THERASCREEN KRAS RGQ PCR KIT

{0} # SUMMARY OF SAFETY AND EFFECTIVENESS DATA (SSED) ## I. GENERAL INFORMATION Device Generic Name: Real-time PCR test Device Trade Name: therascreen® KRAS RGQ PCR Kit Device Procode: OWD Applicant’s Name and Address: QIAGEN Manchester Ltd. Skelton House, Lloyd Street North Manchester, UK M15 6SH Date(s) of Panel Recommendation: None Premarket Approval Application (PMA) Number: P110030 Date of FDA Notice of Approval: July 6, 2012 Expedited: Not applicable ## II. INDICATIONS FOR USE The therascreen KRAS RGQ PCR Kit is a real-time qualitative PCR assay used on the Rotor-Gene Q MDx instrument for the detection of seven somatic mutations in the human KRAS oncogene, using DNA extracted from formalin-fixed paraffin-embedded (FFPE), colorectal cancer (CRC) tissue. The therascreen KRAS RGQ PCR Kit is intended to aid in the identification of CRC patients for treatment with Erbitux® (cetuximab) based on a KRAS no mutation detected test result. ## III. CONTRAINDICATIONS None. ## IV. WARNINGS AND PRECAUTIONS The warnings and precautions can be found in the therascreen® KRAS RGQ PCR Kit labeling. ## V. DEVICE DESCRIPTION The following components comprise the overall device: - QIAGEN QIAamp® DSP DNA FFPE Tissue Kit - QIAGEN therascreen® KRAS RGQ PCR Kit - QIAGEN Rotor-Gene Q MDx, Software version 2.1.0, and KRAS Assay Package {1} 2 # Specimen Preparation Formalin-fixed, paraffin-embedded (FFPE) blocks are sectioned onto glass slides. A stained slide is used to confirm that the tumor content exceeds 20% of the tissue and that a minimum tumor area of 4mm² is available. A single non-stained tissue section is scraped from the slide for DNA extraction. If sections have a tumor content of less than 20%, the section should be macrodissected. DNA is manually extracted and purified from 5 μm glass-mounted sections of FFPE tissue taken from colorectal cancer patients using the QIAGEN QIAamp® DSP DNA FFPE Tissue Kit and a modified protocol. The tumor tissue is deparaffinized with xylene and the xylene is extracted with ethanol. The sample is lysed under denaturing conditions with proteinase K for one hour. The sample is heated at 90°C to reverse formalin cross-linking of genomic DNA. The sample is passed through a silica-based membrane so that genomic DNA binds to the membrane and contaminants are removed. Purified genomic DNA is eluted from the membrane into 200 μL of elution buffer. Extracted DNA is stored at -20°C. # PCR Amplification and Detection The QIAGEN therascreen® KRAS RGQ PCR Kit contains reagents for eight separate reactions; seven mutation specific reactions to amplify and detect mutations in codons 12 and 13 in exon 2 of the K-Ras oncogene, and one Control Reaction that amplifies and detects a region of exon 4 in the K-Ras oncogene. Each reaction in the KRAS RGQ Kit makes use of an amplification refractory mutation system (ARMS®) allele specific polymerase chain reactions (PCR) to selectively amplify mutated genomic DNA templates (mutation-positive) in a background of non-mutated genomic DNA (mutation-negative; wild-type) combined with a fluorophore-labeled Scorpion® primer to detect any resultant amplification product. ARMS technology exploits the ability of Taq polymerase to distinguish between a match and a mismatch at the 3' end of a PCR primer. Scorpions are bifunctional molecules containing a PCR primer covalently linked to a probe. The probes incorporate both a fluorophore, [carboxyfluorescein (FAM™)] and a quencher which quenches the fluorescence of the fluorophore. During PCR, when the probe binds to the ARMS amplicon, the fluorophore and quencher become separated leading to a detectable increase in fluorescence. Before testing with the mutation-specific test reactions, each DNA sample must be tested with the Control Reaction to determine whether the quality and quantity of DNA is sufficient and appropriate for the working range of the assay. The Control Reaction Ct value is used to assess the total amplifiable DNA in a sample and must fall within prespecified ranges for each sample. The interpretation of the results obtained from the Control reaction is as follows: {2} | Control Ct value | Interpretation | Action | | --- | --- | --- | | >32.00 | Quantity of amplifiable DNA is not sufficient for mutation analysis. | Additional samples should be extracted and tested | | <21.92 | Quantity of amplifiable DNA is too high for mutation analysis. | Dilute with the sample diluent water supplied in the kit | | 21.92≤Control Ct≥32.00 | Quantity of amplifiable DNA is suitable for mutation analysis. | --- | The run parameters used for assessing the DNA sample with the Control Reaction mix are the same run parameters for mutation analysis using the Mutation Reaction mixes. They run parameters are: (1) Hold at $95^{\circ}\mathrm{C}$ for 15 minutes to activate the Taq polymerase; (2) PCR for 40 cycles of $95^{\circ}\mathrm{C}$ for 30 seconds, to denature, and $60^{\circ}\mathrm{C}$ for 1 minute, to anneal/extend. The PCR cycle at which the fluorescence from a particular reaction crosses the pre-defined threshold value is defined as the Ct value. The seven mutations in codons 12 and 13 of the K-RAS oncogene detected by the Kit are listed below: | Mutation | Base Change | | --- | --- | | GLY12ALA (G12A) | GGT>GCT | | GLY12ASP (G12D) | GGT>GAT | | GLY12ARG (G12R) | GGT>CGT | | GLY12CYS (G12C) | GGT>TGT | | GLY12SER (G12S) | GGT>AGT | | GLY12VAL (G12V) | GGT>GTT | | GLY13ASP (G13D) | GGC>GAC | # Test Controls Each test run must contain an Internal Control, the Positive Control, and the Negative Control. A test run is considered invalid if the Negative Control indicates that the test run has been contaminated (Ct value above a set value for the FAM channel) or if the Positive Control Ct value lies outside a set range (both FAM and HEX channels). Run Validity Criteria | Reaction Mix | Sample | RGQ Channel | Valid Ct Range* | | --- | --- | --- | --- | | Control | Positive Control | FAM | 23.50 to 29.50 | | Control | No Template Control | FAM | No Amplification | | Control | No Template Control | HEX | 31.91 to 35.16 | | Mutation | Positive Control | FAM | 23.50 to 29.50 | | Mutation | No Template Control | FAM | No Amplification | | Mutation | No Template Control | HEX | 31.91 to 35.16 | *Ranges are inclusive {3} 4 # Internal Control: All eight reactions contain an additional ARMS primer and a HEX-labeled Scorpion primer for the amplification and detection of a synthetic non K-Ras related oligonucleotide template that is used as an Internal Control. The Scorpion primer is labeled with HEX to distinguish from the FAM-labeled Scorpions in the control and mutation reactions. In each reaction, the Internal Control reaction is designed to be the weaker of the two reactions. This is achieved through the use of a very low concentration of Internal Control template. The Internal Control reaction is designed to work independently of mutation-specific amplification, but can fail in the presence of strong amplification if it is "out-competed" by the FAM reaction. A mutation negative result with a failed Internal Control reaction in any one of the seven mutation reactions will be reported as an invalid result. The Internal Control is used to detect inhibitors or gross reaction failures. # Positive Control: The positive control is comprised of a mixture of synthetic oligonucleotides representing each of the mutations detected by the KRAS Kit. Detection of the positive control confirms the proper functioning of each of the reaction mixes in the Kit. # Negative Control: The KRAS RGQ Kit contains nuclease-free water to be used as a no template control (NTC) reaction. The NTC serves as a