbiol 34:690-693
(1987).
Although X-gal and X-gluc are each separately useful in the
quantitative determination of either conforms (X-gal) or E. coli (X-gluc), these
indicator compounds have the disadvantage that they each contain the same
chromogenic component. Therefore, they cannot be used together to identify
and distinguish both E. coli and general coliforms in a single test with a single
sample, since they both generate identically hued indigo blue colonies. A
person using both reagents together would be able to quantitatively identify
the total number of coliforms, the same as if X-gal were used alone, but would
not be able to indicate which of the colonies were E. coli and which were other
coliforms besides E. coli.
A recently developed and highly commercially successful test method
and test medium for quantitatively identifying and differentiating general
coliforms and E. coli in a test sample is described in U.S. Patent Nos.
5,210,022, and 5,393,662, both of which share common inventorship with the
present application and which are hereby incorporated by reference. This
method and test medium improves upon prior art methods by allowing the
quantitative identification of general coliforms and E. coli in a single sample.
Additional confirmatory tests are not necessary. The test sample is added to a
medium containing a β-galactosidase substrate, such as 6-chloroindolyl-β-D-
galactoside, and a β-glucuronidase substrate, such as 5-bromo-4-chloro-3-
indolyl-β-D-glucuronide (X-gluc). The β-galactosidase substrate is capable of
forming a water insoluble precipitate of a first color upon reacting with [3-
galactosidase, and the β-glucuronidase substrate is capable of forming a water
insoluble precipitate of a second color, contrasting with the first color, upon
reacting with β-glucuronidase. As a result, general coliforms may be
quantified by enumerating the colonies of the first color (having β-

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galactosidase activity), and E. coli may be quantified by enumerating the
colonies of the second color (having both β-galactosidase and β-glucuronidase
activity). This technology has been widely copied.
Another recently developed test method and apparatus provides
excellent results for the differentiation and identification of general coliforms,
E. coli and E. coli 0157 strains and non-coliform Enterobacleriaceae . The
method and test medium are described in U.S. Patent No. 5,726,031, which
shares common inventorship with the present application, and which is hereby
incorporated by reference.
A certain class of substrates, referred to herein as "nonchromogenic,"
have been used to detect various microorganisms. A dipslide for detecting E.
coli using hydroxy-quinoline- β-D-glucuronide is disclosed by Dalet et al., J
Clin. Microbiol, 33(5):1395-8 (1995). Similarly, a technique for detection of
E. coli in an agar-based medium using 8-hydroxyquinoline-β-D-glucuronide is
disclosed by James et al., Zentralbl Bakteriol Mikrobiol Hyg [A], 267(3):316-
21 (1988).
It is desirable to further improve the distinguishing colors generated in
the test media. That is to say, in prior art test media which detect and
distinguishing two biological entities, confusion may arise between the two
colors which show in the media.
Further, it is desirable to be able to identify and differentiate other
closely related organisms, such as members of the families Aeromonaceae,
Vibrionaceae, and Salmonella. For example, the genus Aeromonas is closely
related to coliforms and gives an almost identical biochemical test pattern.
Further, the genus Vibrio is also an important type of bacteria that grows under
the same general conditions as coliforms. It is known to distinguish
Aeromonas colonies from general coliforms by testing all colonies in a given
sample for the presence of cytochrome oxidase. Undesirably, however, this
requires another set of tests. Further, Aeromonas is common in water and
food, and it is commonly indicated in test samples as general coliforms, which
results in high a false positive error for general coliforms by most current test
methods. The Aeromonas can be prevented from interfering with the coliform

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results by adding certain antibiotics to the medium. However, the antibiotic
amounts added must be carefully controlled. Further, the antibiotics which
have been conventionally used have short life spans in the media so that they
lose their potency quickly in other than a frozen condition. It may often be
desirable to be able to culture, identify and enumerate Aeromonas spp. which
cannot be done if they are inhibited.
Further, in those cases where it is desirable to inhibit Aeromonas, it is
desirable for a better method of so doing, one in which the shelf life of the
medium is not appreciably reduced by the inclusion of an inhibitor.
Additionally, it is also desirable to distinguish strains of Salmonella
from E. coli, general conforms and Aeromonas.
Summary of the Invention
The present invention overcomes the disadvantages of prior art
methods by providing a test method and medium for quantitatively or
qualitatively identifying and differentiating biological entities in a test sample
that may include a plurality of different biological entities.
In one embodiment, the present invention introduces the use of
"nonchromogenic" substrates to enhance the distinction among multiple colors
produced by distinct biological entities present in the inventive test medium.
Unexpectedly, it has been discovered that other "chromogenic" substrates
present in the inventive test medium do not interfere with the substantially
black color achieved with the nonchromogenic substrate. That is to say, so
long as a given biological entity is responsive to the nonchromogenic
substrate, aggregations thereof present in the test medium will show as a
substantially black color-independent of whether such biological entity is
responsive to one, two or more chromogenic substrates which are also present
in the medium. The present invention exploits this hitherto unexplored
property of nonchromogenic substrates.
In one form thereof, the present invention provides a test medium for
detecting, identifying and qualifying or quantifying first and second biological
entities. The test medium includes a nutrient base medium including ions of a
salt, a chromogenic substrate and a nonchromogenic substrate. The First

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biological entity is responsive to the nonchromogenic substrate whereas the
second biological entity is responsive to the chromogenic substrate. In this test
medium, aggregations of the first biological entity present in the test medium
are substantially black and aggregations of the second biological entity present
in the test medium are a second color, the second color being distinguishable
from the substantially black.
In one form, the inventive test medium accounts for the first biological
entity being responsive to the chromogenic substrate in addition to the
nonchromogenic substrate. In such event, aggregations of the first biological
entity present in the test medium will nonetheless show as substantially black.
Significantly, even though the aggregations of the first biological entity
are responsive to both the first and second substrates in this form, these
aggregations still show as substantially black in the test medium. That is, the
chromogenic substrate does not interfere with the substantially black color.
Advantageously, this property of nonchromogenic substrates allows several
different biological entities to be identified and differentiated in a single
medium, aggregations of each biological entity having a visually
distinguishable color.
In another form of the above-described inventive medium, the medium
further includes the antibiotic nalidixic acid to inhibit the growth of
Aeromonas, spp. Advantageously, it has been found that nalidixic acid, as
compared with cefsulodin, does not significantly reduce the shelf life of the
test medium incorporating it.
In this connection, another form of the present invention provides a
method of making a test medium for detecting at least one first type of
biological entity and inhibiting a second type of biological entity from
growing in the medium. The method includes the steps of combining desired
substrates with a nutrient base medium; adding an inhibitor to the medium;
and then sterilizing the medium by subjecting the medium to at least 100°C.
Because the inhibitor is added as an initial step, subsequent sterile addition of
inhibitor is unnecessary.

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In another form thereof, the present invention provides a test medium
for detecting, identifying and qualifying or quantifying first, second and third
biological entities. The test medium includes a nutrient base medium including
ions of a salt. First and second chromogenic substrates and a nonchromogenic
substrate are provided in the test medium. The first and second biological
entities are responsive to the first and the second chromogenic substrates,
respectively, and the third biological entity is responsive to the
nonchromogenic substrate. Aggregations of the first biological entity present
in the test medium are a first color, aggregations of the second biological
entity present in the test medium are a second color, and aggregations of the
third biological entity present in the test medium are substantially black.
In one form, the inventive test medium accounts for the third biological
entity being responsive to the first and/or the second chromogenic substrates
in addition to the nonchromogenic substrate. In such event, aggregations of
the third biological entity will nonetheless show as substantially black.
It should be appreciated that the use of a nonchromogenic substrate
along with one or more chromogenic substrates synergistically increases the
number of biological entities that can be detected and distinguished in a single
medium and synergistically increases the possible color combinations for a
given set of biological entities to be detected. Stated another way, including a
nonchromogenic component as one of the substrates synergistically increases
the degrees of freedom in selecting other substrates and corresponding colors
for a test medium. This is so because an aggregation of the biological entity
which is responsive to the nonchromogenic substrate will dependably show as
substantially black. No combined color effects need be accounted for with the
nonchromogenic substrates. For example, in a test medium including three
chromogenic substrates and a nonchromogenic substrate, at least three
combined color combination effects are avoided by using the one
nonchromogenic component, as compared with using four chromogenic
components.
The present invention, in another form thereof, provides a test medium
capable of detecting, quantifying, and differentiating general coliforms and/or

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E. coli spp. under ambient light. The test medium comprises a nutrient based
medium including a salt. A first substrate capable of forming a first water
insoluble component of a first color in the presence of E. coli and the ions of
the salt is provided in the medium. The first color is substantially black. A
second substrate capable of forming a second water insoluble component of a
second color in the presence of general coliforms is provided. The second
color is visually distinguishable from the first color. Thus, colonies of E. coli
present in the test medium are indicated by the first substantially black color
and colonies of general coliforms are indicated by the second color.
In one form of the above invention, the test medium further includes a
third substrate capable of forming a third water insoluble component of a third
color in the presence of Salmonella. The third color is distinguishable from
the first and second colors, whereby the test medium is capable of quantifying
and/or differentiating E. coli, general coliforms and Salmonella. Further, the
substrates are selected such that general coliforms present in the test medium
will also react with the third substrate to form a water insoluble component
which includes the third color. Consequently, general coliform colonies are
indicated in the test medium as a fourth color, the fourth color being a
combination of the second color and the third color. The fourth color is
visually distinguishable from the first and third colors. Still further, the
substrates can be selected such that Aeromonas spp. form an insoluble
component of the second color by reacting with the second substrate, but not
the first and third substrates. Thus, in the inventive test medium, E. coli
colonies will be generally black, general coliform colonies will be the fourth
color, Aeromonas colonies will be the second color and Salmonella colonies
will be the third color.
In another form thereof, the present invention provides a method for
detecting, quantifying and differentiating under ambient light general
coliforms, E. coli, and at least one of the genera Aeromonas ox Salmonella in a
test sample. The method comprises the steps of providing a nutrient base
medium including first, second and third substrates. Each of the substrates is
capable of forming a water insoluble component in the presence of at least one

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of general coliforms, E. coli, Aeromonas, Salmonella. The substrates are
selected such that colonies of E. coli produced in the test medium are a first
color, colonies of general coliforms produced in the test medium are a second
color, and colonies of one of Aeromonas and Salmonella produced in the test
medium are a third color. Each of the colors are visually distinguishable. The
test medium is inoculated with the test sample and then incubated. The test
medium is then examined for the presence of first colonies having the first
color, second colonies having the second color, and third colonies having the
third color. The first colonies are E. coli, the second colonies are general
coliforms, and the third colonies are one of Aeromonas or Salmonella.
In one form thereof, the inventive method further includes adding ions
from a salt to the test medium to react with one or more of the substrates. In
so doing, a precipitate is produced which shows as a substantially black color
in the presence of the specific enzyme for that substrate. A preferred
compound for forming the substantially black color in the presence of the ions
of the salt consists of a β-D-glucuronide. These compounds release an
aglycone when hydrolized which forms a substantially black insoluble
complex in the presence of ions.
In another form of the inventive method, the method further comprises
examining the test medium for the presence of fourth colonies having a fourth
color, wherein the substrates are selected such that colonies of Aeromonas are
the third color and colonies of Salmonella are the fourth color, the fourth color
being visually distinguishable from the first, the second and the third colors.
The substrates may be selected such that the first color is substantially black,
the second color is substantially blue-violet, the third color is substantially red-
pink and the fourth color is substantially teal-green.
In another form of the inventive method, the substrates are selected
such that colonies of Aeromonas as well as colonies of Plesiomonas and
Vibrios are indicated as the third color.
One embodiment of the present invention uses a nonchromogenic
substrate along with one or more chromogenic substrates and thereby
synergistically increases the degrees of design freedom in selecting colors for

