Nucleic acid assays

FIELD OF THE INVENTION

The present invention relates to the detection of specific nucleic acid sequences in a target test sample.

In particular, the present invention relates to the automated detection of specific nucleic acid sequences which are either unamplified or amplified nucleic acid sequences (amplicons).

In addition, the present invention relates to the use of automated amplification, methods and compositions for monitoring successful amplification, improved methods for reducing the chance for contamination, and the use of unified reaction buffers and unit dose aliquots of reaction components for amplification.

Finally, the present invention also relates to unique constructs and methods for the conventional or automated detection of one, or more than one different nucleic acid sequences in a single assay.

THE BACKGROUND OF THE INVENTION

The development of techniques for the manipulation of nucleic acids, the amplification of such nucleic acids when necessary, and the subsequent detection of specific sequences of nucleic acids or amplicons has generated extremely sensitive and nucleic acid sequence specific assays for the diagnosis of disease and/or identification of pathogenic organisms in a test sample.

Amplification of Nucleic Acids

When necessary, enzymatic amplification of nucleic acid sequences will enhance the ability to detect such nucleic acid sequences. Generally, the currently known amplification schemes can be broadly grouped into two classes based on whether, the enzymatic amplification reactions are driven by continuous cycling of the temperature between the denaturation temperature, the primer annealing temperature, and the amplicon (product of enzymatic amplification of nucleic acid) synthesis temperature, or whether the temperature is kept constant throughout the enzymatic amplification process (isothermal amplification). Typical cycling nucleic acid amplification technologies (thermocycling) are polymerase chain reaction (PCR), and ligase chain reaction (LCR). Specific protocols for such reactions are discussed in, for example,

Short Protocols in Molecular Biology

, 2

nd

Edition,

A Compendium of Methods from Current Protocols in Molecular Biology

, (Eds. Ausubel et al., John Wiley & Sons, New York, 1992) chapter 15. Reactions which are isothermal include: transcription-mediated amplification (TMA), nucleic acid sequence-based amplification (NASBA), and strand displacement amplification (SDA).

U.S. Patent documents which discuss nucleic acid amplification include U.S. Pat. Nos. 4,683,195; 4,683,202; 5,130,238; 4,876,187; 5,030,557; 5,399,491; 5,409,818; 5,485,184; 5,409,818; 5,554,517; 5,437,990 and 5,554,516 (each of which are hereby incorporated by reference in their entirety). It is well known that methods such as those described in these patents permit the amplification and detection of nucleic acids without requiring cloning, and are responsible for the most sensitive assays for nucleic acid sequences. However, it is equally well recognized that along with the sensitivity of detection possible with nucleic acid amplification, the ease of contamination by minute amounts of unwanted exogenous nucleic acid sequences is extremely great. Contamination by unwanted exogenous DNA or RNA nucleic acids is equally likely. The utility of amplification reactions will be enhanced by methods to control the introduction of unwanted exogenous nucleic acids and other contaminants.

Prior to the discovery of thermostable enzymes, methods that used thermocycling were made extremely difficult by the requirement for the addition of fresh enzyme after each denaturation step, since initially the elevated temperatures required for denaturation also inactivated the polymerases. Once thermostable enzymes were discovered, cycling nucleic acid amplification became a far more simplified procedure where the addition of enzyme was only needed at the beginning of the reaction. Thus reaction tubes did not need to be opened and new enzyme did not need to be added during the reaction, allowed for an improvement in efficiency and accuracy as the risk of contamination was reduced, and the cost of enzymes was also reduced. An example of a thermostable enzyme is the polymerase isolated from the organism

Thermophilus aquaticus.

In general, isothermal amplification can require the combined activity of multiple enzyme activities for which no optimal thermostable variants have been described. The initial step of an amplification reaction will usually require denaturation of the nucleic acid target, for example in the TMA reaction, the initial denaturation step is usually ≧65° C., but can be typically ≧95° C., and is used when required to remove the secondary structure of the target nucleic acid.

The reaction mixture is then cooled to a lower temperature which allows for primer annealing, and is the optimal reaction temperature for the combined activities of the amplification enzymes. For example, in TMA the enzymes are generally a T7 RNA polymerase and a reverse transcriptase (which includes endogenous RNase H activity). The temperature of the reaction is kept constant through out the subsequent isothermal amplification cycle.

Because of the lack of suitable thermostable enzymes, some isothermal amplifications will generally require the addition of enzymes to the reaction mixture after denaturation at high temperature, and cool-down to a lower temperature. This requirement is inconvenient, and requires the opening of the amplification reaction tube, which introduces a major opportunity for contamination.

Thus, it would be most useful if such reactions could be more easily performed with a reduced risk of contamination by methods which would allow for integrated denaturation and amplification without the need for manual enzyme transfer.

Amplification Buffer and Single Reaction Aliquot of Reagents

Typical reaction protocols require the use of several different buffers, tailored to optimize the activity of the particular enzyme being used at certain steps in the reaction, or for optimal resuspension of reaction components. For example, while a typical PCR 10× amplification buffer will contain 500 mM KCl and 100 mM Tris HCl, pH 8.4, the concentration of MgCl

2

will depend upon the nucleic acid target sequence and primer set of interest. Reverse transcription buffer (5x) typically contains 400 mM Tris-Cl, pH 8.2; 400 mM KCl and 300 mM MgCl

2

, whereas Murine Maloney Leukemia Virus reverse transcriptase buffer (5×) typically contains 250 mM Tris-Cl, pH 8.3; 375 mM KCl; 50 mM DTT (Dithiothreitol) and 15 mM MgCl

2

.

While such reaction buffers can be prepared in bulk from stock chemicals, most commercially available amplification products provide bulk packaged reagents and specific buffers for use with the amplification protocol. For example, commercially available manual amplification assays for detection of clinically significant pathogens (for example Gen-Probe Inc. Chlamydia, and

Mycobacterium tuberculosis

detection assays) requires several manual manipulations to perform the assay, including dilution of the test sample in a sample dilution buffer (SDB), combination of the diluted sample with amplification reaction reagents such as oligonucleotides and specific oligonucleotide promoter/primers which have been reconstituted in an amplification reconstitution buffer (ARB), and finally, the addition to this reaction mixture of enzymes reconstituted in an enzyme dilution buffer (EDB).

The preparation and use of multiple buffers which requires multiple manual additions to the reaction mixture introduces a greater chance for contamination. It would be most useful to have a single unified buffer which could be used in all phases of an amplification protocol. In particular, with the commercially available TMA assays described above, the requirement for three buffers greatly complicates automation of such a protocol.

Bulk packaging of the enzyme or other reaction components by manufacturers, may require reconstitution of the components in large quantities, and the use of stock amounts of multiple reagents, can be wasteful when less than the maximal number of reactions are to be carried out, as some of these components may be stable for only a short time. This process of reconstitution also requires multiple manipulations by the user of the stock reagents, and aliquoting of individual reaction amounts of reagents from stocks which creates a major opportunity for contamination.

Methods and compositions for the preparation of bulk quantities of preserved proteins are known, see for example, U.S. Pat. Nos. 5,098,893; 4,762,857; 4,457,916; 4,891,319; 5,026,566 and International Patent Publications WO 89/06542; WO 93/00806; WO 95/33488 and WO 89/00012, all of which are hereby incorporated by reference in their entirety. However, the use of pre-aliquoted and preserved reagent components in single reaction quantities/dose is both very useful and economical. Single aliquots of enzyme reagent avoids multiple use of bulk reagents, reduceing waste, and greatly reducing the chance of contamination. Further, such single reaction aliquots are most suitable for the automation of the reaction process.

The requirement for many changes of buffer and the multiple addition of reagents complicates the automation of such reactions. A single dose unit of reaction buffer mixture, and a unified combination buffer will both simplify automation of the process and reduce the chance of contamination.

Automation of Nucleic Acid Detection with or without Amplification

Nucleic acid probe assays, and combination amplification/probe assays can be rapid, sensitive, highly specific, and usually require precise handling in order to minimize contamination with non-specific nucleic acids, and are thus prime candidates for automation. As with conventional nucleic acid detection protocols, it is generally required to utilize a detection probe oligonucleotide sequence which is linked by some means to a detectable signal generating component. One possible probe detection system is described in U.S. Pat. No. 4,581,333 hereby incorporated by reference in its entirety.

In addition, automation of a nucleic acid detection system targeting unamplified or amplified nucleic acid, or a combined automated amplification/detection system will generally be adaptable to the use of nucleic acid capture oligonucleotides that are attached to some form of solid support system. Examples of such attachment and methods for attachment of nucleic acid to solid support are found in U.S. Pat. Nos. 5,489,653 and 5,510,084 both of which are hereby incorporated by reference.

Automation of amplification, detection, and a combination of amplification and detection is desirable to reduce the requirement of multiple user interactions with the assay. Apparatus and methods for optically analyzing test materials are described for example in U.S. Pat. No. 5,122,284 (hereby incorporated by reference in its entirety). Automation is generally believed to be more economical, efficient, reproducible and accurate for the processing of clinical assays. Thus with the superior sensitivity and specificity of nucleic acid detection assays, the use of amplification of nucleic acid sequences, and automation at one or more phases of a assay protocol can enhance the utility of the assay protocol and its utility in a clinical setting.

Advantage of Internal Control Sequences

Nucleic acid amplification is highly sensitive to reaction conditions, and the failure to amplify and/or detect any specific nucleic acid sequences in a sample may be due to error in the amplification process as much as being due to absence of desired target sequence. Amplification reactions are notoriously sensitive to reaction conditions and have generally required including control reactions with known nucleic acid target and primers in separate reaction vessels treated at the same time. However, internal control sequences added into the test reaction mixture would truly control for the success of the amplification process in the subject test reaction mixture and would be most useful. U.S. Pat. No. 5,457,027 (hereby incorporated by reference in its entirety) teaches certain internal control sequences which are useful as an internal oligonucleotide standard in isothermal amplification reactions for

Mycobacterium tuberculosis.

However it would be extremely useful to have a general method of generating internal control sequences, that would be useful as internal controls of the various amplification procedures, which are specifically tailored to be unaffected by the nucleic acid sequences present in the target organism, the host organism, or nucleic acids present in the normal flora or in the environment. Generally, such internal control sequences should not be substantially similar to any nucleic acid sequences present in a clinical setting, including human, pathogenic organism, normal flora organisms, or environmental organisms which could interfere with the amplification and detection of the internal control sequences.