negative control and assesses potential contamination during assay set up. # Instrument and Software The Rotor-Gene Q (RGQ) MDx Instrument is a real-time PCR analyzer designed for thermocycling and real-time detection of amplified DNA. The RGQ MDx Instrument controls and monitors PCR reactions and includes the software that determines mutation status based upon PCR results. It incorporates a centrifugal rotor design for thermal cycling during PCR reactions where each tube spins in a chamber of moving air. Samples are heated and cooled in a low-mass-air oven according to a software determined cycle that initiates the different phases of the PCR cycle for a total of 40 cycles for each PCR run. In the RGQ MDx Instrument, samples are excited from the bottom of the chamber by a light emitting diode. Energy is transmitted through the thin walls at the base of the tube. Emitted fluorescence passes through the emission filters on the side of the chamber and is detected by a photomultiplier tube. Detection is performed as each tube aligns with the detection optics; tubes spin past the excitation/detection optics every 150 milliseconds. The fluorescence signals monitor the progress of the PCR reactions. The instrument is capable of supporting up to six optical channels (six excitation sources and six detection filters), however only two of these channels (the FAM and HEX channels) are used with the KRAS Kit. The therascreen KRAS Assay Package consists of two templates: the "therascreen KRAS QC Locked Template" (for DNA sample assessment) and the "therascreen KRAS Locked Template" (for detection of KRAS mutations). These templates contain the PCR run {4} parameters and calculate the results. The same run parameters are used for both the DNA sample assessment with the Control Reaction Mix and for detection of KRAS mutations using the mutation reaction mixes. The RGQ MDx Instrument software supports real-time analysis procedures. The software determines Ct values, calculates $\Delta$ Ct values, and compares these to the mutation-specific cut-off values incorporated into the software as described above. A system of Flags/Warnings is embedded within the software in order to inform the user of potential problems with the assay and to indicate non-valid test runs or non-valid samples within a valid test run (inappropriate level of DNA or Internal Control failure). No results are reported for invalid runs or for non-valid samples. Users of the KRAS RGQ Kit cannot make subjective determinations of mutation status as they do not have access to the Ct or $\Delta$ Ct values and only see the mutation status calls reported by the software. # Interpretation of Results The Ct for the control reaction reflects the total amount of amplifiable K-Ras template in the sample, while the Ct for the allele specific reactions reflect the amount of K-Ras mutation within the sample. The difference in Ct values ( $\Delta$ Ct) between the control reaction and the allele-specific reaction indicates the proportion of mutation within the sample. The $\Delta$ Ct value approaches 0 as the proportion of mutant DNA in the samples increases. The $\Delta$ Ct value increases (approaches the threshold for positive vs. negative call) as the proportion of mutant DNA in the sample decreases. When the $\Delta$ Ct measure exceeds $\Delta$ Ct cut-off values for the mutant reactions, the assay reports no mutation detected (e.g., negative for the 7 mutations). For each sample, a calculation is performed by the RGQ MDx Instrument software to determine the $\Delta$ Ct value (FAM channel) for each of the 7 mutation-specific reactions: [Mutation reaction Ct value] - [Control Reaction Ct value] = $\Delta$ Ct Based on pre-determined analytical Ct and $\Delta$ Ct values, the Rotor-Gene Q software qualitatively determines the mutation status of the DNA samples and reports which samples contain which mutation. Each sample will have seven possible $\Delta$ Ct values (one per mutation). These values are compared to pre-established specifications (cut-off values) incorporated into the RGQ MDx Instrument software to determine whether a sample is mutation positive or negative and which mutation, if any, is present. When the mutation reaction $\Delta$ Ct value is less than or equal to the cut-off value for that reaction, the sample is K-Ras mutation-positive. The assay results will be displayed as "Mutation Positive," "No Mutation Detected," "Invalid" or, if a run control fails, "Run Control Failed." For the mutation-positive samples, specific mutations are reported. | Mutation Assay | 12ALA | 12ASP | 12ARG | 12CYS | 12SER | 12VAL | 13ASP | | --- | --- | --- | --- | --- | --- | --- | --- | | Cut-Off (ΔCt) | ≤8.0 | ≤6.6 | ≤8.0 | ≤8.0 | ≤8.0 | ≤7.5 | ≤7.5 | {5} VI. ALTERNATIVE PRACTICES AND PROCEDURES There are no other FDA-cleared or approved alternatives for the testing of colorectal cancer tissue for detecting mutations in the K-Ras oncogene for the selection of patients who may benefit with Erbitux® (cetuximab) therapy. VII. MARKETING HISTORY The QIAGEN therascreen® KRAS RGQ PCR Kit has not been marketed in the United States or any foreign country. VIII. POTENTIAL ADVERSE EFFECTS OF THE DEVICE ON HEALTH Failure of the device to perform as expected or failure to correctly interpret test results may lead to incorrect K-Ras test results, and consequently improper patient management decisions in colorectal cancer treatment. A false positive test result may lead to Erbitux® (cetuximab) treatment being withheld from a patient who might have benefitted. A false negative test result may lead to Erbitux® (cetuximab) treatment being administered to a patient who is not expected to benefit, and potentially any adverse side effects associated with treatment. For the specific adverse side effects that are associated with Erbitux® (cetuximab) treatment, please see Section X below. IX. SUMMARY OF PRECLINICAL STUDIES A. Laboratory Studies The specific performance characteristics of the QIAGEN therascreen® KRAS RGQ PCR Kit (henceforth referred to as KRAS Kit) were determined by studies using formalin-fixed, paraffin-embedded (FFPE) tissue specimens collected from colorectal cancer patients (CRC) and 8 formalin-fixed, paraffin-embedded human cell lines (FFPE cell lines) of which 7 harbor known K-Ras mutations, and one K-Ras wild-type (i.e., glycine amino acids at codons 12 and 13). Mutation status of specimens was confirmed by bi-directional Sanger sequencing. The similarity between FFPE cell lines and FFPE clinical specimens was demonstrated. FFPE cell lines were sectioned and processed similar to FFPE patient specimens. DNA was extracted and tested according the instructions for use. 1. Comparison to Reference Method To demonstrate the accuracy of the KRAS Kit relative to Sanger bi-directional sequencing, two accuracy studies with procured specimens were conducted. In the first study, a set of 350 procured tumor specimens from CRC patients was obtained based on characteristics that aligned with patient samples screened in the clinical trial (i.e., intended use population). Variables that impact test performance were described for the procured specimens and compared to the clinical trial specimens. The variables were deemed similar between both groups and consisted of patient demographics (age, genders, race, and country of origin), fixation process, tumor sampling, tumor tissue content, stage, histology, amount of necrotic tissue, and storage conditions. Using a statistical random sampling technique, 150 samples of unknown mutation status were chosen for evaluation. Ten sequential 5μm sections 6 {6} were cut from each sample and mounted onto glass slides. Sections