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the inventive test medium. This is so because the chromogenic substrates do
not interfere with the substantially black precipitate formed by the
nonchromogenic substrate.
Another advantage of one embodiment of the present invention is that
it enables the quantification, identification and differentiation of four (4)
different bacterial strains simultaneously in a single test medium using a single
test sample, under ambient lighting. Subsequent tests with their concomitant
extra time spent and extra costs are avoided. Of course, the inventive test
medium of the present invention could also be used purely for qualitative
purposes, as a mere presence/absence (P/A) test.
In one embodiment, the substrates are selected such that the colors are
easy to visually distinguish from one another without the need for UV light or
other visual aids, other than, perhaps, magnification means. For example, in
one embodiment, E. coli colonies are clearly indicated by a precipitate having
a substantially black color, general coliform colonies are indicated by a blue-
violet color, Aeromonas colonies are indicated by a red-pink color, and
Salmonella colonies are indicated by a teal-green color. Because these colors
are visually so distinct, confusion among the colors is greatly reduced as
compared to prior art media. In one embodiment, MUGluc (4-
methylumbelliferyl-Beta-D-glucuronic acid) is used in place of a
nonchromogenic substrate. In this test medium, general coliforms would still
be indicated by a blue-violet or grayish color. Aeromonas colonies indicated
by a red-pink color and Salmonella colonies indicated by a teal-green color;
however, E. coli colonies would look the same in visible light as general
coliforms, but also would fluoresce a bright bluish color under a long wave
UV light and this could be distinguished from the other colonies. Although,
the fluorescent product would diffuse more quickly than chromogenic or
nonchromogenic substrates and make quantifying the colonies of E. coli more
difficult, the E. coli colonies can be detected at around 14 hours incubation
time, and in any case will suffice as a presence/absence test for the E. coli.
In yet another embodiment of the invention, it has been found that
three chromogenic substrates may be used if properly combined. For

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example, a β-glucuronide such as X-Gluc (5-bromo-4-chloro-3-indolyl-P-D-
glucuronic acid) or Iodo-Gluc (5-iodo-3-indolyl-β-D-glucuronic acid) may be
used with chromogenic a- and β-D-galactoside substrates. Examples of a- and
β-galactoside substrates that may be suitable are 6-chloro-3-indolyl-P-D-
galactoside and 5-bromo-4-chloro-3-indolyl-α-D-galactoside. In this
embodiment, the β-D-glucuronide and α-D-galactoside substrates form the
same general color in the presence of colonies that produce the respective
enzymes; however, the colors may be distinguished by providing the
substrates in different amounts so that the resulting color produced by one is
darker than that produced by the other. In addition, even if the substrates are
provided in approximately the same amounts, colonies that react to both the β-
D-glucuronide and α-D-galactoside, such as E. coli should be darker that
colonies such as general coliforms, which only react to the α-D-galactoside It
should be appreciated, that it would not be necessary to add ions of salt if a
nonchromogenic substrate is not used.
In an additional aspect of the present invention, MUGluc or another
fluorescent glucuronide substrate may be combined in a test medium with a
chromogenic or nonchromogenic glucuronide substrate. In this case, the
MUGluc substrate can be used to detect E. coli under fluorescent light with
less incubation time than is required to detect colonies with a chromogenic or
nonchromogenic glucuronide. In addition, the MUGluc substrate can serve as
a confirmation of the presence/absence of E. coli, if for any reasons there is
some question as to the colors visible in ambient light produced by the
colonies in the presence of the substrates.
Another advantage of the test medium of the present invention is its
flexibility and ease of use. The incubation temperature is not critical as
growth and differentiation of the organisms mentioned may occur within an
optimum range. Therefore, resuscitation steps are avoided and inhibition of
temperature sensitive strains does not occur. Also, inexpensive equipment
may be used.
In one embodiment of the present invention, the color distinction
obtained in a test medium can be intensified for identifying and differentiating

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E. coli from general coliforms. In one test medium, E. coli colonies present a
substantially black color, whereas general coliforms present a red-pink color,
the distinction therebetween being much more apparent than in prior art test
media. Confusion between the two colors is therefore greatly reduced.
Still another advantage of the present invention is that it enables the
identification and differentiation of Aeromonas spp. from general coliforms.
Prior art test media undesirably require using a cefsulodin inhibitor for
preventing Aeromonas spp. from growing therein. However, the use of
cefsulodin as an inhibitor requires an extra step in the process, viz., sterile
addition of filter sterilized antibiotic, and is difficult to control. Further, the
presence of cefsulodin significantly reduces the effective shelf life of the
medium. Further, the use of an inhibitor, obviously, prevents the detection
and quantitification of Aeromonas spp. Advantageously, with the present
invention, Aeromonas spp. can be detected, quantified and differentiated from
general coliforms in a single medium.
As a related advantage, if it is nonetheless desired to inhibit colonies of
Aeromonas spp. from growing in the test medium, the present invention
provides a superior means for doing so. Specifically, preferred forms of the
present invention employ nalidixic acid as an inhibitor, which has been shown
to have a far less deleterious effect to the shelf-life of the medium
incorporating it. Further, nalidixic acid can be added as part of the initial
medium formulation prior to sterilization, thereby avoiding a costly and
difficult process step which is required with cefsulodin. Finally, nalidixic acid
is much less expensive than cefsulodin.
Another advantage of the present invention is that it can provide a test
medium for qualitative or quantitative testing. That is, the test media in
accordance with the present invention can be used as mere presence/absence
test devices, or can be used to quantify various biological entities showing as
different colored colonies on the inventive test media.
Detailed Description of the Invention
The method and medium of the present invention allow the
simultaneous detection, quantification, identification and differentiation of a

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variety of selected biological entities in a sample of mixed populations of
biological entities. The inventive method and medium are particularly useful
for the detection, quantification, identification and differentiation of E. coli
and general coliforms, and further quantitative identification and
differentiation of other selected biological entities, including Aeromonas,
Salmonella, and Vibrio bacterial species.
The method and test media incorporating the present invention utilize
the fact that the enzymatic activity of biological entities and specifically of
bacteria varies with the genus, and/or family of bacteria of interest. The
method and test media incorporating the present invention further utilize the
fact that various enzyme identifying substrate complexes can be used to
identify specific enzymes with the production of distinctive colors.
Significantly, in one embodiment of the present invention, the method and test
media incorporating the present invention exploit the fact that chromogenic
substrates present in a test medium do not interfere with the substantially black
color produced by nonchromogenic substrates.
While nonchromogenic substrates are known in the art, per se, their
distinct properties vis-a-vis chromogenic substrates have been unrecognized.
However, the behavior of a nonchromogenic substrate in a medium including
the combination of chromogenic substrates is unique. To illustrate,
aggregations of a biological entity which are responsive to two chromogenic
substrates will typically show in a test medium as a combination of the two
colors produced upon cleavage of the two respective substrates. When three
chromogenic substrates are involved, as in another embodiment of the
invention, the combined color effect is not obvious to predict and account for.
Further, inherent variations in the amount of enzymes produced by particular
strains of biological entities can result in different shades or hues of colors
upon cleavage of the chromogenic substrates. Consequently, the colors can be
difficult to distinguish for the lay person examining the test medium.
Chromogenic substrates must therefore be chosen and used in a concentration
in view of the other chromogenic substrates planned for inclusion in a given
test medium.

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Such is not the case with the nonchromogenic components. While
aggregations of biological entities which are responsive to chromogenic
substrates in addition to nonchromogenic substrates may show in the test
medium as having a colored or fluorescent "halo," such aggregations
nonetheless appear substantially black and are therefore easy to identify.
Multiple "degrees of freedom" are achieved with the nonchromogenic
components.
Using a nonchromogenic substrate is one way of enabling a single test
medium to differentiate four (4) different bacterial strains with four (4)
visually distinguishable colors. The black color is difficult to mistake. Further,
the substantially black pigmentation does not diffuse so that the location of the
colonies is precisely known and the colonies can be accurately counted. The
nonchromogenic substrates produce an insoluble chelated compound which is
different than the dimer which is produced by the chromogenic substrates.
The inventive test medium and method allows not only a detection,
quantification or qualitative identification and differentiation of genera]
coliforms and E. coli, but also of Salmonella and Aeromonas, as well as
Plesiomonas and Vibrio. Plesiomonas and Vibrios species are determined
but not differentiated from Aeromonas species as they are very closely related.
Definitions
Biological entities, such as general coliforms, E. coli., etc., are herein
referred to as being "responsive" to certain chromogenic and nonchromogenic
substrates. More specifically, a biological entity will predictably produce
specific enzymes when the entity is present in a test medium such as the one
described hereinbelow. These enzymes will selectively cleave chromogenic
and nonchromogenic substrates. Upon cleavage, these substrates produce a
color in the test medium. The mechanism for producing the color is different
for chromogenic and nonchromogenic substrates, as described hereinbelow.
Microorganisms having p-galactosidase activity include those
commonly known by the designation "coliform." There are various definitions
of "coliform," but the generally accepted ones include bacteria which are
members of the Enter obacteriaceae family, and have the ability to ferment the

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sugar lactose with the evolution of gas and acid. Most coliforms are positive
for both α-and β-galactosidase. That is, they produce both α-and β-
galactosidases.
Microorganisms having P-glucuronidase activity in addition to
galactosidase activity primarily include most strains of Escherichia coli. That
is, E. coli is positive for both α- and β-galactosidase as well as β-
glucuronidase.
The term "general coliforms" as used in this application refers to
coliforms other than the various strains of E. coli. These "general coliforms"
are gram-negative, non-spore forming microorganisms generally having α-
and β-galactosidase activity (i.e., lactose fermenters), but not having β-
glucuronidase activity, and having the ability to ferment the sugar sorbitol.
For purposes of this specification, a "chromogenic substrate" is a
substrate which needs no additional chemicals present in the test medium upon
hydrolysis for color production. That is, a chromogenic substrate is cleaved by
the specific enzyme corresponding to that substrate to form a dimer with the
color being concentrated in the area of cleavage of the substrate. Many
chromogenic substrates are known in the art. For purposes of this specification
"chromogenic" includes fiuorogenic substrates. The products of fluorogenic
substrates require ultraviolet (UV) light to be detected and are more water
soluble than other chromogenic substrates.
Certain substrates, referred to herein as "nonchromogenic," produce a
dark, substantially black precipitate in the presence of ions of a salt and
enzyme activity. For example, 8-hydroxyquinoline-β-D-glucuronide, when
included in a medium along with a salt that produces ions, such as ferric
ammonium citrate, will produce a substantially black precipitate in the
presence of P-glucuronidase produced by E. coli or other biological entities.
More specifically, upon cleavage of the nonchromogenic substrate by the
particular enzyme, a substantially black water-insoluble complex forms in the
medium. The substantially black precipitate consists of the ferric ions and the
aglycone released when the substrate is hydrolized by the glucuronidase from
E. coli. This precipitate is a chelated compound which does not diffuse. Nor is