Detection of More than One Nucleic Acid Sequence in a Single Assay

In general, a single assay reaction for the detection of nucleic acid sequences is limited to the detection of a single target nucleic acid sequence. This single target limitation increases costs and time required to perform clinical diagnostic assays and verification control reactions. The detection of more than one nucleic acid sequence in a sample using a single assay would greatly enhance the efficiency of sample analysis and would be of a great economic benefit by reducing costs, for example helping to reduce the need for multiple clinical assays.

Multiple analyte detection in a single assay has been applied to antibody detection of analyte as in for example International Patent Publication number WO 89/00290 and WO 93/21346 both of which are hereby incorporated by reference in their entirety.

In addition to reducing cost, time required, the detection of more than one nucleic acid target sequence in a single assay would reduce the chance of erroneous results. In particular multiple detection would greatly enhance the utility and benefit using internal control sequences and allow for the rapid validation of negative results.

SUMMARY OF THE INVENTION

The present invention comprises methods for the automated isothermal amplification and detection of a specific nucleic acid in a test sample to be tested comprising:

a) combining a test sample to be tested with a buffer, a mixture of free nucleotides, specific oligonucleotide primers, and optionally thermostable nucleic acid polymerization enzyme, in a first reaction vessel and placing the reaction vessel in an automated apparatus such that;

b) the automated apparatus heats the first reaction vessel to a temperature, and for a time sufficient to denature, if necessary, the nucleic acid in the sample to be tested;

c) the automated apparatus cools the first reaction vessel to a temperature such that oligonucleotide primers can specifically anneal to the target nucleic acid;

d) the automated apparatus transfers the reaction mixture from the first reaction vessel to a second reaction vessel, and brings the reaction mixture in contact with thermolabile nucleic acid amplification enzyme;

e) the automated apparatus maintains the temperature of the second reaction vessel at a temperature which allows primer mediated amplification of the nucleic acid;

f) the automated apparatus contacts the amplified nucleic acid in the second reaction vessel with a capture nucleic acid specific for the nucleic acid (amplicon) to be tested such that they form a specifically-bound nucleic acid-capture probe complex;

g) the automated apparatus optionally washes the specifically captured amplified nucleic acid such that non-specifically bound nucleic acid is washed away from the specifically-bound nucleic acid-capture probe complex;

h) the automated apparatus contacts the specifically-bound nucleic acid-capture probe complex with a labeled nucleic acid probe specific for the amplified nucleic acid such that a complex is formed between the specifically amplified nucleic acid and the labeled nucleic acid probe;

i) the automated apparatus washes the specifically-bound nucleic acid-capture probe-labeled probe complex such that non-specifically bound labeled probe nucleic acid is washed away from the specifically bound complex;

j) the automated apparatus contacts the specifically bound complex with a solution wherein an detection reaction between the labeled nucleic acid probe is effected between the solution and the label attached to the nucleic acid such that a detectable signal is generated from the sample in proportion the amount of specifically-bound amplified nucleic acid in the sample;

wherein the steps h, i, and j may occur sequentially or simultaneously;

k) the automated apparatus detects the signal and optionally displays a value for the signal, or optionally records a value for the signal.

As used herein, the term test sample includes samples taken from living patients, from non-living patients, from surfaces, gas, vacuum or liquids, from tissues, bodily fluids, swabs from body surfaces or cavities, and any similar source. The term buffer as used here encompasses suitable formulations of buffer which can support the effective activity of a label, for example an enzyme placed into such buffer when treated at the appropriate temperature for activity and given the proper enzymatic substrate and templates as needed. The term specific oligonucleotide nucleic acid primers means an oligonucleotide having a nucleic acid sequence which is substantially complementary to and will specifically hybridize/anneal to a target nucleic acid of interest and may optionally contain a promoter sequence recognized by RNA polymerase. The term reaction vessel means a container in which a chemical reaction can be performed and preferably capable of withstanding temperatures of anywhere from about −80° C. to 100° C.

The instant invention further provides for the method described above, wherein the reaction buffer is a unified buffer and as such is suitable for denaturation nucleic acids and annealing of nucleic acids, and is further capable of sustaining the enzymatic activity of nucleic acid polymerization and amplification enzyme. Further encompassed by the invention is the method wherein the nucleic acid amplification enzyme is administered in the second reaction chamber as a single assay dose amount in a lyophilized pellet, and the reaction chamber is sealed prior to the amplification step.

The invention teaches an apparatus for the automated detection of more than one nucleic acid target sequences or amplicons comprising a solid phase receptacle (SPR® pipet-like devise) coated with at least two distinct zones of a capture nucleic acid oligonucleotide.

The invention teaches a method for the automated detection of more than one nucleic acid target sequence comprising contacting a solid phase receptacle (SPR® pipet-like devise) coated with at least two distinct capture nucleic acid oligonucleotides in a single or multiple zones to a sample to be tested and detecting a signal(s) from specifically bound probe. In one embodiment of the invention, the SPR® is coated with two distinct zones of capture nucleic acid oligonucleotides which are specific for different nucleic acid sequence targets. In another embodiment of the invention, the SPR® is coated with at least one capture probe for a target nucleic acid sequence, and one capture probe for an amplification control nucleic acid sequence which when detected confirms that amplification did take place.

The present invention also comprises an internal amplification randomly generated positive control nucleic acid including the nucleic acid sequence of RIC1 and a second internal amplification positive control nucleic acid having the nucleic acid sequence of RIC2.

The present invention also comprises internal amplification positive control nucleic acids having the nucleic acid sequence of CRIC-2, GRIC, MRIC, and HRIC.

The present invention further comprises a method for generating an internal amplification positive control nucleic acid consisting of:

generating random nucleic acid sequences of at least 10 nucleotides in length, screening said random nucleic acid sequence and selecting for specific functionality, combining in tandem a number of such functionally selected nucleic acid sequences, and screening the combined nucleic acid sequence and optionally selecting against formation of intra-strand nucleic acid dimers, or the formation of hairpin structures.

BRIEF DESCRIPTION OF THE DRAWINGS

Presently preferred embodiments of the invention will be described in conjunction with the appended drawings, wherein like reference numerals refer to like elements in the various views, and in which:

FIG. 1

is a graph illustrating single dose reagent pellet temperature stability;

FIG. 2

illustrates the general TMA protocol;

FIG. 3A

is a schematic representation of a disposable dual chamber reaction vessel and the heating steps associated therewith to perform a TMA reaction in accordance with one possible embodiment of the invention;

FIG. 3B

is a schematic representation of alternative form of the invention in which two separate reaction chambers are combined to form a dual chamber reaction vessel;

FIG. 3C

is a schematic representation of two alternative embodiments of a dual chamber reaction vessel that are snapped into place in a test strip for processing with a solid phase receptacle and optical equipment in accordance with a preferred embodiment of the invention;

FIG. 4

is a schematic representation of an alternative embodiment of a dual chamber reaction vessel formed from two separate chambers that are combined in a manner to permit a fluid sample in one chamber to be transferred to the other chamber, with the combined dual chamber vessel placed into a test strip such as illustrated in

FIG. 3C

;

FIG. 5

is a perspective view of a stand-alone amplification processing station for the test strips having the dual chamber reaction vessels in accordance with a presently preferred form of the invention;

FIG. 6

is a perspective view of one of the amplification modules of FIG.

4

/

31

, as seen from the rear of the module;

FIG. 7

is a perspective view of the front of the module of FIG.

5

/

32

;

FIG. 8

is another perspective view of the module of

FIG. 7

;

FIG. 9

is a detailed perspective view of a portion of the test strip holder and 95° C. Peltier heating subsystems of the module of

FIGS. 6-8

;

FIG. 10

is an isolated perspective view of the test strip holder of

FIG. 9

, showing two test strips installed in the test strip holder;

FIG. 11

is a detailed perspective view of the test strip holder or tray of

FIG. 7

;

FIG. 12

is a block diagram of the electronics of the amplification processing station of

FIG. 7

;

FIG. 13

is a diagram of the vacuum subsystem for the amplification processing station of

FIG. 6

; and

FIG. 14

is a graph of the thermal cycle of the station of FIG.

6

.

FIG. 15

illustrates a schematic of the operation of the multiplex VIDAS detection.

FIG. 16

illustrates the production of SPR® with two distinct capture zones;

FIG. 17

illustrates the VIDAS apparatus strip configuration for multiplex detection;

FIG. 18

illustrates and graphs the results of verification of the VIDAS multiplex protocol detecting only Neisseria gonorrhoeae (NG) target;

FIGS.

19

A/

46

A is a graph showing the results when 1×10

12

CT targets were mixed with 0, 1×10

9

, 1×10

10

, 1×10

11

, or 1×10

12

, NG targets, and detected with the VIDAS instrument using the multiplex protocol and SPRs coated with Chlamydia trachomatis (CT) capture probes on the bottom zone of the SPR®, and NG capture probes on the top zone of the SPR®.

FIGS.

19

B/

46

B illustrates the results when 1×10

12

NG targets was mixed with 0, 1×10

9

, 1×10

10

, 1×10

11

, or 1×10

12

, NG targets, and detected with the VIDAS instrument using the multiplex protocol and SPR® coated with CT capture probes on the bottom zone of the SPR®, and NG capture probes on the top zone of the SPR®.

FIG. 20A

is a diagram showing detection of M.tb nucleic acid by VIDAS apparatus after amplification.

FIG. 20B

is a diagram showing detection of M.tb nucleic acid by VIDAS apparatus.

FIG. 21

is a diagram showing detection of M.tb nucleic acid by VIDAS apparatus after amplification.

FIG. 22

is a diagram showing detection of M.tb nucleic acid by VIDAS apparatus after amplification using the binary/dual chamber protocol.

FIG. 23

illustrates the results generated by the method described showing a collection of strings of nucleic acid sequences and screening for specific functional parameters.

FIG. 24

shows the nucleic acid sequence of Random Internal Control 1 (RIC1) with the possible oligonucleotide primers/probes for amplification and detection of the control sequence.

FIG. 25

shows an analysis of the possible secondary structural components of the RIC1 sequence.

FIG. 26

shows the nucleic acid sequence of Random Internal Control 2 (RIC2) with the possible oligonucleotide primers/probes for amplification and detection of the control sequence.

FIG. 27

shows an analysis of the possible secondary structural components of the RIC2 sequence.