used for testing with the KRAS Kit or for bi-directional sequencing were adjacent to each other. Specimens were processed and tested by the KRAS Kit according to the final product labeling. All sections used for bi-directional sequencing were macrodissected to enrich for tumor content. A Phred score greater than 40 was a pre-specified acceptance criterion for sequencing (seven samples that failed were excluded). Invalid and indeterminate samples were retested according to protocol. The results demonstrated that the KRAS Kit reported two samples as negative. These samples were reported by bi-directional sequencing to be positive for 12ASP or 13ASP. In contrast three samples were reported as having a K-Ras mutation by the KRAS Kit that were not reported as positive by sequencing. In addition, one sample identified as 12ARG by the KRAS Kit was determined to be 12ASP by sequencing. The overall results are shown in the Table below. ## KRAS Kit compared to Sanger bi-directional Sequencing | | | Mutation Call by Bi-Directional Sequencing | | | | | | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | | | | Mutation Negative | IND | 12ALA | 12ARG | 12ASP | 12CYS | 12SER | 12VAL | 13ASP | Total | | KRAS Kit call | Indeterminate | 3 | - | - | - | - | - | - | - | - | 3 | | | Invalid | 2 | - | - | - | - | - | - | - | - | 2 | | | Mutation-negative | 80 | - | - | - | 1 | - | - | - | 1 | 82 | | | 12ALA | - | - | 3 | - | - | - | - | - | - | 3 | | | 12ARG | - | - | - | - | 1 | - | - | - | - | 1 | | | 12ASP | - | - | - | - | 20 | - | - | - | - | 20 | | | 12CYS | - | - | - | - | - | 3 | - | - | - | 3 | | | 12SER | - | 1 | - | - | - | - | - | - | - | 1 | | | 12VAL | 2 | - | - | - | - | - | - | 14 | - | 16 | | | 13ASP | 1 | - | - | - | - | - | - | - | 11 | 12 | | | Total | 88 | 1 | 3 | 0 | 22 | 3 | 0 | 14 | 12 | 143 | Concordance between methods for this study was calculated as the positive percent agreement (PPA), negative percent agreement (NPA) and overall percent agreement (OPA) with the 95% confidence intervals for all samples with valid results. The results demonstrate a PPA of 96.3%, a NPA of 96.3% and an OPA of 96.4%. ## Agreement for Samples with both Sanger and KRAS Kit valid Results | Measurement of Agreement | Percentage | 95% CI | | --- | --- | --- | | Overall percent agreement (OPA) | 96.3% (132/137) | 92.69 – 98.21 | | Percent positive agreement (PPA) | 96.3% (52/54) | 89.41 – 98.77 | | Percent negative agreement (NPA) | 96.4% (80/83) | 91.30 – 98.55 | {7} A sensitivity analysis was performed to evaluate the agreement between the two methods if all of the KRAS Kit indeterminate and invalid results were treated as mutation-positive or as mutation-negative. Under the condition where all of the invalid/indeterminate calls are assumed to be positive, the NPA was reduced to 90.9% and the OPA reduced to 92.9%. A second unique set of 271 CRC FFPE specimens were procured and compared to Sanger bi-directional sequencing as described above to supplement the data from the first study. The set consisted of 250 specimens of unknown mutations status, and 21 specimens of known mutation status to enrich for rare mutations. A total of 13 (~5%) specimens required macrodissection in accordance with KRAS Kit instructions because the tumor content was less than 20%. Out of the 271 specimens tested, 24 were indeterminate (failed control Ct range). Concordance analysis was carried out on 247 samples with both valid bi-directional and KRAS Kit results. There were 9 discordant samples. One sample from the 247 samples had a mutation positive result with bi-directional sequencing but a mutation negative result with the KRAS Kit. Eight samples were shown to have a positive result with the KRAS Kit but a negative result with bi-directional sequencing. The results are shown in the tables below. Overall agreement was 96.4%. The data supports the performance of the therascreen® RGQ PCR KRAS Kit. Comparison of Mutation Calls by KRAS Kit and Bi-directional Sequencing | | | Mutation Call by Bi-Directional Sequencing | | | | | | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | | | | Mutation Negative | IND | 12ALA | 12ARG | 12ASP | 12CYS | 12SER | 12VAL | 13ASP | Total | | KRAS Kit call | Indeterminate | 15 | 5 | 1 | - | 1 | 1 | - | 1 | - | 24 | | | Mutation-negative | 132 | - | - | - | - | - | 1 | - | - | 133 | | | 12ALA | - | - | 10 | - | - | - | - | - | - | 10 | | | 12ARG | 5 | - | - | 5 | - | - | - | - | - | 10 | | | 12ASP | - | - | - | - | 31 | - | - | - | - | 31 | | | 12CYS | 1 | - | - | - | - | 11 | - | - | - | 13 | | | 12SER | - | - | - | - | - | - | 13 | - | - | 13 | | | 12VAL | 2 | - | - | - | - | - | - | 25 | - | 27 | | | 13ASP | - | - | - | - | - | - | - | - | 11 | 11 | | | Total | 155 | 5 | 11 | 5 | 32 | 12 | 14 | 26 | 11 | 271 | Agreement between Sanger and KRAS Kit* | | Percent observed agreement (Lower 95% confidence interval) | | --- | --- | | Overall percent agreement | 96.36% (93.73%) | | Positive percent agreement | 99.07% (95.64%) | | Negative percent agreement | 94.29% (89.93%) | * Excluding the 24 KRAS Kit indeterminate results (failed Control Ct range) {8} 9 ## 2. Analytical Sensitivity ### a) Limit of Blank (LoB) – No Template To assess performance of the therascreen® KRAS RGQ PCR Kit in the absence of template and to ensure that a blank sample does not generate an analytical signal that might indicate a low concentration of mutation, samples with no template were evaluated. Ten KRAS Kit runs consisting of specimens with nuclease-free water (no DNA template) were conducted. Each of the runs included positive and negative controls, as well as seven no-template samples. The results demonstrated no detectable control or mutant Ct values in any of the mutation or control reaction wells (Internal control Ct values were all valid). Results are reported as invalid due to failed controls in the absence of DNA. ### b) Limit of Detection (LoD) The therascreen® KRAS RGQ PCR Kit does not use a specific concentration of DNA as determined by spectrophotometry. DNA input is based on the Control reaction Ct result which is used to indicate that there is sufficient amplifiable DNA present in the sample. The stated DNA input for the assay is defined by the Control Ct prespecified range 21.92 to 32.00. For the therascreen® KRAS RGQ PCR Kit, the limit of detecting mutant DNA in a background of wild-type DNA is defined as the lowest dilution factor at which 95% of the test replicates for each mutation positive sample were determined to be positive. Eight FFPE cell lines; seven with known mutant DNA content and one wild-type were used for this evaluation. The proportion of mutant in total amplifiable DNA (percent mutant DNA) was determined previously using a bi-directional Sanger sequencing method from unfixed cells followed by relative peak analysis. In the case of three cell lines the mutant content was 100% (i.e., the cell line DNA was homozygous mutant). The other cell lines were of mixed zygosity. Multiple DNA extractions from each sample were pooled to generate DNA stocks. The DNA stocks were then normalized to achieve target Control reaction Ct values. Normalized mutant DNA extracts were diluted with normalized WT DNA extract to create a dilution series of extracts containing the same level of total amplifiable DNA but different levels of mutant DNA. Serial dilutions were then generated from these samples and 9 replicates for each dilution were run. The first dilution series was created for the mid-range Control reaction Ct value (approximately 26). The percentage of correct calls as a function of the dilution for each mutant reaction is shown below. Shaded boxes indicate the corresponding dilution for