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the substantially black color susceptible to interference from chromogenic
compounds present in the test medium.
For purposes of this specification, a "nonchromogenic substrate"
means that a chemical in addition to those used with chromogenic components
must be present in the test medium when the substrate is cleaved by its
corresponding enzyme. The substantially black precipitate formed thereby is a
combination of the substrate - salt complex and is not a dimer as is formed by
the "chromogenic compounds."
For purposes of this specification, the expression "under ambient light"
refers to the visible spectrum, i.e., colors which can be seen and distinguished
with the naked eye. A colony present in a test medium which requires
ultraviolet light to be seen, for example, would not fall under the definition
"under ambient light". However, it is to be understood that the term "under
ambient light" includes using a magnification device, if necessary.
Magnification can be especially helpful when counting numerous colonies.
The term "visually distinguishable" refers to two or more colors which can be
differentiated under ambient light.
For purposes of this specification, the term "substantially black"
includes dark brown to black, and also includes black with various colored
halos, such as red-violet, green, fluorescent, etc.
For further purposes of this specification, color names recited herein
are given as guidance, but it is to be understood that the color names are to be
read broadly. That is, there can be overlap among the recited colors. This is
because, as discussed, biological entities produce varying amounts of
enzymes, which in turn affects the shade or hue of the resulting color.
The term "β-galactosidase substrate" as used herein refers to a β-
galactoside comprising galactose joined by β-lmkage to a substituent that
forms a detectable compound when liberated by the action of β-galactosidase
on the substrate. Similarly, the term "α-galactosidase substrate" as used herein
refers to α-galactoside comprising galactose joined by α-linkage to a
substituent that forms a detectable compound when liberated by the action of
a-galactosidase on the substrate. The term "β-glucuronidase substrate" as used

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herein refers to a β-glucuronide comprising glucuronic acid joined by β-
linkage to a substituent that forms a detectable precipitate when liberated by
the action of β-glucuronidase on the substrate.
The α- and β-galactosidase substrates and compounds and any other
substrates described herein as well as the β-glucuronidase substrates and
compounds and any other substrates described herein may comprise
carboxylate salts formed by reacting a suitable base with the appropriate
galactoside or glucuronic carboxyl group. Suitable bases include alkali metal
or alkaline earth metal hydroxides or carbonates, for example, sodium
hydroxide, potassium hydroxide, calcium hydroxide, magnesium hydroxide,
and corresponding carbonates; and nitrogen bases such as ammonia, and
alkylamines such as trimethylamine, triethylamine and cyclohexylamine.
Designing a Test Medium for Specific Biological Entities
Certain members of the family Enterobacteriaceae can be
distinguished by the presence of α-galactosidase activity in the absence of β-
galactosidase activity, or vice-versa. For example, most Salmonella and
Shigella spp. are positive for a-galactosidase, but negative for β-galactosidase.
Similarly, Aeromonas spp. can be distinguished from other members of the
family Enter obacteriaceae by the presence of β-galactosidase activity in the
absence of α-galactosidase activity. The method and medium incorporating
the present invention are designed to take advantage of these distinguishing
characteristics. For example, the specificity of enzyme activity for Salmonella
and Aeromonas spp., as opposed to general coliforms, can be exploited, as
illustrated below.
The method described herein is particularly suitable for the detection,
quantification or qualitative identification and differentiation of the different
classes of microorganisms described previously, viz., general coliforms, E.
coli, Aeromonas and Salmonella. Although the inventive method is
particularly suitable for these particular microorganisms, it is not limited
thereto. Instead, the techniques described herein have application to the
identification and differentiation of a wide variety of biological entities.

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That is, specific biological entities are "responsive" to various
substrates. More particularly, these biological entities predictably produce or
contain known enzymes. Substrates, either chromogenic or nonchromogenic,
can be selected which, in the presence of a particular enzyme(s), will form a
product of a predictable and distinguishable color. Multiple substrates can be
selected to simultaneously identify a plurality of distinct biological entities in
a single test medium, aggregations of each distinct entity being identifiable by
a separate, distinguishable color. Further, while certain embodiments
disclosed herein distinguish all of the various aggregations present in a test
medium under ambient light, as that term is defined herein, such is not
necessary. For example, several substrates disclosed herein require the use of
ultraviolet light for the aggregations present in the medium to be seen.
Table I lists various enzymes whose presence may be detected using
certain of the substrates listed in Table II.
Table I
Enzymes and Abbreviations

Aara=α-D-arabinopyranosidase Bglu=β-D-glucopyranosidase
Agal=α-D-galactopyranosidase Bgluc=β-D-glucuronidase
Aglu=α-D-glucopyranosidase Bman=β-D-mannopyranosidase
Bcel=β-D-cellopyranosidase Bxyl=β-D-xylopyranosidase
Bfuc=p-D-fucopyranosidase Nagal=N-acetyl-β-D-galactopyranosidase
Bgal=p-D-galactopyranosidase Nag]u=N-acetyl-β-D-glucopyranosidase
Afuc=a-D-fucopyranosidase Bara=β-D-arabinopyranosidase
Bxyl=p-D-xylopyranosidase Acel=α-D-cellopyranosidase
Aman=a-D-mannopyranosidase Agluc=α-D-glucuronidase
Axyl=a-D-xylopyranosidase Nagluc=N-acetyl-β-D-glucuronidase
esterase

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Table II
Various Substrates and Color Upon Cleavage

6-chloro-3-indolyl substrates Pink
5-bromo-4-chloro-3-indolyl substrates Teal
3-indolyl substrates Teal
N-methylindolyl substrates Green
nitrophenyl substrates Yellow
nitroaniline substrates Yellow
8-hydroxyquinoline substrates (and ion of salt) Substantially black
cyclohexenoesculetin substrates (and ion of salt) Substantially black
esculetin substrates (and ion of salt) Substantially black
quinoline substrates (and ion of salt) Substantially black
5-Iodo-3-Indolyl substrates Purple
5-Bromo-6-Chloro-3-Indolyl substrates Magenta
6-Fluoro-3-Indolyl substrates Pink
coumarin substrates Fluorescent
fluorescein substrates Fluorescent
rhodamine substrates Fluorescent
resorufin substrates Fluorescent
Specific substrate compounds applicable for use with the test medium
of the present invention are available as follows:
5-bromo-4-chloro-3-indolyl-β-D-galactopyranoside (X-gal) is a
commercially available β-galactosidase substrate that produces an insoluble
precipitate having an approximately teal color when reacted upon by (3-
galactosidase and is available from Biosynth International, Naperville, IL.
6-chloro-3-indolyl-β-D-glucuronide is a compound which produces an
insoluble precipitate having a magenta color, the preparation of which is
described in the aforementioned incorporated by reference U.S. Patent No.
5,210,022 and is available from Research Organics, Cleveland, OH.
The compound 5-bromo-4-chloro-3-indolyl-β-D-glucuronide (X-gluc)
is a commercially available β-glucuronide that produces an insoluble

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precipitate having an approximately teal color when reacted upon by β-
glucuronidase. Similarly, indoxyl-β-glucuronide is a similar compound, the
preparation of which is described in the aforementioned article by Ley et al.,
in Can J. Microbiol, the disclosure of which is incorporated by reference.
Another suitable β-galactoside is the compound 6-chloro-3-indolyl-β-
D-galactoside which produces an insoluble precipitate having a pink/magenta
color, the preparation of which is described in the aforementioned U.S. Patent
No. 5,210,022.
Other suitable compounds applicable as substrates in the practice of the
present invention are specified in U.S. Patent No. 5,210,022, all of which are
incorporated herein by reference.
The substrate 8-hydroxyquinoline-β-D-glucuronide is a commercially
available β-glucuronide that, in the presence of metallic ions such as iron,
produces an insoluble precipitate having a substantially black color when
reacted upon by β-glucuronidase and in the presence of other a- or β-
galactoside substrates. 8-hydroxyquinoline-β-D-glucuronide is available from
Biosynth International, Naperville, IL.
Further, a salt providing ions suitable for use with the present invention
is ferric ammonium citrate, available from Sigma Chemical, St. Louis, MO.
The cyclohexenoesculetin substrates are described in James et al., Appl. &
Envir. Micro. 62:3868-3870 (1996) and in the presence of ferric ions, produce
an insoluble substantially black precipitate.
N-methyl-indolyl substrates such as N-methylhydroxy- P-D-
galactopyranoside are commercially available from Biosynth International,
Naperville, IL.
Nitrophenyl substrates, such as 2-nitrophenyl-β-D-galactopyranoside,
are commercially available from Biosynth International, Naperville, IL.
Similarly,. nitroaniline compounds are available for synthesis through Sigma
Chemical, St. Louis, MO.
Other substrates producing a substantially black color include esculetin
substrates such as cyclohexenoesculetin- β-D-galactoside, which is described
in James et al., Appl. & Envir. Microbiol. 62:3868-3870 (1996). Quinoline

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substrates, such as 8-hydroxyquinoline-β-D-galactopyranoside and 8-
hydroxyquinoline-β-D-glucuronide are available through Biosynth
International, Naperville, IL.
Iodo-indolyl substrates, such as 5-iodo-3-indolyl-β-D-
galactopyranoside are available through Biosynth International, Naperville, IL.
Several fluorescent substrates are suitable for use with the present
invention. Coumarin substrates such as 4-methylumbelliferyl substrates and
5-trifluoromethylumbelliferyl substrates are commercially available from
Biosynth International, Naperville, IL. Also suitable are fluorescein
substrates, rhodamine substrates, and resorufin substrates. No commercial
source is known for these three substrates but components are available from
Sigma Chemical, St. Louis, MO.
While specific examples of substrates suitable for use with the present
invention have been enumerated hereinabove, such is not to be construed as
limiting the invention in any manner. Instead, one of ordinary skill in the art
can use Table IV and V hereinbelow to identify a virtually limitless number of
substrates.
Preparation of Test Medium
The test medium is formed by combining the desired substrates with a
nutrient base medium. The nutrient base medium can be any culture medium
known in the art for providing the maintenance and reproduction of living
cells. Generally, such media include nutrients, buffers, water, and sometimes
a gelling agent. Possible gelling agents include agars, pectins, carrageenans,
alginates, locust bean, and xanthins, among others.
The following is an example of the preparation of a test medium
suitable for use in this invention. This example coincides with Example I,
below.
The substrates 8-hydroxyquinoline-β-D-glucuronide, 5-Bromo-4-
chloro-3-indolyl-α-D-galactopyranoside, and 6-Chloro-3-indolyl-β-D-
galactopyranoside are added in quantities of 250 mg/L medium; 70 mg/L
medium; and 175 mg/L medium, respectively. The substrates are added

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directly to the hot (75°- 85°C) medium (formula below) in a blender prior to
sterilization.
Standard agar medium may be made by adding 15 gm of
bacteriological quality agar gum to the following nutrient formula

and then sterilizing at 121 °C for 15 minutes. The medium should be adjusted
to result in a pH of 7.0. The sterilized agar medium is allowed to drop to a
temperature of 45°C in a water bath and then the sterile solution containing the
substrates prepared as described above is added. The medium is mixed
thoroughly and poured into sterile petri plates at a volume of 20 ml/plate.
A pectin-based test medium may be prepared using the same steps
described above except that 25 gm of low methoxyl pectin is used as the
solidifying agent and the medium is poured at room temperature into petri
plates containing a thin gel layer containing calcium ions which combine with
the pectin to form a solid gel. A suitable pectin culture medium is described in
U.S. Patent No. 4,241,186 and U.S. Patent No. 4,282,317, the disclosures of
which are incorporated herein by reference. A pectin-based medium is
preferred over a standard agar medium because it has the advantages of
convenience and temperature independence for the user. The use of pectin
media is well described and accepted as a result of AOAC collaborative
studies and other published and in-house investigations.
A suitable pectin medium is commercially available from Micrology
Laboratories, LLC under the trademark Easygel®. Aqueous based medium
without gelling agent is available from Micrology Labs, Goshen IN., for use
with membrane filters.