FIG. 28

illustrates results from detection of RIC1 DNA, where the ran21 was the capture probe and ran33 was an enzyme-linked detector-probe, and shows that amplification and detection occurs under standard assay conditions.

FIG. 29

shows that RIC1 RNA, amplified by TMA and the chemically activated signal detected on a VIDAS instrument (bioMérieux Vitek, Inc.) using the enzyme-linked detection system, has a limit of sensitivity of about 1000 molecules of RIC1 RNA (without optimization of conditions).

FIG. 30

shows the nucleic acid sequence for internal control oligonucleotides designed for assays for detecting:

Chlamydia trachomatis

(CT) identified as CRIC-2; for

Neisseria gonorrhoeae

(NG) identified as GRIC; for

Mycobacterium tuberculosis

(MT) identified as MRIC; and internal control for HIV identified as HRIC.

DESCRIPTION OF THE INVENTION

The following examples are provided to better illustrate certain embodiments of the present invention without intending to limit the scope of the invention.

EXAMPLE 1

Single Dose Reagents and Unified Buffer

The implementation of a TMA reaction (see U.S. Pat. No. 5,437,990, incorporated by reference) on-line in a VIDAS or off-line in a separate instrument (with detection occurring on a VIDAS instrument) requires modification of the chemistry used to perform the reaction manually. First, bulk packaged reagents have been modified into single aliquot doses, and second, the buffer components of the reaction have been altered to form a single comprehensive multifunctional unified buffer solution.

Under the current manual technology, the reagents are prepared as lyophilized “cakes” of multiple-assay quantities. The amplification and enzyme reagents thus must be reconstituted in bulk and aliquoted for individual assays.

Thus the automated form of TMA on the VIDAS system improves on the above manual method by utilizing single dose pellets of lyophilized reaction components that can be resuspended in a single unified buffer which will support sample dilution, denaturation of nucleic acids, annealing of nucleic acids, and desired enzymatic activity.

A) Unified Buffer and Single Dose Reagents

To test the feasibility of single dose amplification reagents, standard Chlamydia TMA Amplification and Enzyme reagents (Gen-Probe Inc.), the bulk reagents were reconstituted in 0.75 ml of water. 12.5 μl of either the water reconstituted amplification or enzyme reagent (i.e. a single dose aliquot) were aliquoted into microcentrifuge tubes. These tubes were placed in a vacuum centrifuge with low heat to remove water. The end result of this procedure was microcentrifuge tube containing a small, dry cake of either enzyme or amplification reagent at the bottom of the tube.

The combined Unified Buffer used in this example, consists of a combination of standard commercially available Gen-Probe Inc. Sample Dilution Buffer (SDB), Amplification Reconstitution Buffer (ARB), and Enzyme Dilution Buffer (EDB) in a 2:1:1 ratio. To each dried amplification reagent microfuge tube was added 100 μl of the combined Unified Buffer, and positive control nucleic acid (+), and overlaid with 100 μl of silicone oil. The tube was then heated to 95° C. for 10 minutes and then cooled to 42° C. for 5 minutes. The 200 μl total volume was then transferred to a tube containing the dried enzyme reagent. This was then gently mixed to resuspend the enzyme reagent, and the solution was heated for one hour at 42° C.

Control reactions were prepared using Gen-Probe Control reagents which were reconstituted in the normal 1.5 ml of ARB or EDB according to instructions provided in the Gen-Probe kit. In each control reaction 25 μl of the reconstituted amplification reagent was combined with 50 μl or the SDB with the positive control nucleic acid (+). The mixture was also heated to 95° C. for 10 minutes and then cooled to 42° C. for 5 minutes. To this was added 25 μl of the reconstituted enzyme reagent and incubated at 42° C. for one hour. Negative control had no nucleic acid.

Both the test Unified Buffer (Unified) reactions and the standard Control (Control) reactions were then subjected to the Gen-Probe Inc. standard Hybridization Protection Assay (HPA) protocol. Briefly, 100 μl of a

Chlamydia trachomatis

specific nucleic acid probe was added to each tube and allowed to hybridize for 15 minutes at 60° C. Then 300 μl of Selection Reagent was added to each tube and the differential hydrolysis of hybridized and unhybridized probe was allowed to occur for 10 minutes. The tubes were then read in a Gen-Probe Inc. Leader 50 luminometer and the resultant data recorded as Relative Light Units (RLU) detected from the label, as shown in Table 1 below. Data reported as RLU, standard

C. Trachomatis

TMA/HPA reaction.

TABLE 1

Unified single dose aliquot of amplification and enzyme reagents

Control (+)

Unified (+)

Control (−)

Unified (−)

2,264,426

2,245,495

6,734

3,993

2,156,498

2,062,483

3,484

3,765

1,958,742

2,418,531

5,439

5,836

2,451,872

2,286,773

2,346,131

1,834,198

The data in Table 1 demonstrates that comparable results are obtained when using the single dose aliquots of dried amplification and enzyme reagent. In addition, the data shows that the results were comparable using three separate buffers (ARB, EDB and SDB) and one unified combined buffer (SDB, ARB and EDB combined at a ratio of 2:1:1) to resuspend the reagents and run the reactions.

B) Pellitization of Single Dose Reagents

In order to simplify the single dose aliquoting of reagents, methods which will allow for pelletization of these reagents in single dose aliquots were used. Briefly, reagent pellets (or beads) can be made by aliquoting an aqueous solution of the reagent of choice (that has been combined with an appropriate excipient, such as D(+) Trehalose (α-D-Glucopyranosyl-α-D-glucopyranoside, purchased from Pfanstiehl Laboratories, Inc., Waukegan, Ill.) into a cryogenic fluid, and then using sublimation to remove the water from the pellet. Once the reagent/trehalose mixture is aliquoted (drops) into the cryogenic fluid, it forms a spherical frozen pellet. These pellets are then placed in a lyophilizer where the frozen water molecules sublimate during the vacuum cycle. The result of this procedure is small, stable, non-flaking reagent pellets which can be dispensed into the appropriate packaging. Single dose aliquot pellets of reagents which contained RT, T7 and sugar were subjected to a wide range of temperatures to examine pellet stability. After being subject to a test temperature for 10 minutes, the pellets were then used for CT amplification. The results are graphed in FIG.

1

. The results show that the single dose reagent pellet remains stable even after to exposure to high temperatures for 10 minutes.

The extraordinary stability of enzymes dried in trehalose has been previously reported (Colaco et al., 1992, Bio/Technology, 10, 1007) which has renewed interest in research on long-term stabilization of proteins has become a topic of interest (Franks, 1994, Bio/Technology, 12, 253). The resulting pellets of the amplification reagent and enzyme reagents were tested by use in

C. Trachomatis

TMA/HPA reactions.

The prepared amplification pellets were placed in a tube to which was added 75 μl of a mixture of ARB and SDB (mixed in a 1:2 ratio) with positive control nucleic acid. This sample was then heated to 95° C. for 10 minutes and then cooled to 42° C. for 5 minutes. To this was added 25 μl of enzyme reagent, which had been reconstituted using standard Gen-Probe Inc. procedure. This mixture was allowed to incubate for one hour at 42° C. The reactions were then analyzed by the HPA procedure, as described above. The results of this test are reported as RLU in Table 2, and labeled AMP Pellets(+). As above, negative control reactions were run without nucleic acid (−).

The prepared enzyme pellets were tested by heating 100 μl of a combination of SDB with positive control nucleic acid, EDB, and the standard reconstituted amplification reagent (in a 2:1:1 ratio) at 95° C. for 10 minutes and then cooled to 42° C. for 5 minutes. The total volume of the reaction mix was added to the prepared enzyme pellet. After the pellet was dissolved, the reaction was heated to 42° C. for one hour and then subjected to HPA analysis as above. The results of this test are reported as RLU in Table 2 below, labeled Enzyme Pellet (+). Control reactions were prepared using standard Gen-Probe Inc. reagents following standard procedure. Data reported as RLU, standard

C. Trachomatis

TMA/HPA reaction.

TABLE 2

Single dose aliquot of pelleted ampliflcation and enzyme reagents

Amp Pellets

Amp Pellets

Enzyme

Enzyme

Control (+)

(+)

(−)

Pellets (+)

Pellets (−)

2,363,342

2,451,387

2,619

2,240,989

3,418

2,350,028

2,215,235

2,358

3,383,195

1,865

2,168,393

2,136,645

3,421

2,596,041

2,649

2,412,876

2,375,541

2,247

2,342,288

1,653

The data in Table 2 demonstrates that there was no significant difference when using the standard Gen-Probe Inc. reagents, or the dried, prepared, single dose amplification reagent pellet, or the enzyme reagent pellet. Thus the single dose aliquots of reagents are suitable for use with a single unified buffer for application to automation using a VIDAS system.

EXAMPLE 2

Automated Isothermal Amplification Using Thermolabile Enzymes

In order to automate the isothermal amplification assay reaction for use with clinical assay apparatus, such as a VIDAS instrument (bioMérieux Vitek, Inc.), a novel dual-chamber reaction vessel has been designed to implement the use of the unified buffer and single reaction aliquot reagent pellets described above in isothermal amplification assay of test samples which can be further used in combination with a stand alone processing station.

A) Dual Reaction Chambers

The use of two chambers will facilitate keeping separate the heat stable sample/amplification reagent (containing the specific primers and nucleotides) from the heat labile enzymatic components (i.e. RNA reverse transcriptase, RNA polymerase RNase H).

FIG. 3A

is a schematic representation of a disposable dual chamber reaction vessel 10 and the heating steps associated therewith to perform a TMA reaction in accordance with one possible embodiment of the invention. Chamber A contains the amplification mix, namely nucleotides, primers, MgCl

2

and other salts and buffer components. Chamber B contains the amplification enzyme that catalyzes the amplification reaction, e.g., T7 and/or RT. After addition of the targets (or patient sample) into chamber A, heat is applied to chamber A to denature the DNA nucleic acid targets and/or remove RNA secondary structure. The temperature of chamber A is then cooled down to allow primer annealing. Subsequently, the solution of chamber A is brought into contact with chamber B. Chambers A and B, now in fluid communication with each other, are then maintained at the optimum temperature for the amplification reaction, e.g., 42 degrees C. By spatially separating chamber A from chamber B, and applying the heat for denaturation to chamber A only, the thermolabile enzymes in chamber B are protected from inactivation during the denaturation step.

