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L uminex
Luminex Molecular Diagnostics xTAGO RVP FAST Traditional 510(k) Submission 510(k) SUMMARY This summary of 510(k) safety and effectiveness information is being submitted in accordance with the requirements of 21 CFR 807.92. 510(k) Number: k103776 Submission Type: Traditional 510(k), New Device Measurand: A panel of viruses including: Influenza A, Influenza Asubtype Hi, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus, Human Metapneumovirus, Rhinovirus, and Adenovirus Type of Test: Qualitative nucleic acid multiplex test Applicant: Luminex Molecular Diagnostics Inc., Toronto, Ontario, Canada Proprietary and Established Names: xTAGO Respiratory Viral Panel FAST (RVP FAST) Regulatory Information: Product Code Class 11 0CC, OEM, OEP
IClassification
Regulation Section 21 CFR 866.3980 Respiratory viral panel multiplex nucleic acid assay
Review Panel Microbiology (83)
Intended Use: The xTAGO Respiratory Viral Panel Fast (RVP FAST) is a qualitative nucleic acid multiplex test intended for the simultaneous detection and identification of multiple respiratory virus nucleic acids in nasopharyngeal swabs from individuals suspected of respiratory tract infections. The following virus types and subtypes are identified using RVP FAST: Influenza A, Influenza A subtype Hi, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus, Human Metapneumnovirus, Rhinovirus, and Adenovirus. The detection and identification of specific viral nucleic acids from individuals exhibiting signs and symptoms of respiratory infection aids in the diagnosis of respiratory viral infection if used in conjunction with other clinical and epidemiological information. Negative results do not preclude respiratory viral infection and should not be used as the sole basis for diagnosis, treatment or other management decisions. Positive results do not rule out bacterial infection or co-infection with other organisms. The agent detected may not be the definite cause of disease. The use of additional laboratory testing (e.g. bacterial and viral culture, immunofluorescence, and radiography) and clinical presentation must be taken into consideration in order to obtain the final diagnosis of respiratory infection.
K103776 xTAG RVP FAST 510(k) Summary
L umiex
xTAGO RVP FAST Traditional 510(k) Submission
Due to the genetic similarity between human Rhinovirus and Enterovirus, the RVP FAST primers for the detection of rhinovirus cross react with enterovirus. A rhinovirus reactive result should be confirmed by an alternate method (e.g. cell culture). Performance characteristics for Influenza A Virus were established when Influenza A/H-3 and A/Hi were the predominant Influenza A viruses in circulation. When other Influenza A viruses are emerging, performance characteristics may vary. If infection with a novel Influenza A virus is suspected based on current clinical and epidemiological screening criteria recommended by public health authorities, specimens should be collected with appropriate infection control precautions for novel virulent Influenza viruses and sent to a state or local health department for testing. Viral culture should not be attempted in these cases unless a BSL 3+ facility is available to receive and culture specimens. Indlication(s) for use: Same as intended use. Special instrument requirements: Luminex 100 or 200 instrument with ISor xPONENT software Device Description: RVP FAST is a PCR-based system for detecting the presence / absence of viral DNA / RNA in clinical specimens. The oligonucleotidle primer / probe components of the RVP FAST have been designed to specifically target unique regions in the RNA / DNA of each molecular species listed in the intended use. Amplified products are then sorted and analyzed on the Luminex 100 or 200 instrument, which generates signals based on the acquisition of spectrofluorometric data. The raw signals are median fluorescence intensities (MFI) which are acquired in a Luminex Output.csv file that is subsequently analyzed by the xTAG Data Analysis Software (TOAS RVP FAST) to establish the presence or absence of all viral types / subtypes for which a Luminex microsphere population has been dedicated. The RVP FAST reagent components are described below. xTAG xTAG xTAG xTAG xTAG xTAG xTAG xTAG xTAG xTAG xTAG RVP Fast Primer Mix RVP Fast Bead Mix OneStep Enzyme Mix OneStep Buffer, 5X dNTP Mix RNase-Free Water Reporter Buffer Streptavidin, R-Phycoerythrin G15 M52 Bacteriophage Lambda DNA TDAS RVP FAST (US) software