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Inoculation of the Test Medium with the Sample
The test medium may be inoculated with a sample to be tested for the
presence of microorganisms by any method known in the art for inoculating a
medium with a sample containing microorganisms. For example, the sample
to be tested may be added to the petri plates prior to adding the nutrient base
medium (pour plate technique) or spread on the surface of the plates after they
have cooled and solidified (swab or streak plate technique). Liquid samples
may also be filtered through a micropore (.45 micrometer size) membrane
filter which is then placed on the surface of a solid medium or on a pad
saturated with the medium.
Incubation of the Test Medium
The inoculated test medium is incubated for a sufficient time and at
such a temperature for individual microorganisms present in the sample to
grow into detectable colonies. Suitable incubation conditions for growing
microorganisms in a medium are known in the art. Commonly, the test
medium is incubated for about 24-48 hours at a temperature of about 30°-
4CPC. Less incubation time may be required, such as about 14 hours, to obtain
results for a fluorescent substrate.
Unless inhibitors of the general microbial population are used, the
general microbial population as well as general coliforms, E. coli, Aeromonas
spp., and Salmonella spp. and Shigella spp. will grow in the incubated test
medium. Because the precipitates formed are insoluble (except for the
fluorogenic substrates) in the test medium, they remain in the immediate
vicinity of microorganisms producing the various enzymes. As the
microorganisms reproduce to form colonies, the colonies show as colony
forming units having the color produced by the particular substrate.
For example, E. coli produces |3-galactosidase and β-galactosidase, but,
unlike general coliforms and Aeromonas spp., also produces β-glucuronidase.
Therefore, insoluble precipitates of each of the β-galactosidase substrate, the
β-galactosidase substrate and the nonchromogenic β-glucuronide substrate are
formed by the action of the respective enzymes such that colonies of E. coli

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show as a substantially black color, sometimes having a violet-blue halo
therearound.
General coliforms produce β-galactosidase and α-galactosidase and
consequently cleave both the a-galactosidase and β-galactosidase substrates.
In the present example, the 5-Bromo-4-chloro-3-indolyl-α-D-galactoside
substrate produces a blue-green or teal color, whereas the 6-Chloro-3-indolyl-
β-D-galactoside produces a pink, or red-pink color. Thus, general coliform
colonies will show as a blue-violet color, which is a combination of the colors
produced by each of the α- and β-galactosides, respectively.
Significantly, however, it has been found that Aeromonas spp., which
are closely related to coliforms, and give an almost identical biochemical test
pattern, are β-galactosidase positive and a-galactosidase negative. That is,
Aeromonas spp. will not hydrolize the α-galactoside substrate. Therefore,
Aeromonas colonies present in the test medium will show as colonies having
the pink-red color produced by the β-galactoside substrate.
Further, it has been found that members of the genus Salmonella are
positive for a-galactosidase, but negative for p-galactosidase. That is,
Salmonella will not hydrolize the β-galactosidase substrate. Therefore,
colonies of Salmonella present in the test medium will appear as a teal, or
blue-green color produced by the a-galactoside substrate.
Examination of the Test Medium and Enumeration of Microorganisms
The substrates selected for the above example produce three distinct
colors, and general coliforms are indicated by a fourth color which is a
combination of two of the three colors. That is, E. coli colonies show as
substantially black, general coliform colonies show as blue-violet, Aeromonas
colonies show as red-pink, and Salmonella colonies show as teal-green. While
the individual shades of these colors may vary somewhat in the test medium
due to factors such as varying enzyme production of the biological entities, it
has been found that these four colors are distinct enough so that confusion
amongst them is unlikely.
The colonies of each type of microorganism may be enumerated by
counting the colonies or by other methods known in the art for enumerating

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microorganisms on a test plate. The number of colonies of each type generally
indicates the number of microorganisms of each type originally present in the
sample before incubation.
Optional Ingredients
Inhibitors
The method of the present invention does not require inhibitors.
However, the medium may be made more selective for general coliforms and
E. coli if desired by the addition of various compounds that are inhibitory to
the general microbial population, but have little or no effect on coliforms.
Following are some compounds which may be used: a) bile salts, about 0.3
g/liter, b) sodium lauryl sulfate, about 0.2 g/liter, c) sodium desoxycholate,
about 0.2 g/liter, d) Tergitol 7, about 0.1 ml/liter. The use of one or more of
these compounds reduces the background (non-coliform) microorganism
presence and makes a less cluttered plate and eliminates the possibility of
inhibition or interference by the non-coliform organisms in the sample. The
use of certain antibiotics may accomplish the same result.
Cefsulodin is commonly used in currently available test media to
inhibit Aeromonas spp. However, the use of cefsulodin as an inhibitor
requires an extra step in the process, viz., sterile addition of filter sterilized
antibiotic. This step is difficult to control. Further, the presence of cefsulodin
significantly reduces the effective shelf life of the medium. It has been found
that Nalidixic acid can be used instead of Cefsulodin to inhibit Aeromonas
spp. with about the same efficacy. Nalidixic acid is preferable because it can
survive the approximately 120 °C temperature reached in autoclaving the test
media. Therefore, unlike cefsulodin, nalidixic acid can be added to the test
media as part of the initial media formulation prior to sterilization {see,
preparation of test medium, above). It also follows that the resistance of the
nalidixic acid to unfavorable environmental conditions will result in a longer
shelf life for a medium containing it as compared to cefsulodin.
Inducers
It is possible that the enzyme production of the general coliforms may
be enhanced by the addition to the medium formulations of very small

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amounts of substances known as enzyme inducers. One specific inducer for β-
galactosidase is available and is known chemically as isopropyl-β-
thiogalactopyranoside. Adding approximately 100 mg/liter of medium has a
positive and noticeable effect on the speed of enzyme production for some
species of coliforms. Other enzyme inducers are available and may be added
to media formulations if enhanced enzyme production is deemed helpful.
Examples
Listed below are broad examples of test media enzyme substrate
combinations to be used in combination with the nutrient formula discussed
above or other suitable nutrient formulas which may be prepared in practicing
the present invention.
Table III illustrates the flexibility of the preferred embodiments
incorporating the present invention. Table III is a matrix of some of the
possible four-color combinations available for the preferred biological entities
E. coli, general coliforms, and at least one of the genera Aeromonas or
Salmonella to be detected by using the teachings of this disclosure. Other
color combinations are possible. In many cases, a plurality of different
substrates will achieve a desired result, the only difference being the colors
detected for a specific enzyme. The preferred color choice for the detection of
E. coli is denoted with an asterisk in Table III, depending on the colors chosen
to detect other microorganisms. As discussed above, other chromogenic
substrates do not interfere with the substantially black color, and the
substantially black color is easy to distinguish from the other colors.
As discussed above, the use of Table III requires taking into account
the combined color effect discussed above which is produced by the inclusion
of multiple chromogenic substrates in a single medium. For example, with
reference to the first entry in Table III, it can be understood that general
coliforms will appear as a combination of (1) red-pink (magenta) and (2) teal,
the resulting color being blue-violet. This is the case because general
coliforms are responsive to two chromogenic substrates. Similarly, general
coliforms will show in a test medium in accordance with the second entry of
Table III as a combination of (1) red-pink (magenta) and (2) yellow.

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Table III
Color possibilities for detection of preferred microorganisms

* Shigella may also show as this color.



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Table IV is a partial list of enzyme patterns for biological entities
preferred to be to be detected in accordance with the teachings of this
disclosure. It is to be understood that one of ordinary skill in the art would
readily recognized that other enzymes which are known and have been
produced, and enzymes which are known only on a theoretically level, would
also perform satisfactorily.
Table IV

Table V is a matrix which teaches a wide variety of substrates and their
associated colors for use in test media in accordance with the teachings of this
disclosure. The left hand side of Table V indicates the color that will result
when the listed chromogenic component is cleaved from its corresponding
substrate by the specific enzyme for that substrate. In the case of the
nonchromogenic components, the color is substantially black and the reaction

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mechanism requires the presence of ions of a salt upon cleavage of the
substrate, as explained above.
Test enzymes which are produced by certain biological entities {see
Table IV) are found at the right hand side of table V. "Substrate components"
are shown to the left of the specific test enzymes. Each of the substrate
components listed on the right hand side of table V can be combined with any
of the chromogenic or nonchromogenic components listed on the left hand
side of table V to identify a specific substrate for use in a test medium. It can
therefore be understood that Table V teaches a large quantity of substrates
possible for use in accordance with the present invention. Many of the
substrates identified by the above-described use of table V are commercially
available, whereas the method for producing other identified substrates is
described in the literature. Still other substrates identified by using table V are
only theoretically possible.
Nonchromogenic components are included at the bottom left hand side
of Table V, and are different from the chromogenic components because they
do not form specific colors upon cleavage. Instead, the quinoline or esculetin
components combine with ions of a salt {e.g., ferric salt) which must be
present in the medium when the substrate is cleaved by the specific enzyme.
The substantially black precipitate formed by the nonchromogenic
components is a combination of the quinoline or esculetin - iron complex
rather than a dimer which is formed by the chromogenic components.
Unlike nonchromogenic components, the chromogenic components
should be selected in view of all other chromogenic components selected for
the medium and in view of the enzyme patterns of the entities to be detected.
The selection and concentration of chromogenic components should maximize
the distinction among the respective colors produced.
While many various chromogenic component and substrate
component/enzyme possibilities are taught by Table V, other possibilities
within the scope of the appended claims would be possible by one of ordinary
skill in the art. For example, as shown in Table V, one of ordinary skill in the
art could combine an N-acetyl group with many of the sugars of the substrate

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components listed in Table V. For example, an N-acetyl group could be
combined with P-D-mannopyranoside to form N-acetyl- β-D-mannosaminide,
the corresponding enzyme being N-acetyl-β-D-mannosaminidase. Any of the
chromogenic components or nonchromogenic components listed on the left
hand side of Table V could then be combined with the substrate component to
identify a substrate. If the substrate is commercially available or the method
of making it is known, the substrate could be used in a test medium. Upon
cleavage of the substrate by the corresponding enzyme in the test medium, the
color listed will appear.
Generally, the teachings of this disclosure can be used as follows to
make a test medium for detecting various microorganisms or cell types. First,
the microorganisms desired to be detected and differentiated are selected. The
preferred organisms to be detected are E. coli, general coliforms, and at least
one of the genera Aeromonas or Salmonella. Enzymes produced by the
selected organisms can be identified with reference to Table IV. Equipped
with knowledge of specific enzymes produced by each microorganism, one
can then identify corresponding substrates components from the right hand
side of Table V. Depending upon the color desired, one can select a
chromogenic or nonchromogenic component from Table V to be combined
with the substrate component to identify a substrate for inclusion in the test
medium. If the substrate thereby identified is commercially available or the
method of its synthesis is known, the substrate can be used in the test medium.