FIG. 3B

is a schematic representation of an alternative form of the invention in which two separate reaction chambers

12

and

14

are combined to form a dual chamber reaction vessel

10

. Like the embodiment of

FIG. 3A

, Chamber A is pre-loaded during a manufacturing step with an amplification mix, namely nucleotides, primers, MgCl

2

and other salts and buffer components. Chamber B is pre-loaded during manufacturing with the amplification enzyme that catalyzes the amplification reaction, e.g., T7 and/or RT. Fluid sample is then introduced into chamber A. The targets are heated for denaturation to 95° C. in chamber A. After cooling chamber A to 42° C., the solution in chamber A is brought into contact with the enzymes in chamber B to trigger the isothermal amplification reaction.

If the reaction vessel is designed such that, after having brought the contents of chambers A and B into contact, the amplification chamber does not allow any exchange of materials with the environment, a closed system amplification is realized that minimizes the risk of contaminating the amplification reaction with heterologous targets or amplification products from previous reactions.

FIG. 3C

is a schematic representation of two alternative dual chamber reaction vessels

10

and

10

′ that are snapped into place in a test strip

19

for processing with a solid phase receptacle and optical equipment in accordance with a preferred embodiment of the invention. In the embodiments of

FIG. 3

, a unidirectional flow system is provided. The sample is first introduced into chamber A for heating to the denaturation temperature. Chamber A contains the dried amplification reagent mix

16

. After cooling, the fluid is transferred to chamber B containing the dried enzyme

18

in the form of a pellet. Chamber B is maintained at 42° C. after the fluid sample is introduced into Chamber B. The amplification reaction takes place in Chamber B at the optimum reaction temperature (e.g., 42° C.). After the reaction is completed, the test strip

19

is then processed in a machine such as the VIDAS instrument available from bioMérieux Vitek, Inc., the assignee of the present invention. Persons of skill in the art are familiar with the VIDAS instrument.

The steps of heating and cooling of chamber A could be performed prior to the insertion of the dual chamber disposable reaction vessel

10

or

10

′ into the test strip

16

, or, alternatively, suitable heating elements could be placed adjacent to the left hand end

24

of the test strip

19

in order to provide the proper temperature control of the reaction chamber A. The stand alone amplification processing station of

FIGS. 4-14

, described below, incorporates suitable heating elements and control systems to provide the proper temperature control for the reaction vessel

10

.

FIG. 4

is a schematic representation of an alternative embodiment of a dual chamber reaction vessel

10

″ formed from two separate interlocking vessels

10

A and

10

B that are combined in a manner to permit a fluid sample in one chamber to flow to the other, with the combined dual chamber vessel

10

″ placed into a test strip

19

such as described above in FIG.

3

A. The fluid sample is introduced into chamber A, which contains the dried amplification reagent mix

16

. Vessel A is then heated off-line to 95 degrees C., then cooled to 42 degrees C. The two vessels A and B are brought together by means of a conventional snap fit between complementary locking surfaces on the tube projection

26

on chamber B and the recessed conduit

28

on chamber A. The mixing of the sample solution from chamber A with the enzyme from chamber B occurs since the two chambers are in fluid communication with each other, as indicated by the arrow

30

. The sample can then be amplified in the combined dual chamber disposable reaction vessel

10

″ off-line, or on-line by snapping the combined disposable vessel

10

″ into a modified VIDAS strip. The VIDAS instrument could perform the detection of the amplification reaction in known fashion.

B) Amplification Station

FIG. 5

is a perspective view of a stand-alone amplification processing system

200

for the test strips

19

having the dual chamber reaction vessels in accordance with a presently preferred form of the invention. The system

200

consists of two identical amplification stations

202

and

204

, a power supply module

206

, a control circuitry module

208

, a vacuum tank

210

and connectors

212

for the power supply module

206

. The tank

210

has hoses

320

and

324

for providing vacuum to amplification stations

202

and

204

and ultimately to a plurality of vacuum probes (one per strip) in the manner described above for facilitating transfer of fluid from the first chamber to the second chamber. The vacuum subsystem is described below in conjunction with FIG.

14

.

The amplification stations

202

and

204

each have a tray for receiving at least one of the strips and associated temperature control, vacuum and valve activation subsystems for heating the reaction wells of the strip to the proper temperatures, transferring fluid from the first chamber in the dual chamber reaction wells to the second chamber, and activating a valve, such as a thimble valve or preferably a ball valve, to open the fluid channel to allow the fluid to flow between the two chambers.

The stations

202

and

204

are designed as stand alone amplification stations for performing the amplification reaction in an automated manner after the patient or clinical sample has been added to the first chamber of the dual chamber reaction vessel described above. The processing of the strips after the reaction is completed with an SPR takes place in a separate machine, such as the VIDAS instrument. Specifically, after the strips have been placed in the stations

202

and

204

and the reaction run in the stations, the strips are removed from the stations

202

and

204

and placed into a VIDAS instrument for subsequent processing and analysis in known fashion.

The entire system

200

is under microprocessor control by an amplification system interface board (not shown in FIG.

5

). The control system is shown in block diagram form in FIG.

12

and will be described later.

Referring now to

FIG. 6

, one of the amplification stations

202

is shown in a perspective view. The other amplification station is of identical design and construction.

FIG. 7

is a perspective view of the front of the module of FIG.

6

.

Referring to these figures, the station includes a vacuum probe slide motor

222

and vacuum probes slide cam wheel

246

that operate to slide a set of vacuum probes

244

(shown in

FIG. 7

) for the thimble valves up and down relative to a vacuum probes slide

246

to open the thimble valves and apply vacuum so as to draw the fluid from the first chamber of the reaction vessel

10

to the second chamber. The vacuum probes

244

reciprocate within annular recesses provided in the vacuum probes slide

246

. Obviously, proper registry of the pin structure and vacuum probe

244

with corresponding structure in the test strip as installed on the tray needs to be observed.

The station includes side walls

228

and

230

that provide a frame for the station

202

. Tray controller board

229

is mounted between the side walls

228

and

230

. The electronics module for the station

202

is installed on the tray controller board

229

.

A set of tray thermal insulation covers

220

are part of a thermal subsystem and are provided to envelop a tray

240

(

FIG. 7

) that receives one or more of the test strips. The insulation covers

220

help maintain the temperature of the tray

240

at the proper temperatures. The thermal subsystem also includes a 42° C. Peltier heat sink

242

, a portion of which is positioned adjacent to the second chamber in the dual chamber reaction vessel in the test strip to maintain that chamber at the proper temperature for the enzymatic amplification reaction. A 95° C. heat sink

250

is provided for the front of the tray

240

for maintaining the first chamber of the reaction well in the test strip at the denaturation temperature.

FIG. 8

is another perspective view of the module of

FIG. 7

, showing the 95° C. heat sink

250

and a set of fins

252

. Note that the 95° C. heat sink

250

is positioned to the front of and slightly below the tray

240

. The 42° C. heat sink

242

is positioned behind the heat sink

250

.

FIG. 9

is a detailed perspective view of a portion of the tray

240

that holds the test strips (not shown) as seen from above. The tray

240

includes a front portion having a base

254

, a plurality of discontinuous raised parallel ridge structures

256

with recessed slots

258

for receiving the test strips. The base of the front

254

of the tray

240

is in contact with the 95° C. heat sink

250

. The side walls of the parallel raised ridges

256

at positions

256

A and

256

B are placed as close as possible to the first and second chambers of the reaction vessel

10

of

FIG. 3A

so as to reduce thermal resistance. The base of the rear of the tray

240

is in contact with a 42° C. Peltier heat sink, as best seen in FIG.

8

. The portion

256

B of the raised ridge for the rear of the tray is physically isolated from portion

256

A for the front of the tray, and portion

256

B is in contact with the 42° C. heat sink so as to keep the second chamber of the reaction vessel in the test strip at the proper temperature.

Still referring to

FIG. 9

, the vacuum probes

244

include a rubber gasket

260

. When the vacuum probes

244

are lowered by the vacuum probe motor

222

(

FIG. 6

) the gaskets

260

are positioned on the upper surface of the test strip surrounding the vacuum port in the dual chamber reaction vessel so as to make a tight seal and permit vacuum to be drawn on the second chamber.

FIG. 10

is an isolated perspective view of the test strip holder or tray

240

of

FIG. 9

, showing two test strips installed in the tray

240

. The tray

240

has a plurality of lanes or slots

241

receiving up to six test strips

19

for simultaneous processing.

FIG. 10

shows the heat sinks

242

and

250

for maintaining the respective portions of the tray

240

and ridges

256

at the proper temperature.

FIG. 11

is a detailed perspective view of the test strip holder or tray

240

as seen from below. The 95° C. Peltier heat sink which would be below front portion

254

has been removed in order to better illustrate the rear heat sink

242

beneath the rear portion of the tray

240

.

FIG. 12

is a block diagram of the electronics and control system of the amplification processing system of FIG.

5

. The control system is divided into two boards

310

and

311

, section A

310

at the top of the diagram devoted to amplification module or station

202

and the other board

311

(section B) devoted to the other module

204

. The two boards

310

and

311

are identical and only the top section

310

will be discussed. The two boards

310

and

311

are connected to an amplification station interface board

300

.

The interface board

300

communicates with a stand alone personal computer

304

via a high speed data bus

302

. The personal computer

304

is a conventional IBM compatible computer with hard disk drive, video monitor, etc. In a preferred embodiment, the stations

202

and

204

are under control by the interface board

300

.

The board

310

for station

202

controls the front tray

240

which is maintained at a temperature of 95° C. by two Peltier heat sink modules, a pair of fans and a temperature sensor incorporated into the front portion

254

of the tray

240

. The back of the tray is maintained at a temperature of 42° C. by two Peltier modules and a temperature sensor. The movement of the vacuum probes

244

is controlled by the probes motor

222

. Position sensors are provided to provide input signals to the tray controller board as to the position of the vacuum probes

244

. The tray controller board

310

includes a set of drivers

312

for the active and passive components of the system which receive data from the temperature and position sensors and issue commands to the active components, i.e., motors, fans, Peltier modules, etc. The drivers are responsive to commands from the amplification interface board

300

. The interface board also issues commands to the vacuum pump for the vacuum subsystem, as shown.

FIG. 13

is a diagram of the vacuum subsystem

320

for the amplification processing stations

202

and

204

of FIG.