K(103776 xTAG RVP FAST 510(k) Summary
Luminex Molecular Diagnostics Substantial Equivalence Information:
xTAG® RVP FAST Traditional 510(k) Submission
a. Predicate device name(s): xTAG Respiratory Viral Panel b. Predicate 510(k) number(s): k063765, k081843, k091667 c. Comparison with predicate: The following tables compare the xTAG Respiratory Viral Panel FAST with the xTAG Respiratory Viral Panel (k063765, k081843, k091667). The first table shows similarities between the new device and the predicate, while the second table shows the differences. Table 1: Similarities between New Device and Predicate
Item New Device (Ref. No. to be determined) xTAG RVP FAST Luminex Molecular Diagnostics Nasopharyngeal swabs Multiplex end point RT-PCR Multiplex bead-based universal array
on Luminex 100/200 instrument
Manufacturer Specimen Types Amplification Method Test Format
__________________sorting
Predicate (k063765, k081483, k091667) xTAG RVP Luminex Molecular Diagnostics Nasopharyngeal swabs Multiplex end point RT-PCR Multiplex bead-based universal array
sorting on Luminexl100/200 instrument
Detection Method Quality Control
Results Instrument
Fluorescence based Internal Control (E.coli phage M52), Run Control (bacteriophage Lambda DNA), rotating analyte control and negative controls Qualitative LX100 or LX200
Fluorescence based Internal Control (E.coli phage M52) and Run Control (bacteriophage Lambda DNA), rotating analyte control and negative controls Qualitative LX100 or LX200
Table 2: Differences between New Device and Predicate
Item New Device (k103776) xTAG RVP FAST The xTAGO Respiratory Viral Panel Fast (RVP FAST) is a qualitative nucleic acid multiplex test intended for the simultaneous detection and identification of multiple respiratory virus nucleic acids in nasopharyngeal swabs from individuals suspected of respiratory tract infections. The following virus types and subtypes are identified using RVP FAST: Influenza A, Influenza A subtype Hi, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus, Human Metapneumovirus, Rhinovirus, and Acienovirus. The detection and identification of specific viral nucleic Predicate (k063765, k081483,k091667) xTAG RVP The xTAG- Respiratory Viral Panel (RVP) is a qualitative nucleic acid multiplex test intended for the simultaneous detection and identification of multiple respiratory virus nucleic acids in nasopharyngeal swabs from individuals suspected of respiratory tract infections. The following virus types and subtypes are identified using RVP: Influenza A, Influenza A subtype HI, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus subtype A, Respiratory Syncytial Virus subtype B, Parainfluenza 1, Parainfluenza 2, and 'Parainfluenza 3 virus, Human
Luminex Molecular Diagnostics xTAG®1 RVP FAST Traditional 510(k) Submission Metapneumovirus, Rhinovirus, and Adenovirus. The detection and identification of specific viral nucleic acids from individuals exhibiting signs and symptoms of respiratory infection aids in the diagnosis of respiratory viral infection if used in conjunction with other clinical and laboratory findings. It is recommended that specimens found to be negative for Influenza B, Respiratory Syncytial Virus subtype A and B, Parainfluenza 1, Parainfluenza 2, Parainfluenza 3 and Adenovirus, after examination using RVP be confirmed by cell culture. Negative results do not preclude respiratory virus infection and should not be used as the sole basis for diagnosis, treatment or other management decisions. Positive results do not rule out bacterial infection, or co-infection with other viruses. The agent detected may not be the definite cause of disease. The use of additional laboratory testing (e.g. bacterial culture, immunofluorescence, radiography) and clinical presentation must be taken into consideration in order to obtain the final diagnosis of respiratory viral infection. Due to seasonal prevalence, performance characteristics for Influenza A/Hi were established primarily