each mutant reaction in which greater than 95% of the replicates produced correct calls. {9} Percentage of Correct Calls | | % Correct Calls | | | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | | % Mutation Dilution | 12ALA | 12ASP | 12ARG | 12CYS | 12SER | 12VAL | 13ASP | | 0.78 | 100 | 0 | 33.3 | 55.6 | 22.2 | 66.7 | 0 | | 1.56 | 100 | 33.3 | 100 | 100 | 88.9 | 100 | 0 | | 3.13 | 100 | 77.8 | 100 | 100 | 100 | 100 | 66.7 | | 6.25 | 100 | 100 | 100 | 100 | 100 | 100 | 100 | | 12.5 | 100 | 100 | 100 | 100 | 100 | 100 | 100 | | 25.0 | 100 | 100 | 100 | 100 | 100 | 100 | 100 | | 50.0 | 100* | 100 | 100 | 100 | 100 | 100 | 100 | * Mutation Dilution for this sample was 40.0. The results of the first dilution series were used to generate dilutions for the confirmation of LoD values using narrower, reaction-specific ranges of percent mutation dilutions at both low and high levels within the input range of the assay. The target value for the High series was approximately Ct 23-24. Twelve replicates for each dilution were evaluated for the High dilution series. The percentage of correct calls is described for each dilution in the High series and is shown in the tables below. Shaded boxes indicate the percentage in which greater than 95% of the replicates produced correct calls. Percentage of Correct Calls for High Dilution Series | | | % Mutation Dilution (High) | | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | | 12ALA | | 0.13 | 0.27 | 0.54 | 1.08 | 2.15 | 4.30 | | | % correct calls | 0 | 0 | 91.7 | 100 | 100 | 100 | | 12ASP | | 0.56 | 1.13 | 2.25 | 4.50 | 9.00 | 18.00* | | | % correct calls | 0 | 8.3 | 33.3 | 83.3 | 100 | 100 | | 12ARG | | 0.16 | 0.33 | 0.65 | 1.30 | 2.60 | 5.20 | | | % correct calls | 0 | 0 | 8.3 | 100 | 100 | 100 | | 12CYS | | 0.12 | 0.24 | 0.49 | 0.98 | 1.95 | 3.90 | | | % correct calls | 0 | 0 | 8.3 | 83.3 | 100 | 100 | | 12SER | | 0.31 | 0.63 | 1.25 | 2.50 | 5.00 | 10.00 | | | % correct calls | 0 | 0 | 33.3 | 66.7 | 100 | 100 | | 12VAL | | 0.17 | 0.34 | 0.69 | 1.38 | 2.75 | 5.50 | | | % correct calls | 0 | 0 | 16.7 | 100 | 100 | 100 | | 13ASP | | 0.63 | 1.25 | 2.50 | 5.0 | 10.0 | 20.0 | | | % correct calls | 0 | 0 | 0 | 100 | 100 | 100 | *Eleven valid replicates in this evaluation The target Ct value for the Low series was approximately 31. Each dilution was run as 24 replicates unless otherwise indicated. The percentage of correct calls is described for each dilution in the Low series and is shown in {10} the tables below. Shaded boxes indicate the percentage in which greater than $95\%$ of the replicates produced correct calls. Percentage of Correct Calls for Low Dilution Series | | | % Mutation Dilution (Low) | | | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | --- | | 12ALA | | 0.27 | 0.54 | 1.08 | 2.15 | 4.30 | 8.60 | 12.90 | | | % correct calls | 12.5 | 20.8 | 33.3 | 83.3 | 100 | 100 | 100 | | 12ASP | | 0.56 | 1.13 | 2.25 | 4.50 | 9.0 | 18.0 | 27.0 | | | % correct calls | 0 | 16.7 | 29.2 | 58.3 | 100 | 100 | 100 | | 12ARG* | | 0.33 | 0.65 | 1.30 | 2.60 | 5.20 | 10.4 | 15.6 | | | % correct calls | 8.3 | 4.2 | 29.2 | 52.2 | 95.8 | 100 | 100 | | 12CYS | | 0.24 | 0.49 | 0.98 | 1.95 | 3.90 | 7.80 | 11.7 | | | % correct calls | 8.3 | 4.2 | 20.9 | 54.2 | 83.3 | 100 | 100 | | 12SER | | 0.63 | 1.25 | 2.50 | 5.0 | 10.0 | 20.0 | 30.0 | | | % correct calls | 0 | 0 | 8.3 | 33.3 | 70.9 | 83.3 | 100 | | 12VAL** | | 0.34 | 0.69 | 1.38 | 2.75 | 5.50 | 11.00 | 16.50 | | | % correct calls | 4.3 | 16.7 | 46.7 | 75.0 | 100 | 100 | 100 | | 13ASP | | 0.63 | 1.25 | 2.5 | 5.0 | 10.0 | 20.0 | 30.0 | | | % correct calls | 0 | 4.2 | 8.3 | 33.3 | 70.8 | 100 | 100 | *For the 2.60 dilution, the number of valid replicates was 23 for 12ARG. **Valid replicates for the 12VAL series were 23, 24, 15, 16, 13, 12, and 19. Logistic Regression models were applied to each assay individually for the low and high input DNA datasets. In these models, the response variable was the binary output of mutation detected (detect = 1) and mutation not detected (detect = 0), the continuous explanatory variable was $\log_2\%$ mutation dilution. The LoDs were calculated as the percent mutation dilution which gave a predicted probability of detection of 0.95. The LoDs determined from the dilution series beginning with either the low or high Ct values are shown in the Table below. Logistics Regression Data for Low and High Ct Dilution Series | | Low | High | | --- | --- | --- | | 12ALA | 4.25 | 0.56 | | 12ASP | 7.27 | 0.87 | | 12ARG | 10.23 | 6.43 | | 12CYS | 6.90 | 1.21 | | 12SER | 25.75 | 4.20 | | 12VAL | 5.17 | 0.90 | | 13ASP | 18.83 | 4.16 | {11} The data overall supports the manufacturers Final LoD claims for FFPE cell lines when the input Ct value is between approximately 22 and 27 Ct. At the lower end of the Ct input range, the sensitivity of the assay decreases as the amount of input DNA may not contain sufficient copies to support the same percentage ratios of wild type to mutant DNA observed within the high and mid points of the working range. LoD Claims FFPE Cell Lines when Control Reaction Ct Range ~22-27 | Mutation Reaction | Final LoD Claim | | --- | --- | | 12ALA | 0.8 | | 12ASP | 2.6 | | 12ARG | 6.4 | | 12CYS | 1.5 | | 12SER | 5.6 | | 12VAL | 1.6 | | 13ASP | 6.4 | c) Control Ct Range and RFI Validation For the KRAS Kit, the acceptable Control Ct range that is used to determine the amount of DNA input and the threshold value is set at 0.05 relative fluorescence units (RFI). This value is configured in the KRAS Locked Templates for both the FAM and HEX channels. The threshold value and Control Ct range were defined during development of the KRAS Kit. Briefly, 220 FFPE samples were assayed. Control reaction Ct values were tested for normality and one-side tolerance limits were developed such that 97.5% of the Control Ct values in the mutation reactions fall above the lower limit with a confidence level &gt;90%. Box and Whisker plots of the ΔCt values were based on the assignment of the optimized Control Ct range and are shown in the box below. The line within each box represents the median value in the distribution, while the box represents the 25th and 75th percentile. The hashed line shows the cut-offs, above that are the mutation negative samples, and below that the mutation-positive samples. {12} # Cut-off $\Delta$ Ct Values by Mutation  # 3. Effect of DNA Input on $\Delta$ Ct Values The DNA input level is defined as the total quantity of amplifiable K-Ras DNA in a sample and is determined by the Ct values from the Control reaction. When samples at different total DNA levels contain the same proportion of mutant DNA, it is expected that the measured $\Delta$ Ct values will remain consistent. The objective of the study was to demonstrate that the performance of the KRAS Kit is consistent over the total DNA input (Control Ct) range of the assay. DNA extracted from 8 FFPE cell lines was used to prepare pools of DNA with the lowest achievable control reaction Ct. Concentrated DNA stocks were subsequently diluted to generate DNA spanning the working range (total of 5 dilutions including the initial concentrated stock). For mutations 12ALA, 12ASP, 12ARG and 12VAL were diluted 1:10 (range 1 to .0001). For mutations 12CYS, 12SER and 13ASP, the dilutions were 1:5.5 (range 1 to 0.001). For each point within the working range sufficient material was prepared to carry out 6 replicate tests. The Dilution range for each mutation reaction, mean Ct value for the Control and Ct reactions in the test runs are shown in the Table below. The results from each mutation pool tested showed Control Reaction Ct values corresponding with the targeted values. For each of the mutations detected by the KRAS