5

. The subsystem includes a 1 liter plastic vacuum tank

210

which is connected via an inlet line

322

to a vacuum pump

323

for generating a vacuum in the tank

210

. A vacuum supply line

324

is provided for providing vacuum to a pair of pinch solenoid valves

224

(see

FIG. 6

) via supply lines

324

A and

324

B. These vacuum supply lines

324

A and

324

B supply vacuum to a manifold

226

distributing the vacuum to the vacuum probes

244

. Note the pointed tips

245

of the vacuum probes

244

for piercing the film or membrane

64

covering the strip

19

. The vacuum system

320

also includes a differential pressure transducer

321

for monitoring the presence of vacuum in the tank

210

. The transducer

321

supplies pressure signals to the interface board

300

of FIG.

12

.

FIG. 14

is a representative graph of the thermal cycle profile of the station of FIG.

5

. As indicated in line

400

, after an initial ramp up

402

in the temperature lasting less than a minute, a first temperature T

1

is reached (e.g., a denaturation temperature) which is maintained for a predetermined time period, such as 5-10 minutes, at which time a reaction occurs in the first chamber of the reaction vessel. Thereafter, a ramp down of temperature as indicated at

404

occurs and the temperature of the reaction solution in the first chamber of the reaction vessel

10

cools to temperature T

2

. After a designated amount of time after cooling to temperature T

2

, a fluid transfer occurs in which the solution in the first chamber is conveyed to the second chamber. Temperature T

2

is maintained for an appropriate amount of time for the reaction of interest, such as one hour. At time

406

, the temperature is raised rapidly to a temperature T

3

of 65° C. to stop the amplification reaction. For a TMA reaction, it is important that the ramp up time from time

406

to time

408

is brief, that is, less than 2 minutes and preferably less than one minute. Preferably, all the ramp up and ramp down of temperatures occur in less than a minute.

Other embodiments of reaction vessels and amplification station components are also envisioned, and such alternative embodiments are encompassed in the present disclosure.

EXAMPLE 3

Automated VIDAS Test for Non-amplified and Amplified Detection of

Mycobacterium tuberculosis

(M.tb)

Using the VIDAS instrument (bioMerieux Vitek, Inc.), modified to 42° C., we have developed an in-line simple rapid nucleic acid amplification and detection assay for the clinical laboratory for the detection of M.tb in test samples which can be completed in a short time. The entire assay is designed to take place on a single test strip, minimizing the potential for target or amplicon contamination. The amplification based assay is capable of detection of M.tb where the sample contains only 5 cells similar to the sensitivity achieved by the Gen-Probe commercial kit.

The amplification based assay utilizes isothermal transcription-mediated amplification (TMA) targeting unique sequences of rRNA, followed by hybridization and enzyme-linked fluorescent detection of nucleic acid probe (amplicon) in the VIDAS instrument.

The amplification/detection assay can detect approximately 1 fg of M.tb rRNA, or less than one M.tb organism per test, and is specific for all members of the M.tb complex. Specific probes for the detection of M.tb can be found in C. Mabilat, 1994, J. Clin. Microbiol. 32, 2707.

Standard smears for acid-fast bacilli are not always reliable as a diagnostic tool, and even when positive may be a mycobateria other than M.tb. Currently, standard methods for diagnosis of tuberculosis requires culturing the slow-growing bacteria, and may take up to 6 weeks or longer. During this time, the patient is usually isolated. Initial results are that this automated test matches or exceeds the clinical sensitivity of the culture method, and offers a highly sensitive method to rapidly (in less than three hours) detect M.tb in infected samples, thereby aiding rapid diagnosis, isolation and treatment.

A) Sample Preparation

A 450 μl volume of specimen is added to 50 μl of specimen dilution buffer in a lysing tube containing glass beads, sonicated for 15 minutes at room temperature to lyse organisms, heat inactivated for 15 minutes at 95° C. Where required, isothermal amplification was conducted as per a commercially available manual assay kit (Gen-Probe Inc.) following the kit instructions using standard kit reagents. However, similar assays can be conducted using the modified components as described in the Examples above.

B) Detection

In order for the automated detection assay to operate, the detection system requires hybridization of the target nucleic acid or amplicon to a specific capture nucleic acid bound to a solid support, (in the VIDAS system called a “solid phase receptacle” SPR® pipet-like devise), and to a labeled detection probe nucleic acid (for example where the label can be alkaline phosphatase, a chemiluminescent signal compound, or other reagent that will allow for specific detection of bound probe).

In an automated system such as the VIDAS, after several wash steps to remove unbound probe, the SPR® transfers the probe-target hybrid to an enzyme substrate, whereby the detectable signal is triggered from the bound probe and detected by the assay instrument. In one embodiment, the detection probe is conjugated to alkaline phosphatase, and once placed in contact with substrate of methyl umbelliferyl phosphate (MUMP), the substrate is converted into 4-methyl umbelliferone (4-MU) by the alkaline phosphatase. The 4-MU produces fluorescence which is measured and recorded by the standard VIDAS instrument as relative fluorescence units (RFU). When target nucleic acid is not present, no detection probe is bound, and no substrate is converted, thus no fluorescence is detected.

C) Analytical Sensitivity; Controls

Generally controls are prepared in a matrix of specimen dilution buffer with positive controls containing 5 fg of M.tb rRNA, or the equivalent rRNA of approximately 1 M. tb cell. Sensitivity of the automated probe assay can be determined by testing dilutions of lysed M. tb cells. The cell lysates can generally be prepared with a 1 μl loop of cells (the assumption being that there are approximately 1×10

9

colony forming units (CFU) per 1 μl loop-full, based upon previous titration and CFU experiments). Dilutions of the M.tb lysates can then be tested with the automated probe assay.

FIG. 20A

is a graph showing detection of M.tb amplicons according to the Gen-Probe kit.

FIG. 20B

is a graph showing detection of M.tb amplicons from the same reactions as in

FIG. 20A

by the VIDAS instrument.

FIG. 21

is a graph showing amplification and detection of M.tb nucleic acids on the modified VIDAS apparatus. Enzyme was used in liquid form and amplification was performed in-line with VIDAS assay instrument.

FIG. 22

is a graph showing amplification and detection of M.tb nucleic acids on the modified VIDAS apparatus using the binary/dual chamber disposable reaction vessel. The denaturation step was performed off-line of the VIDAS instrument, amplification and amplicon detection was performed in-line with VIDAS instrument.

EXAMPLE 4

Automated VIDAS Test for Amplified Detection of

Chlamydia trachomatis

(CT)

Using the VIDAS instrument (bioMérieux Vitek, Inc.), we have developed a simple, fully automated, highly specific assay for the rapid detection of

Chlamydia trachomatis

(CT) from test samples. The test utilizes isothermal TMA targeting unique sequences of the rRNA followed by hybridization and enzyme-linked fluorescence detection. The automated test specifically detects all the clinically important serovars of

Chlamydia trachomatis

(CT) from urogenital specimens in less than two hours. We obtained an analytical sensitivity of 0.5 fg of rRNA, or the equivalent of approximately {fraction (1/10)}

10

of an elementary body of

Chlamydia trachomatis

(CT). Agreement between the automated test and Gen-Probe's Amplified CT test for two-hundred seven (207) clinical endocervical swabs and urines showed complete agreement.

Chlamydia trachomatis

(CT) infection is the leading cause of sexually transmitted disease in the United States and Europe. It is currently estimated that about four million new CT infection occur each year in the United States.

Chlamydia trachomatis

(CT) is a small obligate intracellular parasite that causes infections in both females and males, adults and newborns. The greatest challenge to the control of CT infection is that as many as 75% of infected women and 50% of infected men are asymptomatic. This results in a large reservoir of unrecognized infected individuals who can transmit the CT infection. The rapid and simple detection of CT infection would greatly assist identification infected individuals.

A) Patient Specimens and Sample Preparation

Coded samples (n=207) were obtained from patients with symptoms consistent with CT infection. The cervical samples were collected with a Gen-Probe sample collection kit containing Gen-Probe transport medium; the urine samples were collected into standard urine collection devices. All samples were stored at 4° C. Cervical swabs were centrifuged at 425×g for 5 minutes to bring all liquid to the bottom of the tube. The swabs were then treated with 40 μl Gen-Probe Specimen Preparation Reagent and incubated at 60° C. for 10 minutes. 20 μl of the treated sample was then pipetted into 400 μl of sample dilution buffer (SDB).

Two ml of each urine sample was warmed to 37° C. for 10 minutes and microfuged at 12,000×g for 5 minutes. The supernatant was discarded and 300 μl of sample dilution buffer was added to each specimen. All 15 serovars of CT were used for inclusive samples, specimens were quantified and 20 μl of specimens containing 4×10

2

IFU/ml (inclusion forming unit per ml) of each serovar was added to 400 μl of SDB. A panel of exclusive urogenital micororganisms was obtained and quantified and 20 μl of 2×10

9

/ml microorganisms were pipeted into 400 μl of SDB. Positive control containing 0.5 fg rRNA or the equivalent of 0.1 CT elementary body was diluted in SDB.

B) Sample Amplification and VIDAS Detection

Samples were amplified using the TMA protocol, and rRNA targets were hybridized to oligomer conjugated to AMVE copolymer and an oligomer conjugated to alkaline phosphatase. See for example U.S. Pat. Nos. 5,489,653 and 5,510,084. As described above, the solid phase receptacle (SPR® pipet-like devise) carries the bound hybrids through successive wash steps and finally into the substrate 4-MUP. The alkaline phosphatase converts the substrate to fluorescent 4-MU, which is detected by the VIDAS assay machine and recorded as relative fluorescence units.

Table 2B below illustrates detection of CT by VIDAS automated assay following amplification as RFV (RFV=RFU−Background RFU) against concentration of CT rRNA. Dilutions of

C. trachomatis

purified rRNA from 0 to 200 molecules were amplified (n=3) and detected in the VIDAS automated probe assay. Detection limit is 20 molecules of purified rRNA.

TABLE 2B

CT Detection by VIDAS

rRNA Input Molecules

VIDAS RFV

0

1

2

121

20

3260

200

8487

C) Analytical Specificity and Results

Amplifications and detection were carried out in the presence of each of the following ATCC organisms with detections reported as RFV in Table 3 below.