with retrospective specimens. The RVP assay cannot adequately detect Adenovirus species C,or serotypes 7a and 41. The RVP primers for detection of rhinovirus cross-react with enterovirus. A rhinovirus reactive result should be confirmed by an alternate method (e.g. cell culture). Performance characteristics for Influenza A Virus were established when Influenza A/H3 and A/Hi were the predominant Influenza A viruses in circulation. When other Influenza A viruses are emerging, performance characteristics may vary. If infections with a novel Influenza A virus is suspected based on current clinical and epidemiological screening criteria acids from individuals exhibiting signs and symptoms of respiratory infection aids in the diagnosis of respiratory viral infection if used in conjunction with other clinical and epidemiological information, Negative results do not preclude respiratory viral infection and should not be used as the sole basis for diagnosis, treatment or other management decisions. Positive results do not rule out bacterial infection or co-infection with other organisms. The agent detected may not be the definite cause of disease. The use of additional laboratory testing (e.g. bacterial and viral culture, immunofluorescence, and radiography) and clinical presentation must be taken into consideration in order to obtain the final diagnosis of respiratory infection, Due to the genetic similarity between human Rhinovirus and Enterovirus, the RVP FAST primers for the detection of rhinovirus cross react with enterovirus. A rhinovirus reactive result should be confirmed by an alternate method (e.g. cell culture). Performance characteristics for Influenza A Virus were established when Influenza A/H3 and A/Hi were the predominant Influenza A viruses in circulation. When other Influenza A viruses are emerging, performance characteristics may vary. If infection with a novel Influenza A virus is suspected based on current clinical and epidemiological screening criteria recommended by public health authorities, specimens should be collected with appropriate infection control precautions for novel virulent Influenza viruses and sent to a state or local health departments for testing. Viral culture should not be attempted in these
xTAG®1 RVP FAST Traditional 510(k) Submission
recommended by public health authorities, specimens should be collected with appropriate infection control precautions for novel virulent Influenza viruses and sent to a state or local health department for testing. Viral culture should not be attempted in these cases unless a BSL 3± facility is available to receive and culture specimens. Influenza A, Influenza A subtype Hi, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus, Human Metapneumnovirus, Rhinovirus, Adenovirus, Parainfluenza 1, parainfluenza 2 and Parainfluenza 3 QIAGEN QlAamp MiniElute, Biom6rieux NucliSENSO EasyMagO, and Biom6rieux MiniMagT&quot; xTAGO OneStep Enzyme Mix and
cases unless a BSL 3+ facility is available to receive and culture specimens.
Targets Reported
tnfluenza A,Influenza A subtype Hi, Influenza Asubtype H3, Influenza B, Respiratory Syncytial Virus, Human Metapneumovirus, Rhinovirus, and Adenovirus Biom6rieux NucliSENSI EasyMag*
Amplification Enzyme
xTAGO OneStep Enzyme Mix
ancillary reagent TaKaRa TaqTm Hot
Primer Mixes Software One primer mix (PCR and TSPE combined) xTAG Data Analysis Software RVP
FAST (US)
Start Two primer mixes (1 for PCR and 1 for TSPE) xTAG Data Analysis Software RVP (US)
Standards/Guidance Documents referenced (if applicable): Table 3: Guidance Documents Title Special Controls Guidance: Respiratory Viral Panel Multiplex 1 Class 11 Nucleic Acid Assay Special Control Guidance Document: Testing for Detection and Class 11 2 Differentiation of Influenza A Virus Subtypes Using Multiplex Assays 3 Guidance (Draft) for Establishing the Performance Characteristics of In Vitro Diagnostic Devices for the Detection or Detection and Differentiation of Influenza Viruses 4 Guidance for In Vitro Diagnostic Devices to Detect Influenza A Viruses:
____Labeling
Date Oct. 9, 2009 Oct. 9, 2009 Feb. 15, 2008
May 1, 2007 Mar. 22, 2006 Oct. 9, 2009 May 11, 2005 Aug. 12, 2005_ Page 5 of 12
and Regulatory Path