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Table V
Color Component and Substrate Component Matrix


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Table VI is a concise summary of the specific examples.
Table VI - Example Summaries


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* Shigella may also be indicated as this color
Example I
The microorganisms chosen to be identified, quantified and
differentiated are E. coli, general coliforms, Aeromonas and/or Salmonella.
With reference to Table IV, E. coli produces the enzyme Bgluc, and
Bgluc is not produced by any of the other microorganisms desired to be
detected. With reference to the right hand side of Table V, it can be seen that
the test enzyme Bgluc has a corresponding substrate component of β-D-
glucuronide. Thus, a chromogenic or nonchromogenic component which
produces a distinct color upon cleavage of Bgluc should be chosen from the
left hand side of Table V. 8-hydroxyquinoline is chosen for its preferred
substantially black color. The first identified substrate is therefore 8-
hydroxyquinoline-β-D-glucuronide, the availability of which is described
above. A metallic salt such as ferric ammonium citrate is also required and is
added to the test medium so that, upon cleavage of the substrate by Bgluc, a
substantially black water-insoluble complex forms in the medium. The
substantially black precipitate consists of the ferric ions and the aglycone
released when the substrate is hydrolyzed by the glucuronidase from E. coli.
With further reference to Table IV, Bgal, Bfuc and Bglu are common
to Aeromonas and general coliforms. However, as indicated in Table IV,
Bgal, Bfuc and Bglu are not produced generally by Salmonella. Therefore, a
substrate component corresponding to one of Bgal, Bfuc and Bglu can be
selected form the right hand side of Table V. Bgal and the associated
substrate component β-D-galactopyranoside are chosen. The 6-chloro-3-
indolyl- chromogenic component produces a red-pink color upon cleavage
from its substrate in the presence of Bgal and is selected as the chromogenic
component. The second substrate is therefore 6-chloro-3-indolyl-β-D-
galactopyranoside.

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Again referring to Table IV, Bman, Aara and Agal are common to
Salmonella and general coliforms. However, as indicated in Table IV, Bman,
Aara and Agal are not produced by Aeromonas. Thus, one of Bman, Aara and
Agal can be chosen and its associated substrate component identified with
reference to Table V. The test enzyme Agal and the respective substrate
component α-D-galactopyranoside are chosen. Next, a chromogenic
component must be selected from Table V. As shown on the left hand side of
Table V, the cliromogenic component 5-bromo-4-chloro~3-indolyl produces a
teal color upon cleavage from its associated substrate and is therefore selected.
The third substrate is therefore 5-bromo-4-chloro-3-indolyl-α-D-
galactopyranoside.
General coliforms have a wide enzyme pattern which is responsive to
both the 6-chloro-3-indolyl-β-D-galactopyranoside substrate and the 5-bromo-
4-chloro-3-indolyl-α-D-galactopyranoside substrate. Therefore, general
coliforms will show as a fourth distinct color which is a combination of the
colors produced by the two aforementioned substrates, respectively. In this
case the fourth color will be violet-blue, which is a combination of red-pink
and teal.
Finally, as seen in Table IV, E. coli also exhibits a wide enzyme
pattern and responsive to all three of the substrates chosen in this example,
viz., 8-hydroxyquinoline-P-D-glucuronide, 6-chloro-3-indolyl-[i-D-
galactopyranoside, and 5-bromo-4-chloro-3-indolyl-oc-D-galactopyranoside.
Nonetheless, E. coli colonies present in the test medium will show as a
substantially black color because, as discussed above, the chromogenic
substrates do not interfere with the substantially black color. Advantageously,
this substantially black color provides a superior means for distinguishing the
E. coli, as well as allows four separate microorganisms to be detected,
quantified, differentiated and identified in a single test medium. See Table VI.
Example II
The selected microorganisms to be detected, quantified, differentiated
and identified are E. coli as a first color; general coliforms and Salmonella as a
second color; and Aeromonas as a third color.

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With reference to Table IV, E. coli produces the enzyme Bglue, and
Bgluc is not produced by any of the other microorganisms desired to be
detected. With reference to the right hand side of Table V, it can be seen that
the test enzyme Bgluc has a corresponding substrate component of P-D-
glucuronide. Thus, a chromogenic or nonchromogenic component which
produces a distinct color upon cleavage of Bgluc should be chosen from the
left hand side of Table V. 8-hydroxyquinoline is chosen for its preferred
substantially black color. The first identified substrate is therefore 8-
hydroxyquinoline-p-D-glucuronide, the availability of which is described
above. A metallic salt such as ferric ammonium citrate is also required and is
added to the test medium so that, upon cleavage of the substrate by Bgluc, a
substantially black water-insoluble complex forms in the medium. The
substantially black precipitate consists of the ferric ions and the aglycone
released when the substrate is hydrolized by the glucuronidase from E. coli.
With further reference to Table IV, Bgal, Bfuc and Bglu are common
to Aeromonas and general coliforms. However, as indicated in Table IV,
Bgal, Bfuc and Bglu are not produced by Salmonella. Using Table V in the
fashion described above, 6-Chloro-3-indolyl-β-D-galactopyranoside is
selected as the second substrate, which will produce a red-pink color upon
cleavage as indicated by the chromogenic component list of Table V.
As seen in Table IV, the enzyme Bman is common to Salmonella but
not Aeromonas. From table V, the substrate component associated with Bman
is β-D-mannopyranoside. In this example, it is desired to also produce the
second distinct color (red-pink) with Salmonella so that, ultimately,
Salmonella colonies present in the test medium will show as the same color as
general coliforms present in the test medium. Thus, the chromogenic
component is 6-Chloro-3-indolyl- and the third substrate is therefore 6-
Chloro-3-indolyl-β-D-mannopyranoside.
In this example, again using Table V, a fourth substrate is identified
that will be cleaved by one of the enzymes Bman, Aara, Agal common to
Salmonella to produce a third distinct color. Using table V in the fashion
described above, the fourth substrate selected is 5-Bromo-4-chloro-3-indolyl-

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a-D-galactopyranoside, which produces a teal-green color in the presence of
Agal common to Salmonella.
The resulting colors of colonies present in the test medium can be
predicted as follows. E. coli exhibits a wide enzyme pattern that is positive for
all four of the substrates chosen in this example, including the 8-hydroxy-
glucuronide substrate which produces a substantially black color upon
cleavage in the presence of the ions of the ferric salt. E. coli colonies show as
substantially black. Aeromonas has an enzyme pattern which reacts with only
the 6-Chloro-3-indolyl-β-D-galactopyranoside substrate chosen in this
example and therefore colonies of Aeromonas show as red-pink. Salmonella
has an enzyme pattern which cleaves both the third and fourth substrates
selected in this example and therefore colonies of Salmonella show as purple-
blue (a combination of teal and red-pink). Finally, general coliforms are
positive for each of the second, third and fourth substrates selected and
colonies thereof show as purple-blue, indistinguishable from the Salmonella
colonies. As discussed above, different strains of all species of the various
genera will not all produce the same amounts of the various enzymes, so there
may be slight variations in shades of purple-blue, for example.
Example IIIA
The selected microorganisms to be quantified and differentiated in this
example are E. coli as a first color, general coliforms and Aeromonas as a
second color, and Salmonella as a third color.
With reference to Table IV, E. coli produces the enzyme Bgluc, and
Bgluc is not produced by any of the other microorganisms desired to be
detected. With reference to the right hand side of Table V, it can be seen that
the test enzyme Bgluc has a corresponding substrate component of β-D-
glucuronide. Thus, a chromogenic or nonchromogenic component which
produces a distinct color upon cleavage of Bgluc should be chosen from the
left hand side of Table V. 8-hydroxyquinoline is chosen for its preferred
substantially black color. The first identified substrate is therefore 8-
hydroxyquinoline-β-D-glucuronide, the availability of which is described
above. A metallic salt such as ferric ammonium citrate is also required and is

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added to the test medium so that, upon cleavage of the substrate by Bgluc, a
substantially black water-insoluble complex forms in the medium. The
substantially black precipitate consists of the ferric ions and the aglycone
released when the substrate is hydrolized by the glucuronidase from E. coli.
Using tables IV and V in a fashion similar to that described above with
reference to Examples I and II, 6-Chloro-3-indolyl-β-D-galactopyranoside is
selected as a second substrate to combine with one of the enzymes Bgal, Bfuc
and Bglu common to coliforms and Aeromonas, but negative for Salmonella to
produce a second distinct color, in this case substantially red-pink.
Similarly, 6-Chloro-3-indolyl-α-D-galactopyranoside is selected as a
third substrate to combine with Agal, which is common to coliforms and
Salmonella, but negative for Aeromonas. Upon reaction with the enzyme, this
substrate will also produce the same distinct second color, namely red-pink.
5-Bromo-4-chloro-3-indolyl-β-D-galactopyranoside is selected as a
fourth substrate to combine with the enzyme Bgal, which is common to
coliforms and Aeromonas, but negative for Salmonella. This fourth substrate
produces a teal-green color upon reaction with Bgal.
The resulting colors of colonies present in the test medium can be
predicted as follows. E. coli exhibits a wide enzyme pattern and is positive for
all four of the substrates chosen in this example. Therefore, E. coli colonies
will show as substantially black. General coliform colonies have an enzyme
pattern which is positive for the second, third and fourth substrates, so that
general coliforms colonies show as purple-blue. Aeromonas colonies have an
enzyme pattern which is positive for the second and fourth substrates chosen
so that Aeromonas colonies also show as purple-blue. Finally, the enzymes
common to Salmonella are only positive for the third of the four substrates, so
that Salmonella colonies show as red-pink.
Example IIIB
As a variation, the test medium of Example IIIA can be prepared such
that colonies of Salmonella will show as teal instead of pink-red, all of the
other colony colors being the same as Example IIIA. With reference to Table
VI, such can be accomplished by replacing the 6-chloro-3-indolyl-α-D-

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galactopyranoside of Example IIIA with 5-bromo-4-chloro-3-indolyl-α-D-
galactopyranoside.
Example HIC
A second, independent method for producing the same three colors as
Example IIIA for the same four components can be achieved by adding
nalidixic acid or other antibiotics or inhibitors of Aeromonas to the
components listed in Example 1. In so doing, the cefsulodin or nalidixic acid
or other substance acts as an inhibitor for Aeromonas so Aeromonas colonies
do not grow. If Aeromonas is eliminated, then the purple-blue colonies are all
true coliforms. If not eliminated, any A eromonas will be counted as part of
the coliforms which some persons may prefer since Aeromonas is an
important indicator organism.
Example IV
In this example, the selected microorganisms to be detected, quantified
and differentiated are E. coli, coliforms and Salmonella as a first distinct color
and Aeromonas as a second distinct color. One test medium which achieves
this result is the test medium described in Example II, except that the first
substrate and metallic salt are omitted. Thus, because the enzyme pattern of E.
coli reacts with the same substrates as the enzyme pattern for general
coliforms, E. coli and general coliforms will be the same color in this test
medium. Specifically, E. coli, coliforms and Salmonella colonies will show as
a purple-blue color, whereas Aeromonas colonies will show as a substantially
red-pink color.
Example V
The selected microorganisms to be detected, quantified and
differentiated are E. coli, general coliforms and Aeromonas as a first distinct
color, and Salmonella as a second distinct color. One test medium which
achieves this result is the test medium of Example 3 with the first substrate
and metallic salt being omitted. In this test medium, E. coli, general coliforms
and Aeromonas colonies will show as a generally purple-blue color, whereas
Salmonella colonies will show as a generally teal-green color or as a red-pink
color.