Kit, the $\Delta$ Ct values measured at different total DNA input levels spanning the working range of the assay passed the pre-set acceptance criteria for the study. {13} Mean Ct Values across the Control Reaction Ct Range – FFPE Cell Lines | | Mean Mutation Ct Value | | | | | Mean Control Ct Value | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | | | Dilution 1 | 2 | 3 | 4 | 5 | Dilution 1 | 2 | 3 | 4 | 5 | | 12ALA | 22.75 | 25.57 | 28.77 | 32.31 | 35.77 | 21.19 | 24.32 | 27.61 | 31.17 | 34.51 | | 12ASP | 23.45 | 26.32 | 29.64 | 33.28 | 36.5 | 20.99 | 24.14 | 27.54 | 31.17 | 34.66 | | 12ARG | 21.37 | 24.71 | 28.05 | 31.49 | 34.84 | 20.19 | 24.08 | 26.97 | 30.55 | 33.78 | | 12CYS | 24.32 | 26.64 | 28.99 | 31.45 | 33.8 | 23.35 | 25.94 | 28.4 | 30.64 | 33.13 | | 12SER | 25.54 | 27.19 | 29.67 | 32.14 | 34.61 | 22.63 | 24.98 | 27.52 | 29.99 | 32.53 | | 12VAL | 21.53 | 24.72 | 28.05 | 31.24 | 34.41 | 21.24 | 24.47 | 27.9 | 30.99 | 34.51 | | 13ASP | 26.7 | 28.54 | 30.8 | 33.12 | 35.65 | 23.13 | 25.7 | 28.26 | 30.66 | 33.03 | The mean $\Delta \mathrm{Ct}$ values for each mutation reaction and each dilution are displayed as a function of the Control Reaction Ct ranges for the dilutions in the Table below. Although there is a slight increase in $\Delta \mathrm{Ct}$ as DNA input increases, overall, the $\Delta \mathrm{Ct}$ values were consistent across the working range of the KRAS Kit within the prespecified acceptance criteria. Mean $\Delta$ Ct Values across the Control Reaction Ct Range - FFPE Cell Lines | | Dilution (1) ~20-21Ct | Dilution (2) ~ 23-24Ct | Dilution (3) ~ 26-27Ct | Dilution (4) ~29-30Ct | Dilution (5) ~32-33Ct | | --- | --- | --- | --- | --- | --- | | | Mean ΔCt | | | | | | 12ALA | 1.56 | 1.25 | 1.16 | 1.14 | 1.27 | | 12ASP* | 2.46 | 2.18 | 2.11 | 2.11 | 1.75 | | 12ARG | 1.18 | 0.63 | 1.08 | 0.94 | 1.06 | | 12VAL | 0.29 | 0.25 | 0.15 | 0.26 | -0.1 | | | ~ 22-23Ct | ~ 24-25Ct | ~ 27-28Ct | ~29-30Ct | ~32-33Ct | | | Mean ΔCt | | | | | | 12SER | 2.91 | 2.21 | 2.15 | 2.15 | 2.08 | | 12CYS | 0.98 | 0.71 | 0.58 | 0.81 | 0.67 | | 13ASP | 3.57 | 2.84 | 2.54 | 2.46 | 2.62 | *In the case of 12ASP data, total number of replicates was 27. DNA extracts from FFPE CRC samples were also prepared and diluted to represent three total DNA input levels; nominally High, Medium and Low DNA input levels as defined by the absolute Ct value of the KRAS Kit Control reaction. The High and Medium DNA input levels were within the working range of the assay (i.e., Control Ct range 21.92 - 32.00). The Low DNA input level dilutions were targeted to be within the working range of the assay, however, for the purposes of this study, values that fell outside the working range were also included in the study analysis. The data demonstrates $\Delta \mathrm{Ct}$ values are similarly consistent across DNA input levels. {14} Effect of DNA Input on $\Delta$ Ct Values across the Input Ct Range - CRC Samples | | Mean Control Ct | | | Mean Mutant Ct | | | Mean ΔCt | | | | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | | | Low | Med | High | Low | Med | High | Low | Med | High | | 12ALA | 31.50 | 28.36 | 25.41 | 33.19 | 30.14 | 27.37 | 1.69 | 1.78 | 1.95 | | 12ASP | 30.74 | 27.52 | 25.44 | 33.00 | 29.90 | 27.16 | 2.26 | 2.39 | 2.72 | | 12ARG | 32.12 | 29.23 | 27.03 | 34.18 | 31.34 | 29.24 | 2.06 | 2.11 | 2.21 | | 12CYS | 30.85 | 27.36 | 24.43 | 33.51 | 30.10 | 27.43 | 2.66 | 2.74 | 3.00 | | 12SER | 30.35 | 27.64 | 25.17 | 35.04 | 32.11 | 30.13 | 4.70 | 4.47 | 4.96 | | 12VAL | 30.97 | 27.48 | 24.39 | 32.97 | 29.60 | 26.54 | 2.00 | 2.12 | 2.16 | | 13ASP | 31.14 | 27.77 | 25.13 | 34.58 | 31.26 | 29.05 | 3.44 | 3.49 | 3.92 | # 4. Linearity/Amplification Efficiency as a Function of DNA Input (Part 1) The linearity and amplification efficiency of PCR for each mutation reaction, relative to the control reaction, across the working range of the KRAS Kit was demonstrated. Amplification efficiency was calculated for each of the mutation reactions and the control reaction as [2(-1/slope)]-1. The largest difference in the amplification efficiencies between the Control reaction and a mutant reaction was observed for the 13ASP (mean difference in efficiencies approximately $14.5\%$ ). The amplification efficiency of the control relative to the mutant reactions is consistent across the working range of the assay as shown in the Table below. PCR Amplification Efficiencies (Part 1) | | | | Intercept | Intercept Standard Error | Calculated Slope | Standard Error (slope) | Two-Sided 95% CI (slope) | Amplification Efficiency | Difference in Amplification Efficiencies | | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | | Sample | 12ALA | Control Ct | 21.06 | 0.060 | -1.008 | 0.007 | -1.023, -0.993 | 0.989 | 0.03 | | | | 12ALA Ct | 22.48 | 0.103 | -0.987 | 0.013 | -1.013, -0.961 | 1.019 | | | | 12ASP | Control Ct | 20.82 | 0.083 | -1.035 | 0.01 | -1.056, -1.014 | 0.954 | 0.056 | | | | 12ASP Ct | 23.24 | 0.083 | -0.993 | 0.011 | -1.016, -0.97 | 1.01 | | | | 12ARG | Control Ct | 20.38 | 0.13 | -1.013 | 0.016 | -1.046, -0.98 | 0.982 | -0.003 | | | | 12ARG Ct | 21.35 | 0.065 | -1.015 | 0.008 | -1.032, -0.999 | 0.979 | | | | 12CYS | Control Ct | 23.43 | 0.063 | -0.981 | 0.01 | -1.003, -0.96 | 1.026 | 0.032 | | | | 12CYS Ct | 24.29 | 0.039 | -0.961 | 0.006 | -0.974, -0.947 | 1.058 | | | | 12SER | Control Ct | 22.57 | 0.050 | -1.003 | 0.008 | -1.02, -0.986 | 0.996 | 0.105 | | | | 12SER Ct | 25.21 | 0.087 | -0.934 | 0.014 | -0.963, -0.904 | 1.101 | | | | 12VAL | Control Ct | 21.21 | 0.047 | -0.995 | 0.006 | -1.007, -0.983 | 1.007 | 0.033 | | | | 12VAL Ct | 21.53 | 0.043 | -0.972 | 0.005 | -0.983, -0.961 | 1.04 | | | | 13ASP | Control Ct | 23.21 | 0.056 | -1.001 | 0.009 | -1.02, -0.982 | 0.999 | 0.145 | | | | 13ASP Ct | 26.47 | 0.106 | -0.909 | 0.017 | -0.945, -0.873 | 1.144 | | {15} # 5. Linearity/Amplification Efficiency as a Function of %Mutation (Part 2) The objective of this study was to evaluate the linearity of each mutant reaction across the working range of the assay, when the total amount of DNA is held constant but the percentage of mutant DNA is varied. DNA extracts from FFPE cell lines were initially assessed by OD readings prior to carrying out PCR with the KRAS Kit. DNA stocks were then prepared to a Control Reaction Ct corresponding to $\sim 23$ Cts. The stocks were diluted serially 2 fold each time using wild-type DNA, in order to maintain the total wild-type DNA constant while varying the percentage mutant DNA in the template. Thus, each of the templates generated had the same absolute quantity and concentration of DNA but differing ratios of wild-type to mutant DNA. The dilutions and Target Ct values are shown below. Mean Control Reaction Ct Values for Each Dilution Point | Dilution (x100) | Assay | 12ALA | 12ASP | 12ARG | 12CYS | 12SER | 12VAL | 13ASP | | --- | --- | --- | --- | --- | --- | --- | --- | --- | | | | Target 22.75 | Target 22.75 | Target 22.75 | 23.17 | Target 23.00 | Target 22.75 | Target 23.5 | | 1 | control | 22.33 | 22.87 | 22.97 | 23.68 | 22.76 | 22.29 | 23.51 | | 0.5 | control | 22.42 | 22.71 | 22.98 | 23.45 | 22.98 | 22.60 | 23.75 | | 0.25 | control | 22.51 | 22.62 | 22.95 | 23.40 | 23.05 | 22.61 | 23.75 | | 0.125 | control | 22.54 | 22.62 | 22.90 | 23.36 | 23.11 | 22.65 | 23.65 | | 0.0625 | control | 22.55 | 22.66 | 22.90 | 23.29 | 23.08 | 22.67 | 23.64 | Pools of DNA sufficient for 6 replicates per mutation were prepared. The Ct and $\Delta \mathrm{Ct}$ data for each mutation at each dilution point were calculated. The control reaction Cts were consistent over the dilution series of each mutation. For each sample where the control reaction Ct value fell within the specified range (21.92 - 32.00), $\Delta \mathrm{Ct}$ values were calculated. A linear regression model was fitted with mutation reaction Ct versus $\log_2$ DNA input dilution. The slope and $95\%$ confidence intervals were reported. The study showed the dilution of mutations in a background of a constant concentration of wild type DNA resulted in amplification efficiencies that did not vary significantly outside the values determined in the above linearity study with the amplification efficiencies. PCR Amplification Efficiencies (Part 2) | | Intercept | Intercept (Std. error) | Slope | 95% CI (slope) | Amplification Efficiency | | --- | --- | --- | --- | --- | --- | | 12ALA | 23.5 | 0.025 | -0.968 | -0.989, -0.947 | 1.047 | | 12ASP | 24.8 | 0.054 | -1.030 | -1.075, -0.985 | 0.960 | | 12ARG | 24.2 | 0.028 | -1.008 | -1.031, -0.984 | 0.990 | | 12CYS | 24.4 | 0.027 | -0.981 | -1.003, -0.959 | 1.024 | | 12SER | 25.4 | 0.054 | -0.892 | -0.937, -0.847 | 1.174 | | 12VAL | 22.7 | 0.035 | -1.021 | -1.050, -0.992 | 0.972 | | 13ASP | 27.6 | 0.057 | -0.810 | -0.857, -0.763 | 1.353 | {16} 17 6. Analytical Specificity a) Primer and Probe Specificity The primers and probes have been designed to avoid any known K-Ras polymorphisms. A specificity analysis was conducted using the Basic Local Alignment Search Tool (BLAST) to ensure that the primers used in the therascreen® KRAS RGQ PCR Kit would amplify only human K-Ras sequences and not sequences from other species or to non-K-Ras human sequences (e.g., pseudogenes). No non-specific amplification is predicted from non-K-Ras genes. In addition, alignments of pairs of oligonucleotides (primers, probes, and templates) used in the KRAS Kit were performed to ensure there is no unexpected binding that could lead to non-specific amplification. There was no significant homology between the various reagents. b) Cross-Reactivity/Exclusivity The therascreen® KRAS RGQ PCR Kit is comprised of eight separate reactions; one single control reaction that detects a nonpolymorphic region of the K-Ras gene and seven mutation specific reactions. There is no reaction that specifically measures the wild-type K-Ras sequence at codon 12 or 13. The K-Ras mutation-negative result, (generally wild-type at codon 12 and 13) is determined from the absence of any of the 7 mutations resulting in a positive mutation result. Therefore it is necessary to demonstrate the amount of non-specific amplification, or cross-reactivity that occurs in each reaction with excess amounts of K-Ras wild-type DNA, to ensure no false positive results occur. Similarly, non-specific amplification of KRAS mutations for which the reaction is not intended to detect is evaluated to demonstrate that the amount of cross-reactivity between mutant reactions does not result in erroneous mutation calls in the presence of excess amounts of mutant DNA. Since the DNA input for this assay is based on the control Ct range (21.92 to 32.00), the highest concentration of DNA input is based on having a control Ct value of approximately 22. FFPE clinical samples were used for this evaluation, however due to the difficulty of obtaining DNA at the maximum input level, FFPE cell line DNA was also evaluated. Mutation status was confirmed by bi-directional sequencing. Non-Specific Amplification/Cross-Reactivity: Wild-Type K-Ras DNA: In order to address the amount of non-specific amplification of wild-type (WT) DNA by reaction mixes designed to amplify specific mutations, sixty (60) replicates of WT FFPE cell line DNA, or DNA extracted from CRC tumor tissue at the highest concentration of amplifiable DNA input level, was evaluated using the KRAS Kit. For DNA extracted from FFPE cell line the Control Ct values were approximately 22-23. Control Ct values for three wild-type CRC samples were between 24 and 25. The results demonstrated that the $\Delta$ Ct Values exceeded the established cut-offs. The mean and/or lowest $\Delta$ Ct values observed for each reaction is shown below. {17} Lowest Mean $\Delta C_t$ Observed for Wild type samples in Mutant Reactions | | | WT FFPE cell line | WT Clinical CRC Samples | | | | --- | --- | --- | --- | --- | --- | | Mutant Reaction | Cut-off | Lowest $\Delta C_t$ Observed | Sample 1 $\Delta C_t$ Mean (Lowest) | Sample 2 Mean (Lowest) | Sample 3 Mean (Lowest) | | 12ALA | 8 | 12.76 | 18.00 (11.40) | 18.62 (11.50) | 20.03 (19.36) | | 12ASP | 6.6 | 10.35 | 10.90 (9.62) | 10.34 (8.84) | 10.68 (9.01) | | 12ARG | 8 | 14.26 | 20.33 (12.94) | 20.02 (13.20) | 20.03 (19.36) | | 12CYS | 8 | 13.66 | 20.62 (17.38) | 20.29 (19.62) | 20.03 (19.36) | | 12SER | 8 | 11.97 | 17.26 (11.14) | 17.90 (11.42) | 18.05 (10.44) | | 12VAL | 7.5 | 11.81 | 14.87 (11.46) | 16.27 (11.50) | 18.68 (11.36) | | 13ASP | 7.5 | 10.94 | 12.35 (9.08) | 13.68 (10.69) | 14.82 (9.97) | ## Non-Specific Amplification/Cross-Reactivity/Exclusivity: Mutation-Positive K-Ras DNA: The exclusivity of the KRAS Kit is intended to discriminate between mutation negative and mutation positive status. Mutant samples that have a high concentration of input DNA were tested against all reaction mixes by preparing DNA samples from each of the FFPE cell lines so that the Control Reaction Ct corresponded to approximately 23. Six (6) replicates of each mutation sample were evaluated. The percentage of mutation in the sample was governed by the percentage of mutant in the cell line DNA. The mean $\Delta C_t$ are presented in the table below and demonstrates that there is cross reactivity between mutant reactions when high concentrations of DNA are evaluated. The 12ALA mutation was amplified and generated $\Delta C_t$ values below the $\Delta C_t$ thresholds for the 12CYS, 12SER and 12VAL reactions. The 12VAL mutation was amplified and generated a $\Delta C_t$ value below the $\Delta C_t$ threshold for the 12ALA reaction, however in all cases, the results demonstrate that the correct mutation was called with the matched mutation reaction (i.e., the smallest $\Delta C_t$ value was the correct mutation call). All other test cases were either not detected or outside the $\Delta C_t$ threshold. Cross-Reactivity Between Mutation Reactions Using FFPE Cell Line DNA$^{(1)}$ | | ΔCt Cut-Off | Mutant Reaction ΔCt Values | | | | | | | | | --- | --- | --- | --- | --- | --- | --- | --- | --- | --- | | | | 12ALA | 12ASP | 12ARG | 12CYS | 12SER | 12VAL | 13ASP | | | Mutant DNA | 12ALA | 8 | 1.42 | 12.66 | - | 5.81 | 2.78 | 6.31 | 13.21 | | | 12ASP | 6.6 | 12.56 | 2.42 | - | - | 13.44 | 11.21 | 13.55 | | | 12ARG | 8 | 13.12 | 11.56 | 1.12 | 11.42 | - | 13.43 | 12.66 | | | 12CYS | 8 | 14.2 | 12.48 | 9.23 | 0.98 | - | 7.96 | 12.88 | | | 12SER | 8 | - | 13.39 | 13.31 | - | 3.02 | 12.99 | 13.97 | | | 12VAL | 7.5 | 6.83 | - | - | - | 13.38 | 0.28 | 13.74 | | | 13ASP | 7.5 | - | 13.29 | 13.89 | - | - | 14.36 | 4.5 | (1) $\Delta C_t$ from matched reactions are shown in bold. Blank cells show no cross-reaction. $\Delta C_t$ from cross-reactive reactions below the cut-off are shaded. {18} 19 7. Interference Effects - Necrotic Tissue To support the performance of the KRAS Kit with tissues with high necrosis, the accuracy of the KRAS Kit for 29 samples with greater than 50% necrosis as determined by a pathologist was evaluated. The KRAS Kit did not falsely detect any mutations in the 21 samples identified as wild-type by bi-directional sequencing. The KRAS Kit correctly called 7 of the 8 K-Ras mutant samples. One sample was invalid due to inadequate DNA in the sample. The results support the use of the KRAS Kit with samples with high necrosis. 