____Metapneumnovirus
Class 11Special Controls Guidance: Reagents for Detection of Specific Novel Influenza A Viruses Class 11 Special Control Guidance Document: &quot;Testing for Human (hMPV) Using Nucleic Acid Assays&quot; Guidance for the Content of Premarket Submissions for Software Contained in Medical Devices Guidance document for Format for Traditional and Abbreviated 510(k)s
Table 4: Standards
Standards No. 1 2 3 4 5 6 7 8 MM 13-A
_____Storage
7-191 7-153 7-110 7-127 7-152 7-194 7-128 and
Collection, Transport, Preparation and
of Specimens
03/18/2009 09/09/2008
EP15-A2 EP05-A2 EPO7-A2 EP12-A2 EP17-A EP14-A2 MMO3-A2
User Verification of Performance for
Precision and Trueness ( 2 nd edition)
Evaluation of Precision Performance of Quantitative measurement Methods (2 nd ed.) Interference Testing in Clinical Chemistry (2 nd edition) User Protocol for Evaluation f Qualitative Test Performance (2 &quot;dedition) Protocol for Determination of Limits of Detection and Limits of Quantitation Evaluation of Matrix Effects (2 nd edition)
10/31/2005 05/21/2007 09/09/2008 03/18/2009 06/01/2004 09/09/2008
Molecular Diagnostic Methods for Infectious
Diseases (2fld edition)
Test Principle: RVP FAST incorporates multiplex Reverse-Transcriptase Polymerase Chain Reaction (RT-PCR) with Luminex's proprietary Universal Tag sorting system on the Luminex* platform. The assay also detects an internal control (E.coli phage M52) which should be added to each sample prior to extraction, and a run control (bacteriophage Lambda DNA) which should be added as a separate RT-PCR reaction in each run performed. For each sample, viral extract (RNA or DNA) is amplified in a single multiplex RT-PCR reaction. For each of the viruses/subtypes or internal control present in the sample, PCR amplimers are produced. The RT-PCR product is then added to a hybridization/detection reaction containing the universal array (Bead Mix) and the Streptavidin-R-Phycoerythrin reporter. Each Luminex bead population detects a specific viral target or assay control through a highly specific anti-tag/tag hybridization. Following the incubation of the RT-PCR products with the bead mix and reporter, the hybrid ization/detection reactions are then sorted and read on the Luminex instrument. Signal (median fluorescence intensity, MFI) is generated for each bead population (viral target or assay control). These fluorescence values are then analyzed to establish the presence or absence of viral targets and/or controls in each sample tested.
Luminex Molecular Diagnostics xTAG® RVP FAST Traditional 510(k) Submission All viruses are identified in a single multiplex reaction. The data generated by the xMAP instrument is analyzed by the xTAG Data Analysis Software RVP Fast (TDAS RVP FAST) to provide a qualitative summary report on which viruses are present in the sample, if any. Performance Characteristics: Analytical Performance: Precision/Reproducibility: The site-to-site reproducibility (single analyte targets) study was conducted at three independent sites. Each of two operators performed fifteen separate EasyMag extraction runs and five xTAG RVP FAST runs on non-consecutive days for each of the 8 targets in the assay. For each target, at each dilution, there were 90 data points: 3 sites x 2 operator / site x 5 xTAG runs / operator x 3 replicates (EasyMag extraction runs). Site-to-site reproducibility for dlual-analyte targets was investigated by two operators employing the bioMerieux NucliSENSO EasyMag extraction kit and the RVP FAST test at three independent sites. Each operator conducted 5 separate extractions and runs, on non-consecutive days. There were a total of 30 replicates for each sample type: (3 sites) x (2 operators/site) x (5 runs/operator) = 30 runs. Four different clinically relevant co-infections were represented by the dlual-analyte samples. RVP FAST was reproducible across all sites, operators and targets. Limit of Detection (LaD): The LoD was determined for each of the following viral analyte targets from simulated samples arranged in a dilution series from a high titre stock: Flu A Hi, Flu A H3, Flu B, Adenovirus, RSV (A and B subtypes), Rhinovirus, and hMPV (subtypes Al, A2, Bl1and B32). For each reference strain,
the LoD is provided in Column 3 of the following table in TCID5o/mL.