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Optionally, the 6-chloro-S-indolyl-α-D-galactoside can be replaced
with 5-bromo-4-chloro-3-indolyl-β-D-galactoside so that Salmonella colonies
show as teal, rather than pink.
A third way to achieve the same result is with an antibiotic, preferably
nalidixic acid, to inhibit the growth of Aeromonas colonies. If Aeromonas is
eliminated, then the purple-blue colonies are all true coliforms. If not
eliminated, any Aeromonas will be counted as part of the coliforms which
some persons may prefer since Aeromonas is an important indicator organism.
Example VI
The selected microorganisms to be detected, quantified and
differentiated are E. coli and coliforms as a first distinct color, Aeromonas as a
second distinct color and Salmonella as a third distinct color. A test medium
which achieves this result is the test medium of Example I with the first
substrate and metallic salt being omitted. In such a test medium, E. coli and
general coliform colonies will show as purple-blue, Aeromonas colonies will
show as generally red-pink, and Salmonella colonies will show as generally
teal-green.
Example VII
The selected microorganisms to be detected, quantified and
differentiated are E. coli as a first distinct color which is substantially black;
general coliforms as a second distinct color which is substantially purple-blue;
Aeromonas/Vibrio/Plesiomonas as a third distinct color which is substantially
red-pink; and Salmonella as a fourth distinct color which is substantially teal-
green.
With reference to Table IV, E. coli produces the enzyme Bgluc, and
Bgluc is not produced by any of the other microorganisms desired to be
detected. Therefore, a substrate which produces a distinct color upon cleavage
of Bgluc should be chosen from Table V. 8-hydroxyquinoline-β-D-
glucuronide produces a substantially black color in the presence of Bgluc and
would be the preferred choice of substrate, as explained below. A metallic salt
such as ferric ammonium citrate is also added to form a substantially black

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water insoluble complex consisting of the ferric ions and the aglycone released
when the substrate is hydrolyzed by the glucuronidase from E. coli.
With further reference to Table IV, it can be seen that the enzyme Ngal
and Naglu are common to the microorganisms Aeromonas, Plesiomonas , and
Vibrios. Therefore, a suitable substrate for testing all of these microorganisms
as a single distinct color is 6-chloro-S-indolyl-N-acetyl-β-D-galactosaminide,
which produces a substantially red-pink color in the presence of these
enzymes.
Again referring to Table IV, Bman, Aara and Agal are common to
Salmonella and general coliforms. However, as indicated in Table IV, Bman,
Aara and Agal are not produced by Aeromonas. Therefore, a substrate can be
selected from Table V which reacts with one of Bman, Aara and Agal to
produce a third distinct color. As shown in Table V, 5-bromo-4-chloro-3-
indolyl-α-D-galactoside produces a teal-green color in the presence of Agal
and is therefore selected as a substrate.
In this test medium E. coli colonies will show as substantially black,
general coliform colonies will show as substantially purple-blue, Aeromonas,
Vibrio and Plesiomonas colonies will show as substantially red-pink, and
Salmonella colonies will show as substantially teal.
Example VIII
The selected microorganisms to be detected, quantified and
differentiated are E. coli as a first distinct color; coliforms and Salmonella as a
second distinct color; and Aeromonas, Vibrio and Plesiomonas as a third
distinct color. One test medium for achieving this result is the test medium of
Example 2, except that the fourth substrate chosen is 6-Chloro-3-indolyl-N-
acetyl-α-D-galactosaminide, to which each of the microorganisms
Plesiomonas, Vibrios and Aeromonas are responsive so that each of these
colonies shows as a generally red-pink color.
Example IX
The selected microorganisms to be detected, quantified and
differentiated in this example are E. coli and general coliforms as a first
distinct color which is purple-blue; Aeromonas, Plesiomonas, and Vibrios as a

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second distinct color which is red-pink; and Salmonella as a third distinct
color which is teal-green. This result can be achieved with the test medium as
described in Example 6 with the addition of 6-Chloro-3-indolyl-N-acetyl- β-D-
galactosaminide, to which each of the microorganisms Plesiomonas, Vibrio
and Aeromonas is responsive.
Example X
The selected microorganisms to be detected, quantified and
differentiated in this example are E. coli and general coliforms as a first color;
Aeromonas, Vibrio and Plesiomonas as a second distinct color; and
Salmonella as a third distinct color. A suitable test medium that achieves this
result is the test medium disclosed in Example 7 except that the first substrate
for detecting E. coli colonies is omitted. In this example, E. coli and general
coliform colonies show as generally purple-blue, Aeromonas, Vibrio and
Plesiomonas show as generally red-pink, and Salmonella show as generally
teal-green. The addition of 6-Chloro-3-indolyl-P-D-galactopyranoside is
necessary to yield the purple-blue color for E. coli colonies.
Example XI
The selected microorganisms to be detected, quantified and
differentiated in this example are E. coli as a substantially black color and
general coliforms as a red-pink color. With reference to Table IV, E.
coli produces the enzyme Bgluc, and Bgluc is not produced by any of the
other microorganisms desired to be detected. Therefore, a substrate which
produces a distinct color upon cleavage of Bgluc should be chosen from Table
V. 8-hydroxyquinoline-β-D-glucuronide produces a dark color in the presence
of Bgluc and would be the preferred choice of substrate. A metallic salt such
as ferric ammonium citrate is also added to form a black water insoluble
complex consisting of ferric ions and the aglycone released when the substrate
is hydrolized by glucuronidase from E. coli.
With further reference to Table IV, Bgal, Bfuc and Bglu are common
to Aeromonas and general coliforms. However, as indicated in Table IV,
Bgal, Bfuc and Bglu are not generally produced by Salmonella. Therefore, a
substrate can be selected from Table V which reacts with one of Bgal, Bfuc

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and Bglu to produce a second distinct color. 6-chloro-3-indolyl-β-D-
galactopyranoside produces a pink color in the presence of Bgal and is
selected as the second substrate.
Optionally, the 6-chloro-3-indolyl-β-D-galactopyranoside can be
replaced with S-bromo-β-chloro-S-indolyl-β-D-galactopyranoside so that
Aeromonas and general coliform colonies show as teal instead of pink.
As noted, the second substrate selected will result in colonies of
Aeromonas also showing as a generally red-pink color. To avoid growth of
Aeromonas colonies, an inhibitor, preferably nalidixic acid, is added. Thus,
colonies of E. coli will show as substantially black, whereas colonies of
general coliforms will show as a red-pink color.
Example XII
The selected microorganisms to be detected, quantified and
differentiated in this example are E. coli, general coliforms and Aeromonas
spp. as a substantially black color and Salmonella spp. as a second distinct
color. The first substrate selected is 8-hydroxyquinoline-β-D-galactoside,
which results in colonies of E. coli, general coliforms and Aeromonas showing
as substantially black. The second substrate chosen can be either 5-Bromo-4-
chloro-3-indolyl-α-D-galactopyranoside or 6-chloro-3-indolyl-α-D-
galactopyranoside. If the former of these two substrates is chosen, colonies of
Salmonella will show as a teal color, whereas if the latter of the two
aforementioned substrates is chosen, colonies of Salmonella will show as a
red-pink color.
Optionally, in this example, Aeromonas may be eliminated by adding
an inhibitor, preferably nalidixic acid, as discussed in detail above.
Example XIII
The selected microorganisms to be detected, quantified and
differentiated in this example are the same as in Example 1, except that this
example illustrates a correction for false positives. That is, it is possible that
certain unusual Enterobacter and Klebsiella spp. will show as black colonies
along with E. coli in the test medium disclosed in Example 1. Thus, the count
of E. coli could be inaccurately high.

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In this example, 4-methyl-umbrelliferyl-β-D-xylopyranoside is added
to the test medium described in Example 1. In so doing, Enterobacter and
Klebsiella spp. showing as black colonies will also fluoresce, thereby allowing
reduction in the false positive count of E. coli. This example illustrates the
flexibility of embodiments incorporating the present invention. The
fluoroescent component does not interfere with the substantially black color so
that the black colonies are easily distinguished with the naked eye. Yet, under
ultraviolet light, false positives can be detected and substantially reduced by
examining the black colonies for fluorescence.
Example XIV
The selected microorganisms to be detected, quantified, differentiated
and identified are E. coli as a substantially black color and Salmonella spp. as
pink-red. General coliforms are colorless in this example.
With reference to Example I, E.Coli is responsive to 8-hydroxy-
quinoline- β-D-glucuronide. General coliforms, Salmonella and Aeromonas
are not responsive to 8-hydroxy-quinoline- β-D-glucuronide. Thus, the first
substrate chosen is 8-hydroxy-quinoline- β-D-glucuronide.
With reference to table IV, esterase enzyme is positive for Salmonella
spp., but not any of the other preferred microorganisms to be detected. With
reference to table V, the substrate 6-chloro-3-indolyl-caprylate can be
identified, and will produce a pink-red color upon cleavage, and is therefore
chosen as the second substrate.
In this test medium, colonies of E. coli will show as substantially
black and colonies of Salmonella will show as pink-red.
Example XV
The selected microorganisms to be detected, quantified, differentiated
and identified are E. coli as a substantially black color, Salmonella spp. as
dark blue-purple, and general coliforms as red-pink.
With reference to Example I, E. coli is responsive to 8-hydroxy-
quinoline- β-D-glucuronide. General coliforms, Salmonella and Aeromonas
are not responsive to 8-hydroxy-quinoline-β-D-glucuronide. Thus, the first
substrate chosen is 8-hydroxy-quinoline- β-D-glucuronide.

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With reference to tables IV and V, 5-bromo-4-chloro-3-indolyl-
caprylate can be identified as the second substrate to which Salmonella will be
responsive. With further reference to Table V, 5-bromo-4-chloro-3-indolyl-
caprylate forms a teal color upon cleavage.
6-chloro-S-indolyl-α-D-galactopyranoside, which produces a pink-red
color upon cleavage, is chosen as the third substrate to which E.coli general
coliforms and Salmonella are responsive.
In this example, E. coli colonies show as substantially black, general
coliform colonies show as red-pink, and Salmonella show as blue-violet (=
red-pink + teal).
Example XVI
The selected microorganisms to be detected, quantified and
differentiated in this example are E. coli as a substantially black color and
general coliforms as a second distinct color.
With reference to Table IV, E. coli produces the enzyme Bgluc, and
Bgluc is not produced by any of the other microorganisms desired to be
detected. Therefore, a substrate which produces a distinct color upon cleavage
of Bgluc should be chosen from Table V. 8-hydroxyquinoline-β-D-
glucuronide produces a dark color in the presence of Bgluc and would be the
preferred choice of substrate. A metallic salt such as ferric ammonium citrate
is also added to form a black water insoluble complex consisting of ferric ions
and the aglycone released when the substrate is hydrolized by glucuronidase
from E. coli.
With further reference to Table IV, Bgal, Bfuc and Bglu are common
to Aeromonas and general coliforms. However, as indicated in Table IV,
Bgal, Bfuc and Bglu are not generally produced by Salmonella. Therefore, a
substrate can be selected from Table V which reacts with one of Bgal, Bfuc
and Bglu to produce a second distinct color. 5-bromo-4-chloro-3-indolyl-β-D-
galactopyranoside can be chosen as the second substrate, in which event
colonies of E. coli will appear as substantially black and general colifom
colonies will appear as teal. Optionally, 5-bromo-6-chloro-3-indolyl-
galactopyranoside can be chosen as the second substrate, in which event