8. Interference Effects - Exogenous Substances To evaluate the impact of interfering substance on performance of the KRAS Kit, potentially interfering substances present in the DNA extraction process, were tested at 10x concentration in mutant and wild-type samples with a target Ct value between 27 and 30. The impact of each substance on the ΔCt values and mutation status of the samples was assessed. The substances tested were (1) paraffin wax, (2) xylene, (3) ethanol, and (4) Proteinase K. The difference between the ΔCt of samples with interferent was compared to samples without interferent according to statistical methods outlined in CLSI guidance document EP7-A2. For mutant samples, of the 448 replicates tested (7 mutations x 8 substances x 2 levels X 4 replicates) there were 8 invalid or indeterminate results and 4 false mutation negative results. For wild type samples, 3 of the 448 replicates tested were invalid or indeterminate and 2 false mutation positive results. The results demonstrated that there was no significant interference. 9. Reproducibility The repeatability and reproducibility of the KRAS Kit was investigated by testing DNA extracted from 8 FFPE CRC tissue blocks representing the 7 K-Ras mutations and one wild-type (WT) K-Ras specimen, at three sites with 2 operators at each site across 5 non-consecutive days in duplicate. The study consisted of two-parts: within-laboratory and between-laboratory. Multiple 5-μm sections were cut from each of the blocks and mounted onto glass slides. DNA was extracted using the QIAGEN® QIAamp® DSP DNA FFPE Tissue Kit, pooled and diluted to produce stocks of the same concentration of amplifiable DNA based on target control Ct values. Aliquots of mutant DNA stocks were diluted with WT stock to produce individual DNA samples at the targeted Ct levels representing approximately 3 times the LoD and at the cut-off. (The cut-off sample tested was one that was designed to investigate the variance directly at the cut-off.) The total set consisted of 21 samples; 7 mutation-positive samples at 3xLoD, 7 mutation-positive samples at the cut-off (i.e., at ΔCt cut-off to investigate variance at the cut-off), and 7 wild-type samples. The within-laboratory precision was determined from a series of 20 runs evaluating both dilution levels and a duplicate on each run resulting in 40 replicates per sample (2 operators and 5 non-consecutive days). Between-laboratory reproducibility was evaluated at two additional sites using 2 operators and 5 non-consecutive days in duplicate resulting in 10 runs and 20 duplicates per sample. Three lots were used in this evaluation. The proportion of correct {19} mutation call of 3xLoD samples testing mutant and WT samples were reported. The estimated proportion of 3xLOD samples testing mutant and WT samples were reported overall and within each of the sites. For all assays and sample combinations, at least 79 out of 80 replicates gave the correct mutation call. The overall proportion of correct calls was $99.6\%$ (1115/1120); $99.6\%$ (558/560) for mutation-positive (3xLOD) samples and $99.5\%$ (557/560) for wild-type samples. Proportion of Correct Calls by Assay for Mutation positive and Wild-type samples | Mutant 3X LoD Specimens (Target Control Ct approximately 30) | | | | | | | | --- | --- | --- | --- | --- | --- | --- | | 12ALA | 12ARG | 12ASP | 12CYS | 12SER | 12VAL | 13ASP | | 79/80 | 80/80 | 80/80 | 79/80 | 80/80 | 80/80 | 80/80 | | Wild-Type Specimen | | | | | | | | 80/80 | 79/80 | 80/80 | 80/80 | 79/80 | 79/80 | 80/80 | Variation (i.e., consistency in calling) was also measured using the GINI index calculated over all laboratories as detailed in the table below. The GINI index measures the variation or consistency in call response. A GINI index of zero (0) means total consistency (i.e., all responses in one single category) while a GINI index of half (0.5) means maximum inconsistency (i.e., the calls are spread equally across the two categories). The results of the GINI analyses when applied to the calls achieved for the 3xLOD and wild-type samples demonstrated very high consistency with the GINI indices over all laboratories less than 0.025 for all assays. Variance components analyses (random effects models) were used to generate estimates of reproducibility in terms of $\Delta \mathrm{Ct}$ and Ct values. The $\%$ CV for the $\Delta \mathrm{Ct}$ and Ct values for each reaction per sample below. Reproducibility Precision Estimates | Assay | %CV for ΔCt | | %CV for Mutant Ct | | %CV for Control Ct | | | | --- | --- | --- | --- | --- | --- | --- | --- | | | 3xLOD | C50 | 3xLOD | C50 | 3xLOD | C50 | WT | | 12ALA | 13.14 | 8.32 | 1.87 | 2.02 | 0.97 | 1.12 | 1.12 | | 12ARG | 10.79 | 8.04 | 1.59 | 1.96 | 1.24 | 1.51 | 1.15 | | 12ASP | 12.86 | 5.87 | 1.11 | 1.00 | 0.90 | 0.90 | 1.04 | | 12CYS | 17.61 | 10.83 | 1.86 | 2.02 | 1.54 | 1.22 | 1.15 | | 12SER | 13.97 | 10.43 | 1.71 | 2.11 | 0.94 | 1.19 | 1.15 | | 12VAL | 9.66 | 15.47 | 1.52 | 1.65 | 1.11 | 3.74 | 1.26 | | 13ASP | 13.73 | 9.35 | 1.91 | 2.08 | 1.11 | 1.41 | 1.19 | {20} Repeatability Precision Estimates | Assay | %CV for Delta Ct | | %CV for Mutant Ct | | %CV for Control Ct | | | | --- | --- | --- | --- | --- | --- | --- | --- | | | 3xLOD | C50 | 3xLOD | C50 | 3xLOD | C50 | WT | | 12ALA | 10.71 | 7.51 | 1.69 | 1.76 | 0.77 | 0.90 | 0.79 | | 12ARG | 9.83 | 8.04 | 1.21 | 1.76 | 0.84 | 1.33 | 0.90 | | 12ASP | 10.16 | 4.08 | 0.93 | 0.89 | 0.80 | 0.76 | 0.76 | | 12CYS | 13.15 | 8.80 | 1.31 | 1.76 | 1.40 | 1.01 | 0.76 | | 12SER | 6.76 | 6.18 | 1.10 | 1.48 | 0.80 | 0.90 | 0.90 | | 12VAL | 9.21 | 15.32 | 1.40 | 1.42 | 0.91 | 3.49 | 0.94 | | 13ASP | 8.67 | 7.01 | 1.30 | 1.65 | 0.91 | 1.19 | 0.97 | # 10. Sample Handling Variability Across Three Sites (Extraction Study) To assess sample handling variability as part of the KRAS Kit test system process, 30 sequential $5 - \mu \mathrm{m}$ sections were cut from each of 10 FFPE CRC samples (3 WT and 1 per mutation). Sections were randomized to one of three testing sites so that each site received 10 sections per FFPE sample (100 sections total). Of the 300 DNA extractions tested, 298 samples were valid. There was $99.3\%$ concordance with respect to the K-Ras mutation calls between the three sites. The variance of $\Delta C_t$ values for each assay was estimated, and the contribution of between and within laboratory sources was estimated using an ANOVA variance components model. Variance for within-test site was highest for 12ASP (0.30). Variance between-test site was highest for 12SER (0.05). A comparison by site of mean $\Delta C_t$ values with corresponding SD for mutant and wild-type samples showed very close agreement for results. The results demonstrate the agreement of the DNA extraction procedure and sample processing in conjunction with the KRAS Kit. Comparison by Site of Mean $\Delta$ Ct (SD) Values for Mutant Type Samples | | 12ALA | 12ARG | 12ASP | 12CYS | 12SER | 12VAL | 13ASP | | --- | --- | --- | --- | --- | --- | --- | --- | | CLA | 2.44 (0.1) | 2.62 (0.3) | 3.03 (0.6) | 2.24 (0.1) | 2.34 (0.3) | 2.51 (0.1) | 3.93 (0.4) | | HGX | 2.44 (0.2) | 2.52 (0.4) | 3.01 (0.7) | 2.29 (0.2) | 2.10 (0.4) | 2.44 (0.5) | 4.15 (0.7) | | MAN | 2.67 (0.6) | 2.52 (0.2) | 3.07 (0.5) | 2.29 (0.2) | 2.74 (0.5) | 2.56 (0.2) | 3.95 (0.3) | Comparison by Site of Mean $\Delta$ Ct (SD) Values for Wild-Type Samples | | 12ALA | 12ARG | 12ASP | 12CYS | 12SER | 12VAL | 13ASP | | --- | --- | --- | --- | --- | --- | --- | --- | | CLA | 12.46 (0.3) | - | 10.37 (0.4) | - | 11.84 (0.4) | 12.36 (0.5) | 11.11 (0.6) | | HGX | 12.09 (0.6) | 13.07 (0.2) | 10.17 (0.5) | - | 11.71 (0.7) | 12.20 (0.6) | 11.00 (0.9) | | MAN | 12.07 (0.2) | - | 10.61 (0.4) | - | 11.94 (0.3) | 12.28 (0.6) | 11.82 (0.5) | | Note: “-” illustrates a missing value, due to no break through being observed | | | | | | | | {21} 22 ## 