Table5: Summary Limit of Detection (LoD) for RVP FAST analytes Analyte Adenovirus Flu A HI Flu A H3
Strain ID Type 1 Strain Adenoid 71 DHI 20-4740010 (original ATCC yR-i) A/Solomon lslands/3/2006 (NML) A/Victoria/3/75
TCIDso/mL (corresponding to the estimated LoD) ~x1 3. 02
7.6 x 10' 1.8 (matrix)
3.6 (H3)
HI 20-4710010 (original ATCC VR-822)
Influenza B/M alays ia/2506/04 FO 1-3774, Type 54
29x1_ _ _ _ _ _ _
Rhnoirs
Luminex Molecular Diagnostics ATCC 1164
University of Iowa, Dept. Public Health. (hMPV sublineage Al, Isolate # 16, Iowa, January 2003)341f CAN 97-83 (hMPV sublineage A2, CDC isolate 26583) University of Iowa, Dept. Public Health. (hMPV sublineage 831, Isolate #5, Iowa) University of Iowa, Dept. Public Health. (hMPV sublineage 82, Isolated October, 2003, Cusco, Peru) RSV A Long strain ATCC VR-26 RSV B Wash/18537/62
20-4730010 (original ATCC VR-1401)1.x1f
34x1_
1.x10
1.2 1.8 1.
___________DHI
Carryover Contamination Limit of Blank (LoB): This study was conducted using water blanks (DNase and RNase free distilled water) and replicate aliquots of a solution of purified viral nucleic acid (RSV B; Wash/I 8537/62DH1 204730010; originalIATCC VR-1401)) prepared from a High Positive (HP) titre simulated sample in a checkerboard manner. This titre was selected to fall far above the assay cut-oft, so that positive calls would be obtained 100% of the time and to experimentally maximize the potential for 'cross contamination'. RSV B was selected as the high titre analyte for the study, since it is commonly observed in clinical specimens at a high titre (Chidgey and Broadley, 2005)'. This titre was selected to fall far above the assay cut-off, so that positive calls would be obtained 100% of the time. The high titer purified viral nucleic acid replicates were tested to assess the probability of carryover contamination in adjacent wells containing water blanks. This study consisted of 6 identical runs tested over six (6) different days each performed by one operator, using a single kit lot and equipment set. The mean MFI of the High Positive RSV B specimen used in the carryover part of this evaluation was 10,860. No carryover contamination with RSV Bwas observed as the MFI values obtained in the blank positions was not significantly greater than the LoB in one or more blank position on the checkerboard plate layout. LoB was set as equal to the 9 5 th percentile of the observed MFI distribution generated from NEGATIVE calls for each analyte target in uncontaminated blanks and replicates of the high titre intact viral organisms
Chidgey, Sharon M.; Broadley, Kenneth J(2005). Respiratory syncytial virus infections: characteristics
and treatment. Journal of Pharmacy and Pharmacology, 57/11:1371-1382.