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colonies of E. coli will appear as substantially black and general colifom
colonies will appear magenta. To avoid growth of Aeromonas colonies, an
inhibitor, preferably nalidixic acid, is added. Thus, colonies of E. coli will
show as substantially black, whereas colonies of general coliforms will show
as a magenta color.
Example XVII
Some selected micro-organisms that can be detected, quantified and
differentiated in this example are E. coli, general coliforms, Aeromonas,
and/or Salmonella. The substrates 5-bromo-4-chloro-3-indolyl- β-D-
glucuronide, 6-chloro-3-indolyl- β-D-galactopyranoside, and 5-bromo-4-
chloro-3-indolyl- α-D-galactopyranoside are added in quantities of
approximately 125 mg/1 medium; 200 mg/1 medium; and 65 mg/1 medium,
respectively. The remaining preparation and inoculation of the test medium in
this example is similar to that discussed above, except that ions of salt are not
required when the medium does not have a nonchromogenic substrate. In this
medium, E.coli, which reacts with all of the substrates, will appear as a very
dark blue and/or purple color because the high concentration of the P-D-
glucuronide will predominate. The general coliforms, which react to both the
α- and β-D-galactopyranoside appear as a light blue-gray color. Salmonella,
which reacts with the a-D-galactopyranoside will have a teal color and
Aeromonas, which reacts with β-D-galactopyranoside will have a pink-red
color. It can be beneficial if the concentration/amount used of the β-D-
glucuronide is greater than the β-D-galactopyranoside to increase the
difference in coloration/darkness between the E. coli and general coliforms,
since these substrates utilize the same color compound in this example.
However, even if the same amounts of β-D-glucuronide and β-D-
galactopyranoside are used, the E. coli may still be darker and distinguishable
from general coliforms since it reacts to both of these substrates whereas the
general coliforms do not react with the β-D-glucuronide.
Example XVIII
An alternate β-D-glucuronide substrate that may be utilized is 5-iodo-
3-indolyl- β-D-glucuronide, which is commonly known as Iodo-Gluc. Selected

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micro-organisms to be detected, quantified and differentiated in this example
are E. coli, general coliforms, Aeromonas, and Salmonella. The concentration
of the β-D-glucuronide must be sufficient to provide a very dark purple color
that can be readily distinguished from the blue-gray color of the general
coliforms.
Example XIX
Another alternate β-D-glucuronide substrate that may be used is
indoxyl-β-D-glucuronide, which is commonly known as IBDG. With a
sufficient concentration of IBDG, E. coli will appear darker than the other
colonies as a dark blue-purple color. General coliforms, Salmonella, and
Aeromonas will appear as light blue-gray, teal and red-pink, respectively.
Example XX
In this example, 4-methylumbelliferyl- β-D-glucuronide, commonly
known as MUGluc, is used instead of a chromogenic or nonchromogenic β-D-
glucuronide. With this medium, E. coli will be light blue-gray and fluoresce
under ultraviolet light, and general coliforms will be light blue-gray,
Salmonella will be teal, and Aeromonas will be pink-red in ambient light. An
advantage of the MUGluc is that the incubation times required for detection of
the colonies may be substantially less than that required with the other
chromogenic or nonchromogenic substrates. An incubation time of about 14
hours should be sufficient to detect E. coli with this substrate. A disadvantage
is that the fluorescent products are more readily diffusible than the other
compounds and may make it more difficult to quantify the E. coli. However,
even if the E. coli can not be quantified in a given test, it will still certainly be
suitable for a presence/absence test for E. coli.
Example XXI
In this medium, a 4-methylumbelliferyl-β-D-glucuronide (MUGluc) is
combined with one of the other previously mentioned chromogenic or
nonchromogenic glucuronide substrates as well as with chromogenic α- and β-
D-galactopyranosides. This medium offers the advantage that a
presence/absence test for E. coli may be performed with shorter incubation
times than required for the chromogenic and nonchromogenic substrates. In

WO 2006/107583 PCT/US2006/010177
52
addition, if for any reason, it is uncertain whether colonies of detected
organisms are E. coli or general coliforms, the medium can be examined under
ultraviolet light so that colonies of E. coli can be confirmed by fluorescence.
This provides a double check on the accuracy of the identity of the colonies.
Example XXII
In this example, one of the previously mentioned chromogenic or
nonchromogenic β-D-glucuronide substrates is combined with a chromogenic
β-D-galactopyranoside and a chromogenic β-D-galactopyranoside. In
addition, the medium includes a 4-methylumbelliferyl-α-D-galactopyranoside.
The glucuronide substrate in one example is a 5-bromo-4-chloro-3-indolyl-β-
D chromogenic glucuronide. The medium also includes a 6-chloro-3-indolyl-
β-D-galactopyranoside and a 5-bromo-4-chloro-3-indolyl α-D-
galactopyranoside. This medium offers the advantage that any organisms that
react with an α-D-galactopyranoside will fluoresce under ultraviolet light.
Additionally, the fluorescent results tend to show up faster than any results
having a positive reaction to the chromogenic or nonchromogenic substrates.
Accordingly, E. coli, general coliforms, and Salmonella, which all react to α-
D-galactopyranoside, will fluoresce under ultraviolet light. In addition, when
the reactions with the chromogenic substrates have had sufficient time, that E.
coli will be a very dark blue due to a reaction to both the glucuronide and α-D-
galactoside teal substrates and the pink β-D-galactoside substrate. Coliforms
will show as a lighter blue than E. coli due to a combination of the teal α-D-
galactoside substrate and pink β-D-galactoside substrate. Aeromonas will be a
pink color in response to the reaction with the β-D-galactoside substrate and
Salmonella will be a teal color in response to the reaction with the α-D-
galactoside substrate.
Example XXIII
This example uses chromogenic substrates of 5-bromo-4-chloro-3-
indolyl-β-D-glucuronide; 6-chloro-3-indolyl-β-D-galactopyranoside; and 5-
bromo-4-chloro-3- indolyl-α-D-galactopyranoside. However, instead of 4-
methylumbelliferyl-α-D-galactopyranoside, a 4-methylumbelliferyl- β-D-
galactopyranoside is used. Under ambient light, E. coli, general coliforms,

WO 2006/107583 PCT/US2006/010177
53
Aeromonas and Salmonella will have the same colors as in Example XXII. In
addition, E. coli and general coliforms will still fluoresce, as both will react to
the β-D-galactoside substrate; however, in this instance, Aeromonas will also
fluoresce under ultraviolet light because of the presence of the β-D-
galactosidase activity. Salmonella, however, will not fluoresce as it is
negative for β-D-galactopyranoside.
In Examples XXII and XXIII, the same chromogenic color component
is used in the β-D-glucuronide and the α-D-galactopyranoside. The same
amount of color component may be used in each substrate, and the E. coli will
still appear as a darker blue than general coliforms as the products formed in
the presence of E. coli result from both the β-D-glucuronide and the α-D-
galactopyranoside, which both produce a teal color, as well as the β-D-
galactopyranoside, which produces a pink color, while coliforms only react
with the a- and β-D-galactopyranosides. It is also possible to increase the
amount of the color component in the β-D-glucuronide as compared to the α-
D-galactopyranoside, so that the E. coli will appear even darker, making the E.
coli more readily distinguishable from general coliforms. Furthermore, as
another alternative, a nonchromogenic substrate such as 8-hydroxyquinolin
plus ions may be used for the β-D-glucuronide instead of a chromogenic
substrate as in other examples above.
Example XXIV
In this example, a 4-methylumbelliferyl-β-D-glucuronide commonly
known as MUGluc is used in combination with a chromogenic or
nonchromogenic β-D- glucuronide substrate. For example, a 5-bromo-4-
chloiO-3-indolyl-β-D-glucuronide substrate may be used. This medium
provides the ability to perform a double validation of positive results for
E. coli in a single test. In addition, the method provides a means of
performing an initial check for E. coli under ultraviolet light as E. coli, which
react with β-D-glucuronide will fluoresce when exposed to ultraviolet light. In
addition, the E. coli will also react with the chromogenic substrate and be seen
as a teal color under ambient light. The MUGluc results will likely be
available before the results with a chromogenic substrate for an initial

WO 2006/107583 PCT/US2006/010177
54
examination, and the follow-up examination of the medium for the presence of
teal colonies will confirm the presence of E coli, and allow for quantifying the
colonies. This method offers a significant advantage over other current
verification tests for checking for E. coli, such as a test for checking for the
presence of tryptophanase, which is also unique to E. coli and not generally
present in other coliforms. However, there is no current way to incorporate
the test for both tryptophanase and glucuronide in the same medium so that the
check for tryptophanase requires a separate preparation and test.
Example XXV
In this medium, a fluorescent 4-methylumbelliferyl-α-D-
galactopyranoside and chromogenic 5-bromo-4-chloro-3-indolyl-β-D-
galactopyranoside are used. E. coli and general coliforms both react with α-D-
galactopyranoside and β-D-galactopyranoside so that the total coliforms will
appear as teal under ambient light and fluoresce under ultraviolet light. E. coli
will be the same color as general coliforms in this particular medium.
Aeromonas which reacts with β-D-galactopyranoside will appear as teal under
ambient light and will not fluoresce, and Salmonella, which will not be
colored in ambient light, will fluoresce under an ultraviolet light.
Example XXVI
This example uses a chromogenic 5-bromo-4-chloro-3-indoly-α-D-
galactopyranoside and fluorescent 4-methylumbelliferyl- β-D-
galactopyranoside. As with Example XXV, E. coli and general coliforms will
appear the same so that the total coliforms will be teal under ambient light and
will fluoresce under ultraviolet light. Aeromonas will have no color under
ambient light, but will fluoresce under an ultraviolet light, and Salmonella will
show as teal in ambient light and will not fluoresce under ultraviolet light. It
should be evident that other chromogenic and nonchromogenic or fluorogenic
substrate components may be substituted for those specified in Examples
XXV and XXVI.
Although several broad examples which incorporate the present
invention have been described above, it is to be understood that the present
invention is not to be limited by the examples disclosed herein. Indeed, the

WO 2006/107583 PCT/US2006/010177
55
disclosure and examples above teach one of ordinary skill a virtually limitless
number of test media which would be within the scope of the claims appended
hereto.
Further, while this invention has been described as having a preferred
design, the present invention can be further modified within the spirit and
scope of this disclosure. This application is therefore intended to cover any
variations, uses, or adaptations of the invention using its general principles.
Further, this application is intended to cover such departures from the present
disclosure as come within known or customary practice in the art to which this
invention pertains and which fall within the limits of the appended claims.