TABLE 3

Exclusivity panel for CT

Bacillus subtilis

Branhamella

Candida albicans

Chlamydia

Chlamydia

33

catarrhalis

26

pneumoniae

psittaci

15

39

11

Escherichia coli

Klebsiella

Lactobacillus

Neisseria

Neisseria

11

pneumoniae

acidophilus

elongata

lactamica

13

27

44

18

Neisseria

Neisseria

Propionibacterium

Pseudomonas

Staphylococcus

meningitidis

-D

meningitidis

-Y

acnes

aeruginosa

aureus

61

52

14

13

13

Streptococcus

Streptococcus

Streptococcus

Yersinia

Chlamydia

agalactiae

bovis

pneumoniae

enterolitica

trachomatis

16

45

34

11

10673

Negative Control

12

Analytical specificity for Chlamydia serovars data reported as RFV is shown in Table 4 below.

TABLE 4

Inclusivity Panel for CT

Serovar A

Serovar B

Serovar Ba

Serovar C

Serovar D

5421

7247

9626

8066

10849

Serovar E

Serovar F

Serovar G

Serovar H

Serovar I

4608

9916

10082

7769

9733

Serovar J

Serovar K

Serovar L1

Serovar L2

Serovar L3

9209

2423

10786

1812

5883

Positive

Negative

Control 3775

Control 9

Table 5 below illustrates the results of clinical cervical swab specimen testing for CT comparing results from the Gen-Probe manual AMP-CT assay and the VIDAS automated probe assay.

TABLE 5

Amplified Clinical Cervical Specimen Detection of CT

Gen-Probe manual AMP-CT assay

VIDAS off-line

+

−

automated probe

+

35

0

assay

−

0

85

Table 6 below illustrates the results of clinical urine specimen testing comparing the results of manual AMP-CT assay and the VIDAS automated probe assay.

TABLE 6

Amplified Clinical Urine Specimen detection of CT

Gen-Probe manual AMP-CT assay

VIDAS off-line

+

−

automated probe

+

25

0

assay

−

0

62

Thus there was perfect agreement in assay results between the automated probe assay using the VIDAS instrument and the manual Gen-Probe AMP-CT assay.

EXAMPLE 5

Multiplex (Multiple Sequence) Nucleic Acid Detection

The value of diagnostic tests based on nucleic acid probes can be substantially increased through the detection of multiple different nucleic acid molecules, and the use of internal positive controls. An automated method has been devised for use with the VIDAS instrument (bioMérieux Vitek, Inc.) which can discretely detect at least two different nucleic acid sequences in one assay reaction, and is termed the Multiplex protocol. Thus a nucleic acid amplification procedure, or a processed test sample may be screened for more than one amplified nucleic acid molecule in the same assay. This method relies on the spatial separation of discrete nucleic acid probes which can specifically capture different target nucleic acid sequences (amplicons), on the SPR pipet-like devise of the VIDAS instrument. The SPR is a disposable pipet-like tip which enables fluid movements as well as acting as the solid support for affinity capture. The multiplex capture by SPR® is demonstrated using capture probes specific for

Chlamydia trachomatis

(CT) and

Neisseria gonorrhoeae

(NG).

FIG. 15

illustrates a schematic of the operation of the multiplex VIDAS detection. The SPR tips are coated in two distinct zones with oligonucleotide nucleic acid sequences which are used to specifically capture complementary nucleic acid sequences (amplicons) with their corresponding specific reporter probe or detector probe nucleic acids labeled with alkaline phosphatase (AKP). Following washes to remove unbound reporter probes, AKP localized to the SPR® bottom is detected with the fluorescent substrate 4-MUP. The AKP is stripped from the bottom of the SPR® with NaOH or other reagents which promote denaturation of nucleic acid hybrids or inacitvates AKP activity. The enzyme reaction well is emptied, washed, and re-filled with fresh 4-MUP. To confirm removal of AKP from the bottom of the SPR®, the new substrate is exposed to the bottom of the SPR® and any residual fluorescence is measured. Finally, AKP-reporter probe bound to the top of the SPR® is detected by immersing the SPR® in the 4-MUP, and representing the presence of the second amplicons.

FIG. 16

illustrates the production of SPR® with two distinct capture zones. The SPR® is inserted tip-first into a silicon plug, which are held in a rack. Differential pressure is used to uniformly draw a solution of a specific capture probe at about 1 μg/ml, conjugated to AMVE copolymer, into all SPR® at one time. The amount of fluid drawn into each SPR, and thus the size of the zone, is controlled by regulating the amount of pressure in the system. Attachment of the conjugate to the SPR® surface is achieved by passive adsorption for several hours at room temperature. After washing, and drying, the SPRos are capped with a small adhesive disc and inserted into new racks in a tip-down orientation. The lower portion of the SPR® is then similarly coated with a second capture probe conjugate. SPR® are stable when stored dry at 4° C.

FIG. 17

illustrates a preferred embodiment of the VIDAS apparatus strip configuration for Multiplex detection. The strip can be pre-filled with 200 μl of AKP-probe mix (about 1×10

12

molecules of each probe) in hybridization buffer in well X1, 600 μl of wash buffer in wells X3, X4, X5, 600 μl of stripping reagent in wells X6 and X7, and 400 μl of AKP substrate in X8 and sealed with foil. A foil-sealed optical cuvette (XA) containing 300 μl of 4-MUP is snapped into the strip, and the strips are inserted into the VIDAS instrument at 37° C. The Multiplex VIDAS protocol is then executed using SPR®s coated with two capture probes in distinct zones.

The VIDAS Multiplex protocol can involve many steps. For example the validation test protocol contained 13 basic steps as follows:

1. Transfer of 203 μl target from X0 to AKP-probes in X1,

2. Hybridize and capture to the entire SPR®,

3. Wash SPR® (316 μl) twice with PBS/Tween (X3, X4),

4. 4-MUP to SPR® bottom (89.6 μl) in XA for 5.3 minutes then read signal,

5. 4-MUP to SPR® bottom (89.6 μl) in XA for 14.8 minutes then read signal,

6. Transfer used substrate from XA to X2 (5×67.1 μl),

7. Strip AKP from SPR® bottom (112.6 μl) with NaOH (X7),

8. Wash XA with fresh NaOH (3×112.6 μl; X6 to XA to X6),

9. Wash XA with PBS/Tween (3×112.6 μl; X5 to XA to X5),

10. Transfer fresh 4-MUP from X8 to XA (6×48 μl),

11. 4-MUP to SPRO® bottom (89.6 μl) in XA for 10.7 minutes then read signal,

12. 4-MUP to SPR® top (294 μl) in XA for 5.5 minutes then read signal,

13. 4-MUP to SPR® top (294 μl) in XA for 15 minutes then read signal.

Hybridization, substrate, wash and stripping steps can all involve multiple cycles of pipeting the respective solution into the SPR®, holding the solution for a defined period of time, and pipeting the solution out of the SPR®. Hold times for hybridization, substrate and washing or stripping are 3.0, 0.5 and 0.17 minutes respectively. The fluorescence signal is detected by the apparatus. Total assay time for the research protocol was about 1.75 hours but can be reduced to about 75 minutes.

FIG. 18

illustrates and graphs the results of verification of the VIDAS Multiplex protocol executed as described above, except the SPR® was homogeneously coated with only a single capture probe for

Neisseria gonorrhoeae

(NG). The number of NG oligonucleotide targets in the test sample was varied from 0, 1×10

10

, or 1×10

11

molecules in the test sample. The data shown are averages of replicate samples. The graph as illustrated is divided into two parts; the left and right halves show the results of two fluorescent measurements from the lower and the upper zones of the SPR®, respectively. The measurements taken from the bottom zone after stripping the lower area of bound nucleic acid, and exposure for about 11 minutes in fresh 4-MUP substrate was approximately 46 RFU for all samples tested, and was equivalent to background fluorescence measured. This measurement is shown by the 0 time point in the center of the graph. Thus the graph illustrates two sequential sets of measurements of fluorescence from a single SPR®, the first set of measurements being taken from the bottom half of the SPR® (left half of the graph), and a second set of measurements taken from the top of the SPR® (the right of the graph). This experiment validates that the multiplex protocol and zone coated SPR prcedure yield essentially idnetical results. As indicated by the fluoresecense intensities in the left and right hand parts of the graph, from the lower and upper portions of the SPR.

FIG. 19

illustrates Multiplex detection of CT and NG oligonucleotide targets at different input amounts.

FIG. 19A

is a graph showing the results when 1×10

12

CT targets were mixed with 0, 1×10

9

, 1×10

10

, 1×10

11

, or 1×10

12

, NG targets, and detected with the VIDAS instrument using the Multiplex protocol and SPR®s coated with CT capture probes on the bottom zone of the SPR®, and NG capture probes on the top zone of the SPR®.

FIG. 19B

illustrates the results when 1×10

12

NG targets was mixed with 0, 1×10

9

, 1×10

10

, 1×10

11

, or 1×

12

, CT targets, and detected with the VIDAS instrument using the Multiplex protocol and SPR®s coated with CT capture probes on the bottom zone of the SPR®, and NG capture probes on the top zone of the SPR®. The data is graphed as above where the graph illustrates two sequential sets of measurements of fluorescence from a single SPR®, the first set of measurements being taken from the bottom half of the SPR® (left half of the graph), Stripped and verified (the center of the graph) and a second set of measurements taken from the top of the SPR® (the right of the graph) with verification of stripping of the SPR in the center of the graph. Importantly, this experiment shows that the two zones of the SPR act independently in the multiplex protocol, since high fluorescence signals from one zone do not interfere with signals produced for the second zone. This is regardless of whether these latter signals are high (1×10

12

) or low (1×10

9

) or negative.

Table 7 below summarizes the data obtained by Multiplex VIDAS detection of CT and NG in a sample at various target levels, reported in RFUs.