PageS8 of 12
Luminex Molecular Diagnostics xTAGO RVP FAST Traditional 510(k) Submission Table 6a: Limit of Blank per analyte in xTAG RVP FAST #fCalls Included Analyte (Virus)
#Call Excuded # Cals Icludd if CllsInclded ifCllsExclded ith
Limit of Blank MFI distribution
Percentile of
0 0 576 0 576 0 576 0 576 _RSV (probe 1) 0 288* RSV (probe 2) 0 576 Adenovirus 0 576 hMPV Rhinovirus 576 0 *Since the target selected for HP is RSV (probe 2)the LoB for this number of blank samples for the plate (whereas for all other samples on the plate). Flu A HI H3 Flu B 576
80 76.125 115.625 75.125 82.825
target was calculated based on the total targets, the LoB is calculated from all
Analytical Specificity (interference and Cross-Reactivity): A total of 26 potentially cross-reactive pathogens (bacterial and viral) were assessed in replicates with RVP FAST. Each replicate underwent a single EasyMag (bioMerieux NucliSENS®1) extraction prior to testing. These bacterial and viral pathogens did not cross-react or interfere with any viral target probed by RVP FAST. Table 7: Bacterial pathogens assessed as potential cross-reactive species in the RVP-FAST Assay Bordetella pertussis Chlamydlia pneumoniae Haemophillus influenzae Pseudomonas aeruginosa Streptococcus pneumoniae Moraxelia cartarrhalis Mycobacterium intracellulare Mycoplasma bovisMyoatru (substitute for M. tuberculosis)Mcoatru Mycoplasma pneumoniae Klebsiella pneumoniae Bacterial (n=20) Legionella pneumophilia Neisseria meningitides Staphylococcus aureus Staphylococcus epidermidis Streptococcus Group B Acinetobacter baumanii (calcoaceticus) Streptococcus pyogenes vm aim Serratia marcescens Escherichia coli
PageS9 of 12
xTAGI RVP FAST Traditional 510(k) Submission
Table 8: Viral pathagens assessed as potential cross-reactive species in the RVP-FASTAssay Viral (n=6)
-Cytomnegalovirus
A total of 14 combinations of analyte and potential interferent were assessed in replicate with RVP FAST. Each replicate underwent a single EasyMag (bioMerieux NucliSENS®) extraction prior to testing. These potential interfering agents were tested in the presence of targets meant to be detected by RVP FAST. Table 9: Combinations of Analytes &amp; Interferents tested in the interference branch. Potential interferent Target analyte Streptococcus pneumoniae RSV Bordetella pertussis Haernophilus influenzae CMAV Bordetella pertussis Adenovirus CVV Chlamydia pneumoniae Influenza A (H-3) Streptococcus pneumoniae Staphylococcus aureus Bordetella pertusis Chlamydlia pneumoniae Streptococcus pneumoniae Mycoplasma pneumoniae
______________________Haemnophilus
These substances did not cross-react or interfere with any viral target probed by RVP FAST. Comparison Studies: Clinical Studies: a. Clinical Sensitivity and Specificity: The purpose of this multi-site study was to establish the clinical accuracy of the RVP FAST assay to detect the assay targets Influenza A, Influenza Asubtype Hi, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus (RSV), Human Metapneumnovirus (hMPV), Rhinovirus, and Adenovirus in clinical specimens, across three independent sites. Specimens tested included left-over, fresh and frozen, nasopharyngeal swabs (NPS) prospectively collected during the 2007/2008 and 2008/2009 flu seasons (i.e. all-corners accrued at enrolled clinical sites). All clinical specimens were analyzed fresh, as per the clinical laboratory routine K(103776 xTAG RVP FAST 510(k) Summary Page 10 of 12
Luminex Molecular Diagnostics xTAG1 RVP FAST Traditional 510(k) Submission algorithm or as ordered by the referring physician, using Direct Fluorescent Antibody Test (DFA) and/or viral culture for the following targets: Influenza A, Influenza B, RSV, and Adenovirus. Well characterized RT-PCR amplification followed by bidirectional sequencing was used as the comparator method for Influenza A subtyping, hMPV and Rhinovirus. To the extent possible, amplification primers used in comparator methods targeted regions distinct from those targeted by the RVP FAST Assay primers. RVP FAST was performed on a total of 1191 prospectively collected clinical specimens that had been extracted from the fresh or frozen states were included in the performance calculations. Total extracted nucleic acid material was stored at -700C. Table 10: xTAGO RVP FAST Sensitivity/ Specificity per Target (Combined Data set) Sensitivity Virus (Analyte) T/95%C1 (TP+FN) percent Lower-Boun for Sensitivity 88.8% 87.3% 89.0% 84.3% 84.3% 84.9% 57.2% 85.5% Specificity T/95% (TN+FP)