PCT/US2006/010177
MLB0001.03.PCT
JANUARY 30, 2007
REPLACEMENT CLAIMS
1. A test medium for detecting, quantifying or differentiating general
coliforms, E. coli, Aeromonas and Salmonella, said test medium
comprising:
a β-D-glucuronide chromogenic or non chromogenic substrate,
which forms a first product that is visible in ambient
light in the presence of E. coli;
an α-D-galactoside chromogenic substrate, which forms a
second product that is visible in ambient light in the
presence of the Salmonella, E. coli and other coliforms;
and
a β-D-galactoside chromogenic substrate, which forms a third
product that is visible in ambient light in the presence of
Aeromonas, E. coli and other coliforms, said products
of said α-D-galactoside and said β-D-galactoside
substrates forming a combined color in the presence of
general coliforms and E. coli, and wherein general
coliforms, E. coli, Aeromonas, and Salmonella are all
distinguishable from one another; and
a fourth substrate being one of a β-D-glucuronide substrate, an
α-D-galactoside substrate, or a β-D-galactoside
substrate, which forms a product that fluoresces under
ultraviolet light in the presence of at least one of E. coli,
general coliforms, Salmonella, or Aeromonas.
2. The test medium of claim 1, wherein said fourth substrate is a β-D-
glucuronide substrate and the product of the fourth substrate formed in
the presence of E. coli fluoresces under an ultraviolet light.
BDDB01 4654145vl
56

MLB0001.03.PCT
JANUARY 30,2007
REPLACEMENT CLAIMS
3. The test medium as set forth in claim 1, wherein said fouth substrate is
an α-D-galactoside substrate, and the product of the fourth substrate
formed in the presence of E. coli, general coliforms and/or Salmonella
fluoresces under an ultraviolet light.
54. The test medium as set forth in claim 1, wherein said fourth substrate is
a β-D-galactoside substrate and the product formed in the presence of
E. coli, general coliforms and/or Aeromonas fluoresces under an
ultraviolet light.
5. The test medium as set forth in claim 1, wherein said β-D-glucuronide
chromogenic or nonchromogenic substrate produces color and one of
either said α-D-galactoside chromogenic substrate or said β-D-
galactoside chromogenic substrate includes the same color component
as said chromogenic or nonchromogencic β-D-glucuronide substrate.
6. The test medium as set forth in claim 5, wherein said β-D-glucuronide
chromogenic or nonchromogencic substrate and said α-D-galactoside
chromogenic substrate or said β-D-galactoside chromogenic substrate
are present in equal amounts.
7. The test medium of claim 5, wherein said β-D-glucuronide substrate
and said one of either said α-D-galactoside chromogenic substrate or
said β-D-galactoside chromogenic substrate are present in different
amounts.
8. The test medium of claim 7, wherein there is more of said β-D-
glucuronide substrate than said α-D-galactoside chromogenic substrate
or said β-D-galactoside chromogenic substrate of the same color
component.
9. The test medium of claim 1, wherein said fouth substrate includes the
fluorescent component 4-methylumbelliferyl.
BDDB01 4654145vl
57

MLB0001.03.PCT
JANUARY 30,2007
REPLACEMENT CLAIMS
10. A test medium for detecting, identifying and qualifying or quantifying
biologic entities, said medium comprising:
a nutrient-based medium;
a first substrate, which forms a first product in the presence of a
first biological entity;
a second substrate, which forms a second product in the
presence of a second biological entity; and
a third substrate, which forms a third product in the presence of
a third biological entity, said second and third substrates
also forming a combined product in the presence of a
fourth biological entity, said second and third substrates
forming a combined product in the presence of said first
biological entity, wherein said first and said second
substrates include the same color forming component,
and said first biological entity appears darker than said
fourth biological entity as said first biological entity
reacts to all of said substrates.
11. The test medium as set forth in claim 10, wherein said first substrate
includes more of said color forming component than said second
substrate.
12. The test medium as set forth in claim 10, wherein said first and said
third substrates include the same color forming component, and said
first biological entity appears darker than said fourth biological entity
as said first biological entity reacts to all of said substrates.
2513. The test medium as set forth in claim 10, wherein said first substrate
includes more of said color forming component than said third
substrate.
20BDDB01 4654145vl
58

MLB0001.03.PCT
JANUARY 30, 2007
25 REPLACEMENT CLAIMS
14. The test medium as set forth in claim 10, including a fourth substrate,
which forms a product in the presence of one of said biological entities
that fluoresces under an ultraviolet light.
15. The test medium as set forth in claim 14, wherein said first substrate is
a β-D-glucuronide chromogenic or nonchromogenic substrate and said
first biological entity is E. coir, said second substrate is an a-D-
galactoside chromogenic substrate and said second biological entity is
Salmonella; said third substrate is a P-D-galactoside chromogenic
substrate and said third biological entity is Aeromonas; and said fourth
biological entity is general coliforms.
16. A test medium for detecting, identifying, or quantifying a biological
entity, said medium comprising:
a nutrient-based medium;
a first substrate, which is a chromogenic or nonchromogenic
substrate, which forms a product that is visible in
ambient light in the presence of a first biological entity;
and
a second substrate, which produces a product that fluoresces
under an ultraviolet light in the presence of said first
biological entity.
17. The test medium as set forth in claim 16, wherein said first substrate is
a β-D-glucuronide substrate and said first biological entity is E coli.
18. The test medium as set forth in claim 17, wherein said second substrate
is a 4-methylumbelliferyl β-D-glucuronide substrate.
BDDB01 4654145vl
59

MLB0001.03.PCT
30 JANUARY 30, 2007
REPLACEMENT CLAIMS
19. The test medium as set forth in claim 18, wherein said medium
provides a dual verification of the presence of E coli, wherein a first
verification is the fluorescence of E coli under ultraviolet light and the
second verification is a visual identification under ambient light of a
product from the chromogenic or nonchromogenic substrate.
20. The test medium as set forth in claim 19, wherein said verification of
Ecoli as fluorescing under an ultraviolet light is detectable before the
visible identification from the chromogenic or nonchromogenic
substrate.
21. The test medium as set forth in claim 16, wherein said first substrate is
an α-D-galactopyranoside and said second substrate is a β-D-
galactopyranoside.
22. The test medium as set forth in claim 21, wherein said first biological
entity is total coliforms and said second substrate also produces a
product that fluoresces under an ultraviolet light in the presence of
Aeromonas.
23. The test medium as set forth in claim 22, wherein said first substrate is
5-bromo-4-chloro-3-indolyl-α-D-galactopyranoside, and the product
formed in the presence of total coliforms is teal, and a teal product is
also formed in the presence of Salmonella.
24. The test medium as set forth in claim 16, wherein said first substrate is
a β-D- galactopyranoside and said second substrate is a α-D-
galactopyranoside.
25. The test medium as set forth in claim 24, wherein said first biological
entity is total coliforms and said second substrate also produces a
product that fluoresces under an ultraviolet light in the presence of
Salmonella.
BDDB01 4654145vl
60

MLB0001.03.PCT
JANUARY 30, 2007
REPLACEMENT CLAIMS
40
26. The test medium as set forth in claim 25, wherein said first substrate is
5-bromo-4-chloro-3-indolyl-P-β-galactopyranoside, and the product
formed in the presence of total coliforms is teal, and a teal product is
also formed in the presence of Aeromonas.
27. The test medium as set forth in claim 16, further including one or more
additional substrates that are specific for one or more different and
additional enzymes than the first and second substrates and that
produce a product that is either visible in ambient light or fluoresces
under ultraviolet light in the presence of biological entities other than
said first biological entity, and wherein all of said products are visually
distinguishable from one another.
28. The test medium as set forth in claim 27, wherein said first substrate is
a β-D-glucuronide substrate and said first biological entity is E. coli.
29. The test medium as set forth in claim 27, wherein said second substrate
is a 4-methylumbelliferyl P-D-glucuronide substrate.
30. The test medium as set forth in claim 27, wherein one of said
additional substrates is a p-D-galactoside substrate.
31. The test medium as set forth in claim 27, wherein said first substrate is
5-bromo-4-chloro-3-indolyl-P-D-glucuronide, said second substrate is
4-methylumbelliferyl-P-D-glucuronide and said additional substrate is
6-Chloro-3-indolyl-P-D-galactoside, and said first biological entity is
E. coli and an additional biological entity is a general coliform species
other than E. coli.
BDDB01 4654145vl
61

MLB0001.03.PCT
JANUARY 30, 2007
REPLACEMENT CLAIMS
32. The test medium as set forth in claim 31, wherein said medium
provides a dual verification of the presence of E. coli, with a first
verification being a visual identification under ambient light of a
product from said first substrate, and a second verification is the
fluorescence of E. coli under ultraviolet light, and wherein general
coliform species appear as pink/red colored colonies from the effect of
said 6-Chloro-3-Indolyl-β-D-galactoside additional substrate, and the
E. coli will appear as blue/purple colonies in ambient light due to the
combination of said 5-Bromo-4-Chloro-3-Indolyl-β-D-glucuronide and
said 6-Chloro-3-Indolyl-P-D-galactoside substrates.
33. The test medium as set forth in claim 32, wherein said verification of
E. coli as fluorescing under an ultraviolet light is detectable before the
visible identification from the chromogenic substrates.
34. The test medium as set forth in claim 31, further including a 5-Bromo-
4-Chloro-3-Indolyl-α-D-galactoside substrate, a third biological entity
being a Salmonella species, and a fourth biological entity being an
Aeromonas species.
35. The test medium and biological entities as set forth in claim 34,
wherein E. coli appear blue/purple in ambient light and fluoresce under
ultraviolet light, general coliforms appear blue-grey in ambient light,
Salmonella appear teal green in ambient light, and Aeromonas appear
pink/red in ambient light so that E. coli, general coliforms, Salmonella,
and Aeromonas are all visually distinguishable from one another.
-62-
BDDB01 4654145vl

A test medium and method for detecting, quantifying, identifying and differentiating up to four (4) separate biological
materials in a test sample. A test medium is disclosed which allows quantifying and differentiating under ambient light aggregates
of biological entities producing specific enzymes, which might include general coliforms, E. coli, Aeromonas, and Salmonella in
a single test medium. A new class of nonchromogenic substrates is disclosed which produce a substantially black, non-diffusible
precipitate. This precipitate is not subject to interference from other chromogenic substrates present in the test medium. In one
embodiment, the substrates are selected such that E. coli colonies present in the test medium show as substantially black, general
coliforms colonies show in the test medium as a blue-violet color, Aeromonas colonies present in the test medium show as a generally
red- pink color, and Salmonella colonies show as a generally teal-green color. Other microorganisms and color possibilities
for detection and quantification thereof are also disclosed. An inhibitor and method for making a test medium incorporating the
inhibitor are disclosed.

Documents:

03779-kolnp-2007-abstract.pdf

03779-kolnp-2007-claims.pdf

03779-kolnp-2007-correspondence others.pdf

03779-kolnp-2007-description complete.pdf

03779-kolnp-2007-form 1.pdf

03779-kolnp-2007-form 3.pdf

03779-kolnp-2007-form 5.pdf

03779-kolnp-2007-international exm report.pdf

03779-kolnp-2007-international publication.pdf

03779-kolnp-2007-international search report.pdf

03779-kolnp-2007-pct priority document notification.pdf

03779-kolnp-2007-pct request form.pdf

03779-kolnp-2007-priority document.pdf

3779-KOLNP-2007-(25-02-2013)-ABSTRACT.pdf

3779-KOLNP-2007-(25-02-2013)-CLAIMS.pdf

3779-KOLNP-2007-(25-02-2013)-CORRESPONDENCE.pdf

3779-KOLNP-2007-(25-02-2013)-DESCRIPTION (COMPLETE).pdf

3779-KOLNP-2007-(25-02-2013)-FORM-1.pdf

3779-KOLNP-2007-(25-02-2013)-FORM-13.pdf

3779-KOLNP-2007-(25-02-2013)-FORM-2.pdf

3779-KOLNP-2007-(25-02-2013)-OTHERS.pdf

3779-KOLNP-2007-CORRESPONDENCE.pdf

3779-kolnp-2007-form 18.pdf


Patent Number 263810
Indian Patent Application Number 3779/KOLNP/2007
PG Journal Number 48/2014
Publication Date 28-Nov-2014
Grant Date 21-Nov-2014
Date of Filing 05-Oct-2007
Name of Patentee MICROLOGY LABORATORIES, LLC.
Applicant Address 1303 EISENHOWER DR., S, GOSHEN, INDIANA
Inventors:
# Inventor's Name Inventor's Address
1 ROTH GEOFFREY N. 19676 RIVERVIEW DRIVE, GOSHEN, INDIANA 46526-0340
2 ROTH JONATHAN N. 19676 RIVERVIEW DRIVE, GOSHEN, INDIANA 46526-0340
PCT International Classification Number C12Q 1/04
PCT International Application Number PCT/US2006/010177
PCT International Filing date 2006-03-21
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 11/096908 2005-04-01 U.S.A.