TABLE 7

Detection of CT and NG targets in sample

RFUs

A

none

B

1 × 10

9

1 × 10

10

1 × 10

11

1 × 10

12

1 × 10

13

none

C

43

D

/40

E

43/116

46/693

62/7116

174/11817

273/12136

1 × 10

9

189/41

246/118

169/773

220/5750

422/12522

399/11401

1 × 10

10

1736/41

2258/125

1937/734

1931/6639

2128/12390

2371/11180

1 × 10

11

10339/48

9815/145

9858/760

9369/4571

9784/11825

10252/10312

1 × 10

12

12149/49

13520/148

12940/796

13593/4397

11239/11786

10158/9900

1 × 10

13

11545/57

11713/121

10804/815

12805/5404

12305/12326

11416/10490

A

Data is reported in RFUs, after ˜5 minute exposure of 4-MUP to bound AKP-probe

B

Columns are data for that number of NG targets in sample

C

Rows are the data for that number of CT targets in sample

D

The first value reported is RFU detected from the CT assay portion

E

The second value reported is RFU detected from the NG assay portion

Thus the Multiplex VIDAS protocol is clearly operative and enables the rapid and discrete detection of more than one different nucleic acid in a sample. This protocol, and the SPR® coating can be manipulated in many formats to present coating zones of different surface area with different sized gaps between two or more detection zones. The SPR® can be coated with nucleic acids which are designed to capture different regions of the same nucleic acid sequence to detect, for example, truncated gene expression, different alleles or alternatively spliced genes. The SPR® can be coated to capture amplicons from internal control nucleic acid molecules which can be used to detect and confirm successful nucleic acid amplification reactions. Thus the VIDAS Multiplex protocol is a flexible method for detection of more than one nucleic acid sequence in the same sample, in a single assay, with or without amplification.

EXAMPLE 6

Internal Control Sequence and Method

The construction of internal control sequences composed of functional building blocks of sequences chosen by random generation of nucleic acid sequences for use as amplification reaction internal positive controls ideally requires that the control sequences be specifically designed to be used for the various nucleic acid amplification protocols including but not limited to PCR, LCR, TMA, NASBA, and SDA. The internal control nucleic acid sequence, in combination with the appropriate sequence specific oligonucleotide primers or promoter-primers will generate a positive amplification signal if the amplification reaction was successfully completed.

Ideally, the internal control nucleic acid is useful regardless of the nucleic acid sequences present in the target organism, the host organism, or nucleic acids present in the normal flora or in the environment. Generally, the internal control sequences should not be substantially similar to any nucleic acid sequences present in a clinical setting, including human, pathogenic organisms, normal flora organisms, or environmental organisms which could interfere with the amplification and detection of the internal control sequences.

The internal control sequences of the instant invention are comprised of functional blocks of sequences chosen from a list of randomly generated nucleic acid sequences. The functional blocks are segments which provide for a special property needed to allow for amplification, capture, and detection of the amplification product. For example, in a TMA reaction, the internal control sequences are most useful when the functional blocks meet certain functional requirements of the amplification protocol, such as: a) a primer binding site on the anti-sense strand; b) a capture site; c) a detector probe binding site; d) a T7-promoter containing primer binding site on the sense strand. Each of these functional elements has its own particular constraints, such as length, %G-C content, Tm, lack of homology to known sequences, and absence of secondary structural features (i.e. free from dimer formation or hairpin structures) which can be used to select the appropriate sequence. Thus randomly generated functional blocks of sequences can be screened for the desired functional properties before use in constructing internal control sequences.

In order to construct internal control sequences having the desired properties comprising a specified number of functional blocks and satisfying the desired constraints within each block, a random sequence generator was used to generate strings of numbers; each number being limited to the range from 0.000 to 4.000. The length of the strings is flexible and chosen based upon the desired lengths of the functional blocks.

Each number in the string (i.e. n

1

, n

2

, n

3

, n

4

. . . nx where x is the length of the string) was then assigned a corresponding nucleotide as follows: guanosine (G) if 0<n≦1; adenosine (A) if 1<n≦2; thymidine (T) if 2<n≦3; and cytosine (C) if 3<n≦4. A large collection of such strings was produced and screened for those meeting the sequence and structural requirements of each functional block.

FIG. 23

illustrates the results generated by the method described showing a collection of strings of nucleic acid sequences and screening for specific functional parameters. The internal control sequence can include DNA, RNA, modified oligonucleotides, or any combination of nucleic acids, such that the illustrated sequences using DNA nomenclature can be readily adapted as desired to the appropriate nucleic acid.

Potential internal control (IC) sequences were then constructed by assembling the functional blocks (selected at random) in the proper order. Finally, the assembled internal control sequences were then examined to insure that overall sequence and structural constraints were maintained. For example, in a TMA reaction, the internal control sequence should not have significant base-pairing potential between the two primer binding sites or form stable 3′ dimer structures. Those internal control sequences which pass thorough these layers of screening were then physically produced using overlapping oligonucleotides and tested for performance in actual amplification/detection assays.

Although any one functional block may have some homology to sequences present in a clinical setting (a perfect match of a 21 nucleotide block is expected at a random frequency of 1 in 4e

21

sequences or about 4×10

12

; generated sequences were screened against the GenBank data base) it is highly unlikely that all functional blocks will be found to have substantial homology. Since the internal control nucleic acid sequences are constructed of a group of functional blocks placed in tandem, the chance possibility that a natural nucleic acid sequence will have an identical string of nucleic acid sequence blocks in the same tandem organization is remote.

Two specific internal control sequences have been constructed using the method described above. Random Internal Control 1 (RIC1) is shown in

FIG. 24

with the possible oligonucleotide primers/probes for amplification and detection of the control sequence.

FIG. 25

shows an analysis of the possible secondary structure of the RIC1 molecule. RIC1 was constructed using randomly generated strings ran16, ran19, ran21 and ran33. The functional blocks requiring primer binding were met by ran16 and ran19, while the capture site was satisfied by ran21 and the detector probe binding site was met by ran33. The choice of a capture probe or detection probe sequence designation can be interchanged, as long as the appropriate linker molecule is attached to the appropriate probe, wherein a reporter probe oligonucleotide is linked to a means for generating a detectable signal, and the capture probe oligonucleotide is linked to a means for adhering the capture probe to an appropriate support. The probes and oligos are described with the understanding that in the case of double stranded DNA, the complementary strand can be the target or as appropriate can be converted for use as the strand for detection. Thus in the appropriate circumstance, one of ordinary skill in the art will be able to modify the sequences as disclosed to generate alternative probes and primers which are suitable for use in an equivalent fashion as described herein.

Random Internal Control 2 (RIC2) is shown in

FIG. 26

with the possible oligonucleotide primers/probes for amplification and detection of the control sequence.

FIG. 27

shows an analysis of the possible secondary structure of the RIC2 sequence. Similarly to RIC1, RIC2 was constructed using randomly generated strings ran27, ran32, ran39 and ran51. Thus, illustrating that it is also possible that the functional blocks requiring primer binding, capture probe binding, detector probe binding can be met by alternative random sequences generated by the method described above.

FIG. 28

illustrates results from detection of RIC1 DNA, where the ran21 was the capture probe and ran33 was an enzyme-linked detector-probe, and shows that detection occurs under standard assay conditions with expected fluorescence intensities.

FIG. 29

shows that RIC1 RNA, amplified by TMA and detected on a VIDAS instrument (bioMérieux Vitek, Inc.) using the enzyme-linked detection system, has a limit of sensitivity of about 1000 molecules of RIC1 RNA (without optimization of conditions). Similar analysis of RIC2 sequences was performed and found to be similar to RIC1. It is significant that the amplification and detection system of the internal control functioned effectively under the conditions optimized for the selected target.

As an alternative approach for Multiplex detection using internal controls (IC), SPR®s can be homogeneously coated with a mixture of different capture nucleic acid sequences in a single, whole-SPR® zone. For example, two capture nucleic acid sequences can be combined in one zone, one specific for a target test sequence, and one specific for an internal control sequence. Target amplicons, if present, and internal control amplicons are simultaneously hybridized to the SPR®, amplicons. In the presence of labeled probe nucleic acid sequences specific for the target test nucleic acid sequence. Following washing, a first signal read is done to so that the presence or absence of label on the SPR® is determined to ascertain the presence or absence of the test target. A second hybridization is then done (sequential hybridization) to the SPR® using a labeled specific for the internal control. The SPR® is washed to remove excess unbound detection probe, and the second label is measured to indicate the presence or absence of the internal control. If the first signal is negative, a positive signal from the IC second read confirms the functionality of the amplification/detection system. In this case, one can conclude that the test target nucleic acid sequence was truly absent or below detection (true negative). If the first signal is positive, this alone is enough to confirm functionality of the amplification and detection system, and the second signal is immaterial (positive result). If the first and second label are the same, an additive signal will result from the positive first read and the positive second IC read. If both the first signal is negative and the second IC signal is also negative, then the amplification/detection functionality failed, which could be due to for example, sample interference or mechanical failure. In this case the test result is reported invalid (false negative) and re-testing is recommended. If the labels used are different then neither sequential hybridization or sequential detection steps would be necessary.

There is great interest in the use of internal controls, the underlying rational being that “ . . . if the sample will not support the amplification of the internal control, it is unlikely to support the amplification of the target nucleic acid sequence.” (NCCLS Document MM3-A, Molecular Diagnostic Methods for Infectious Diseases; Approved Guideline, p. 55, March 1995).

Using a sequential hybridization approach with multiple detector probes, it has been possible to design protocols which allow for the discrete detection of first signal read (ie. pure CT signal) and an additive “mixed” second signal read (ie. additive CT and IC signals; see Table 7A below). This protocol will not need stripping. For example, Table 7A shows the results when different mixtures of CT and IC_synthetic targets were first captured with homogeneously coated SPR®s (CT and IC utilizing same capture probes) and first hybridized with the CT detector probe. After the first read, hybridization was performed with the IC detector probe, followed by a second read (same substrate).

This type of protocol can also be used for a combined GC/CT/internal control assay, if a screening approach is allowed (no discrimination between GC and/or CT positives during the first read). GC and CT specific signals have to be resolved by running the CT and GC specific assays on screen positive samples (5-10% of cases, depending on prevalence) SPR®s would be coated homogeneously with 3 capture probes (CT/GC/internal control). Alternatively, the IC could share a capture probe with either CT or GC.

TABLE 7A

Homogeneous Coated SPR ® Detection of multiple signals

Target

CT 1

st

Read

IC 2

nd

Read

Bkg. RFU

10

10

CT

7077

8608

58

10

10

IC

58

4110

56

10

10

IC/CT

5594

8273

57

10

10

IC/CT

5712

8317

57

no target

66

89

57

Thus internal control sequences described above are useful for application with VIDAS apparatus with coated SPR® and the use of the Multiplex system to provide for combined assay detection of a nucleic acid and monitoring control for successful reaction.