.989/1036
Lower-Bound Cl for percent 95.5% 98.2% 97.8% 98.8% 97.7% Specificity 94.0% 97.2% 96.8% 98.0% 96.6% 90.8% 98.6% 98.2%
Human Influenza A 12/394.2% 7 96.3% 52/54 Hi 96.1% 74/77 H3 94.3% Human Influenza B 50/53 RSV Rhinovirus Adenovirus Metapneumnovirus 110/12
1116/1137 1090/1114 1107/1120 1028/1052
95.6% 43/45 57 12/1 35/36 197.2%
1047/1132 92.5% 1151/1159T 99.3% 1121/11331 98.9%
b. Other clinical supportive data. Since Adenovirus does not show seasonality, the prospective sample set was supplemented with 34 banked, pre-selected, positive clinical specimens collected at selected sites and tested by RVP FAST. All pre-selected specimens were frozen clinical samples which had originally been tested in the fresh-state using culture. The percent positive agreement of the test compared to the reference method was 97.06% (95% lower bound confidence interval of 86.47% - 99.93%). An additional 77 clinical specimens (NP swabs) confirmed positive for Novel 2009/HiNi (swine flu) by the CDC real-time PCR test were tested by RVP FAST. Of these, seventy-five (75) were Flu A unsubtypeable (97.40%, LB 95% Cl 90.93%), two (2)specimens were Flu A Hi by RVP FAST (2.60%). None were negative for Flu A. In addition, none of the confirmed Flu A Hi or Flu A H3 clinical specimens in the clinical data set were unsubtypeable for Influenza A by RVPR FAST. Clinical Cut-off: Not applicable.
Luminex Molecular Diagnostics xTAGI RVP FAST Traditional 510(k) Submission Expected values/ reference range: Not applicable. Conclusion: The information submitted in this premarket notification demonstrates that the device is equivalent to the predicate device.
DEPARTMENT OF HEALTH &amp; HUMAN SERVICES
and Drug Administration 10903 New Hampshire Avenue Silver Spring, MID 20993
Luminex Molecular Diagnostics, Inc. d/o Ms. Lubna Sved Director, Regulatory Affairs 439 University Avenue, Suite 900 Toronto, Ontario MSG IY8 Can ad a
Re: Ki03776 Trade/Device Name: xTAG®&amp; Respiratory Viral Panel FAST (RSP PAST) Regu1.lation Number: 21 CER 866.3980 Regulation Name: Respiratory viral panel multiplex nucleic acid assay Regulatory Class: Class I1 Product Code: 0CC, OEM, GEP Dated: June 3, 2011 Received: June 10, 2011 Dear Ms. Syed We have reviewed Your Section 510(k) premarket notification of intent to market the device referenced above and have determined the device is substantially equivalent (for the indications for use stated in the enclosure) to legally marketed predicate devices marketed in interstate commerce prior to May 28, 1976, the enactment date of the Medical Device Amendments, or to devices that have been reclassified in accordance with the provisions of the Federal Food, Drug, and Cosmetic Act (Act) that do not require approval of a premarket approval application (PMA). You may, therefore, market the device, subject to the general controls provisions of thle Act. Thle general controls provisions of the Act include requirements for annual registration, listing of devices, good manufacturing practice, labeling, and prohibitions against misbranding and adulteration. If your device is classified (see above) into class 11 (Special Controls), it may be subject to such additional controls. Existing major regulations affecting your device can be found in Title 21, Code of Federai Regulations (CFR), Parts 800 to 895. In addition, FDA may publish further announcements concerning your device in the Federal Relister. Please be advised that 1FDA's issuance of a substantial equivalence determination does not mean that FDA has made a determination that your device complies with other requirements of the Act or any Federal statutes and regulations administered by other Federal agencies. You must comply with all the Act's requirements, including, but not limited to: registration and listing (21 CFR Part 807); labeling (21 CFR Parts 801 and 809); medical device reporting (reporting of medical device-related adverse events) (21 CFR 803); and good manufacturing practice requirements as set forth in the quality systems (QS) regulation (21 CFR Part 820). This letter
Page 2 - Ms. Lubna Syed will allow You to begin marketing your device as described in)Your Section 510(k) premarket notification. The FDA finding of substantial equivalence of your device to a legally marketed predicate device results in a classification for your device and thus, permits your device to proceed to the market. If you desire specific advice for your device on our labeling regulation (21 CFR Parts 801 and 809), please contact the Office of In Vitro Diagnostic Device Evaluation and Safety at (301) 7965450. Also, please note the regulation entitled, &quot;Misbranding by reference to premarket notification&quot; (21 CFR Part 807.97). For questions regarding the reporting of adverse events under the MDR regulation (21 CER Part 803), please go to http://www. fdat.cov/Meclical Devices/Safety/Rep~ortaPr-ollm/defaul~htmi for the CDRH's Office of Surveillance and Biomnetrics/Division of Postmarket Surveillance. You may obtain other general information on your responsibilities under the Act from the Division of Small Manufacturers, International and Consumer Assistance at its toll-free number (800) 638-204 1 or (301) 796-7100 or at its Internet address lhttp://www. fda.2ov/cdrh/iindustry/support/index.html.
Sally A. Hojvat, M.Sc., Ph.D. Director Division of Microbiology Devices Office of In Vitro Diagnostic Device Evaluation and Safety Center for Devices and Radiological Health
510(k) Number (if known): k103776
Device Name: xTAG® RVP FAST The xTAG®&amp; Respiratory Viral Panel Fast (RVP FAST) isa qualitative nucleic acid multiplex test intended for the simultaneous detection and identification of multiple respiratory virus nucleic acids in nasopharyngeal swabs from individuals suspected of respiratory tract infections..The following virus types and subtypes are identified using RVP FAST: Influenza A, Influenza A subtype Hi, Influenza A subtype H3, Influenza B, Respiratory Syncytial Virus, Human Metapneumovirus, Rhinovirus, and Adenovirus. The detection and identification of specific viral nucleic acids from individuals exhibiting signs and symptoms of respiratory infection aids in the diagnosis of respiratory viral infection if used in conjunction with other clinical and epidemiological information. Negative results do not preclude respiratory viral infection and should not be used as the sole basis for diagnosis, treatment or other management decisions. Positive results do not rule out bacterial infection, or co-infection with other organisms. The agent detected may not be the definite cause of disease. The use of additional laboratory testing (e.g., bacterial and viral culture, immunofluorescence, and radiography) and clinical presentation-must-be taken into consideration in order to obtain the final diagnosis of respiratory infection. Due to the genetic similarity between human Rhinovirus and Enterovirus, the RVP FAST primers for the detection of rhinovirus cross-react with enterovirus. A rhinovirus reactive result should be confirmed by an alternate method (e.g., cell culture). Performance characteristics for Influenza A Virus were established when Influenza A/H3 and A/Hi were the predominant Influenza A viruses in circulation. When other Influenza .Aviruses are emerging, performance characteristics may vary. If infection with a novel Influenza A virus is suspected based on current clinical and epidemiological screening criteria recommended by public health authorities, specimens should be collected with appropriate infection control precautions for novel virulent Influenza viruses and sent to a state or local health department for testing. Viral culture should not be attempted in these cases unless a BSL 3+ facility is available to receive and culture specimens.
Prescription Use X
AND/OR Over-The-Counter Use
(Part 2i CFIR 801 Subpart 0)
(21 CFR 801 Subpart C)
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