EXAMPLE 7

Internal Control Sequence

Refinement of the randomly generated internal control sequences will allow for optimization of such internal control sequences for specific assay systems. Following the methods described above, internal control nucleic acid sequences have been designed and validated for use in various amplification and detection systems including an internal control for a

Chlamydia trachomatis

(CT) assay identified as CRIC-2; for a

Neisseria gonorrhoeae

(NG) assay identified as GRIC; and for

Mycobacterium tuberculosis

(MT) identified as MRIC. An internal control was generated for HIV assays identified as HRIC, wherein both the capture probe sequence and reporter probe sequence were derived from random sequence. The sequence of the internal control, and the corresponding target sequence are shown in FIG.

30

. In each of these internal control sequences, the Random Sequence Probe #1082 can be used as the reporter probe, when suitably conjugated to a reporter molecule as described previously. In the HIV internal control, a capture oligonucleotide Random Sequence Probe #1081 has been designed for use in the capture of the control sequence, for improved quantitation by elimination of competition between the target amplicons and IC amplicons for a common capture probe.

87 base pairs

nucleic acid

both

unknown

other nucleic acid

/desc = “random internal control 1”

misc_feature

4..24

/note= “RAN16 TMA primer”

misc_feature

46..66

/note= “RAN21 AMVE-probe, amino
link at 5′ end”

misc_feature

25..45

/note= “RAN33 AKP-probe, amino link
at the 5′ end”

misc_feature

1..87

/note= “RIC1 target”

1
GGGAGCGAAT GTTAGGGCAC ACTCATGGGT GAGCAAGTCT TTCTGTAAGG GCTGATGTCA 60
GGCGTATTGA CAAGCATGAC GACCAGA 87

48 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “Random internal control 1
detection oligo”

2
CAATACGCCT GACATCAGCC CTTACAGAAA GACTTGCTCA CCCATGAG 48

56 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “RIC1 top oligo”

misc_feature

3..22

/note= “T3 Promoter”

3
GCAATTAACC CTCACTAAAG GGAGCGAATG TTAGGGCACA TCATGGGTGA GCAGTC 56

64 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “RIC1 bottom oligo”

4
TCTGGTCGTC ATGCTTGTCA ATACGCCTGA CATCAGCCCT TACAGAAAGA CTTGCTCACC 60
CATG 64

48 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “T7 promoter/RAN19 primer”

misc_feature

28..48

/note= “RAN19 primer”

5
AATTTAATAC GACTCACTAT AGGGAGATCT GGTCGTCATG CTTGTCAA 48

96 base pairs

nucleic acid

both

unknown

other nucleic acid

/desc = “Random Internal Control 2”

misc_feature

1..96

/note= “RIC2 target”

misc_feature

1..26

/note= “RAN51 TMA primer”

misc_feature

28..48

/note= “RAN27 AMVE-probe, amino
link at 5′ end”

misc_feature

49..69

/note= “RAN32 AKP-probe, amino link
at 5′ end”

6
CAGTAGAGGT AGGGGCTGCT AGGAGTATAA CAGAAGCCAG TGTACGGAAC GACTCAGCAC 60
GGCGAATACT TTGCTACCAG ACCTAGAGGA GTGCGT 96

47 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “RIC2 detection oligo”

7
AAGTATTCGC CGTGCTGAGT CGTTCCGTAC ACTGGCTTCT GTTATAC 47

67 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “RIC2 Top oligo”

misc_feature

3..22

/note= “T3 promoter”

8
GCAATTAACC CTCACTAAAG GGCAGTAGAG GTAGGGGCTG CTAGGAGTAT AACAGAAGCC 60
AGTGTAC 67

66 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “RIC2 bottom oligo”

9
ACGCACTCCT CTAGGTCTGG TAGCAAAGTA TTCGCCGTGC TGAGTCGTTC CGTACACTGG 60
CTTCTG 66

52 base pairs

nucleic acid

single

linear

other nucleic acid

/desc = “T7 promoter/RAN39 primer”

misc_feature

28..52

/note= “RAN39 primer”

10
AATTTAATAC GACTCACTAT AGGGAGAACG CACTCCTCTA GGTCTGGTAG CA 52

111 base pairs

nucleic acid

both

unknown

other nucleic acid

/desc = “CT internal control target”

11
CGGAGUAAGU UAAGCACGCG GACGAUUGGA AGAGUCCGUA GAGCGAUGAG AACGGUUAGU 60
AGGCAAAUCC GCUAACAUAA GAUCAGGUCG CGAUCAAGGG GAAUCUUCGG G 111

111 base pairs

nucleic acid

both

unknown

other nucleic acid

/desc = “CT internal control”

misc_feature

34..54

/note= “Random Seq Probe #1082
(reporter)”

12
CGGAGUAAGU UAAGCACGCG GACGAUUGGA AGAAUGGGUG AGCAAGUCUU UCUGGUUAGU 60
AGGCAAAUCC GCUAACAUAA GAUCAGGUCG CGAUCAAGGG GAAUCUUCGG G 111

110 base pairs

nucleic acid

both

unknown

other nucleic acid

/desc = “NG internal control target”

13
GGCGAGUGGC GAACGGGUGA GUAACAUAUC GGAACGUACC GGGUAGCGGG GGAUAACUGA 60
UCGAAAGAUC AGCUAAUACC GCAUACGUCU UGAGAGGGAA AGCAGGGGAC 110

110 base pairs

nucleic acid

both

unknown

other nucleic acid

/desc = “NG internal control”

misc_feature

29..49

/note= “Random Seq Probe #1082
(Reporter)”

14
GGCGAGUGGC GAACGGGUGA GUAACAUAAU GGGUGAGCAA GUCUUUCUGG GGAUAACUGA 60
UCGAAAGAUC AGCUAAUACC GCAUACGUCU UGAGAGGGAA AGCAGGGGAC 110

125 base pairs

nucleic acid

double

unknown

other nucleic acid

/desc = “MT internal control target”

15
GGGAUAAGCC UGGGAAACUG GGUCUAAUAC CGGAUAGGAC CACGGGAUGC AUGUCUUGUG 60
GUGGAAAGCG CUUUAGCGGU GUGGGAUGAC CCCGCGGCCU AUCAGCUUGU UGGUGGGGUG 120
ACGGC 125

96 base pairs

nucleic acid

double

unknown

other nucleic acid

/desc = “MT internal control”

misc_feature

54..74

/note= “Random Seq Probe #1082
(Reporter)”

16
GGGAUAAGCC UGGGAAACUG GGUCUAAUAC CGGAUAGGAC CACGGGAUGC AUGAUGGGUG 60
AGCAAGUCUU UCUGAGCTTG TTGGTGGGGT GACGGC 96

109 base pairs

nucleic acid

double

unknown

other nucleic acid

/desc = “HIV internal control
target”

17
ACAGCAUACA AAUGGCAGUA UUCAUCCACA AUUUUAAAAG AAAAGGGGGG AUUGGGGGGU 60
ACAGUGCAGG GGAAAGAAUA GUAGACAUAA UAGCAACAGA CAUACAAAC 109

90 base pairs

nucleic acid

double

unknown

other nucleic acid

/desc = “HIV internal control”

misc_feature

20..40

/note= “Random Sequence Probe #1082
(Reporter)”

misc_feature

41..61

/note= “Random Sequence Probe #1081
(Capture)”

18
ACAGCAUACA AAUGGCAGUA UGGGUGAGCA AGUCUUUCUG UAAGGGCUGA UGUCAGGCGU 60
AGUAGACAUA AUAGCAACAG ACAUACAAAC 90

Number	Name	Date	Kind
4457916	Hayashi et al.	Jul 1984	A
4581333	Kourilskey et al.	Apr 1986	A
4762857	Bollin, Jr. et al.	Aug 1988	A
4891319	Roser et al.	Jan 1990	A
5026566	Roser et al.	Jun 1991	A
5098893	Franks et al.	Mar 1992	A
5122284	Braynin et al.	Jun 1992	A
5217862	Barns et al.	Jun 1993	A
5229297	Schnipelsky	Jul 1993	A
5432271	Barns et al.	Jul 1995	A
5437990	Burg et al.	Aug 1995	A
5457027	Nadeau et al.	Oct 1995	A
5489653	Charles et al.	Feb 1996	A
5498392	Wilding et al.	Mar 1996	A
5510084	Cros et al.	Apr 1996	A
5521300	Shah et al.	May 1996	A
5541308	Hogan et al.	Jul 1996	A
5554516	Kacian et al.	Sep 1996	A
5587128	Wilding et al.	Dec 1996	A
5589585	Mabilat et al.	Dec 1996	A
5645801	Bouma et al.	Jul 1997	A
5693468	Hogan et al.	Dec 1997	A
5703217	Mabilat et al.	Dec 1997	A
5710029	Ryder et al.	Jan 1998	A
5712385	McDonough et al.	Jan 1998	A
5747252	Yang et al.	May 1998	A
5766849	McDonough et al.	Jun 1998	A
5780273	Burg	Jul 1998	A
5849901	Mabilat et al.	Dec 1998	A
5856088	McDonough et al.	Jan 1999	A
5871975	Kacian et al.	Feb 1999	A
5908744	McAllister et al.	Jun 1999	A
5994066	Bergeron	Nov 1999	A
6136529	Hammond	Oct 2000	A

Number	Date	Country
195 03 685	Jan 1996	DE
195 03 685	Jan 1996	DE
195 03 685	Aug 1996	DE
0 622 464	Nov 1994	EP
0 623 682	Nov 1994	EP
0 726 310	Feb 1996	EP
0428693	Jul 1996	EP
0732408	Sep 1996	EP
WO 87 00196	Jan 1987	WO
WO 89 00012	Jan 1989	WO
WO 89 00290	Jan 1989	WO
WO 89 06542	Jul 1989	WO
WO 93 00806	Jan 1993	WO
WO 93 21346	Oct 1993	WO
WO 93 33488	Dec 1995	WO

	Number	Date	Country
Parent	08/850171	May 1997	US
Child	09/065914		US

Nucleic acid assays

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

US Classifications

Field of Search

US

International Classifications

Abstract

Description

Claims

Parent Case Info

US Referenced Citations (34)

Foreign Referenced Citations (15)

Non-Patent Literature Citations (10)

Continuation in Parts (1)

Entry
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P. Allibert, et al. (1992) “Automated Detection of Nucleic Acid Sequences of HPV 16, 18 and 6/11,” RBM, 14.3, p. 152-155.
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English Abstract for DE 195 03 685 A1.