11. Specimen Handling – Minimum Tumor content and Macrodissection To support the consistent mutation calling in macrodissected CRC samples with tumor proportion ≤ 20%, DNA extracted from thirteen samples whose tumor proportion ranged from 3% to 18% were either macrodissected or not. The samples were tested in duplicate. The overall accuracy of the macrodissected samples was compared to the non-macrodissected counterparts as well as ten samples whose tumor proportion was &gt; 20% but close to the cut-off (range 21% to 30%). All results were compared to bi-directional sequencing which were also macrodissected to enrich for tumor. The KRAS Kit did not incorrectly detect a mutation in six (6) samples identified as wild-type by bi-directional sequencing in either the macrodissected and non-macrodissected sections. One (1) wild-type sample produced invalid results with the KRAS Kit across all replicates. Four (4) samples identified as mutant by bi-directional sequencing were also identified as mutant by the KRAS Kit. One (1) mutant positive sample by bi-directional sequencing was correctly detected by the KRAS Kit when the sample was macrodissected but not when the sample was not macrodissected, supporting the use of macrodissection. One sample produced inconclusive results by bi-directional sequencing. The results support the ability of the KRAS Kit to detect mutant in samples with low percentage tumor when the specimen is macrodissected. Additionally, sections from the specimens used in the correlation to bi-directional sequencing studies had tumor proportion (% tumor content) that spanned the range of approximately 10% to 99%. The accuracy results support the use of samples whose tumor proportion is greater than 20% without macrodissection. ## 12. Lot-to-Lot Reproducibility The potential for lot-to-lot variability to impact the mutation detection was assessed. In this study, three lots of QIAamp® DSP DNA FFPE Tissue Kit (FFPE Extraction Kit) and therascreen® KRAS RGQ PCR Kit with each lot of FFPE Extraction were evaluated. An overview of the workflow for this study is shown below: {22}  For this study, five FFPE CRC specimens (FFPE CRC) for six of the seven mutations, plus five wild-type (WT) samples, were obtained. Only two FFPE CRC specimens were available for the 12ARG mutation, so these studies were supplemented with one 12ARG FFPE cell line. For each mutant sample (except for the 12ARG mutation) and the WT Sample, twelve sequential $5 - \mu \mathrm{m}$ sections were cut and mounted onto glass slides. For the 12ARG mutation, twenty-four sections were cut from each of the two 12ARG FFPE Samples and twelve sections were cut from the FFPE Cell Line for 12ARG. Thus a total of 60 sections per mutation and WT were obtained. These 60 sections were randomly assigned to one of three batches, to give three batches of twenty slides per mutation and WT. DNA was extracted and each extracted DNA sample was tested using the control reaction and its corresponding mutation reaction. Each DNA extract was tested singly on three separate KRAS Kit runs. The acceptance criterion for this study was that for each of the mutation assays and the three FFPE Kit Lots tested, the proportion of correct mutation calls would be at least 59/60. All samples met the acceptance criteria with the exception of 12SER and 12VAL, the latter of which was found to be due to reasons unrelated to the kits. To ensure quality across lots, a supplemental study was conducted using FFPE cell lines (one wild type and 7 mutant samples were extracted with 3 lots of FFPE Extraction Kit to yield DNA samples with target control CT values that span the range of total DNA input level for the KRAS Kit. The extracted DNA samples were then tested against 3 lots of KRAS Kit using the strategy outlined above. {23} The mutation status for all samples tested with the different FFPE extractions kit lots and KRAS Kit lots was 100% correct. For the mutant samples, the respective ΔCt value and the corresponding mutation status were calculated. The mutation status for all samples tested with the different FFPE extractions kit lots and KRAS Kit lots was 100% correct. This study criteria was met and the results demonstrated that there is no significant variability between lots of QIAamp® DSP DNA FFPE Tissue kit (FFPE extraction kit) and lots of therascreen® KRAS RGQ PCR Kit. ## 13. Guard Band Studies The potential impact of using different proteinase K digestion times during the DNA extraction process as well as altering the RGQ PCR cycling parameters for the KRAS Kit were investigated. Changes were assessed for any potential effects on mutation reporting. The following studies were conducted to assess the robustness of the Extraction Kit and the KRAS Kit: **Proteinase K Digestion Times**: FFPE CRC specimens were used in the evaluation of different proteinase K digestion times on the potential to impact mutation calling using the KRAS Kit. The current proposed labeling for the KRAS Kit states that proteinase K digestion of samples should be carried out for 60 minutes. Therefore, in order to assess the robustness of this limit, FFPE samples representing the wild type and each of the 7 seven K-Ras mutations, detected by the KRAS Kit, were extracted using digestion times that bracket the stated time. Five time points were tested in total; 50, 55, 60, 65, and 70 minutes respectively. Six replicate extractions were carried out at each time interval. A total of 240 extractions were carried out (6 replicates x 5 time intervals x 8 FFPE CRC Samples). Across all assays, there was 1 replicate of 240 that resulted in a false negative at the 65 minute time point. The KRAS Kit PCR is robust to varying the Proteinase K digestion step by ±10 minutes, from the stated 60 minute digestion. **RGQ PCR Cycling Analysis**: Denaturing and annealing temperatures were investigated. Denaturing temperatures are required for the complete separation of target DNA strands and annealing temperature is required for the specific binding of primers prior to extension. The KRAS Kit cycling uses a denaturing temperature of 95°C and an annealing temperature of 60°C. The combined effect of altering each of these parameters was tested in 9 combinations (inclusive of the standard conditions). These combinations are presented in Table below. The KRAS Kit PCR is robust to varying the melting and annealing temperatures of up to ±1°C (in any combination). All mutation calls for each of the FFPE samples tested at 9 different combinations of cycling conditions returned a 100% correct mutation status. Changes in the cycling temperatures had no impact on the results of mutation status. 24 {24} 25 # Guard Band PCR Cycling Conditions | | Melting Temperature | | | | | --- | --- | --- | --- | --- | | | | 59°C | 60°C | 61°C | | Denaturing Temperature | 94°C | 94°C /59°C | 94°C/60°C | 94°C/61°C | | | 95°C | 95°C/59°C | 95°C/60°C | 95°C/61°C | | | 96°C | 96°C/59°C | 96°C/60°C | 96°C/61°C | PCR Set-up and Stability Times: The goal of the study was to determine the robustness of the therascreen KRAS RGQ PCR Kit to different temperatures for different periods of time before it the reactions are loaded on the MDx Instrument. Three parameters were tested in the study: 1. Stability of reaction mixes/Taq polymerase and Positive Control was assessed to determine the effect of time on the stability of reaction mixtures at room temperature in the event that some experiments take longer to set up than the stipulated 1 hour. The following times were tested: (1) 1 hour at room temperature, (2) 4.5 hours at room temperature or (3) 6 hours at room temperature. 2. The temperature of storage of the Rotor-Gene® Q (RGQ) tubes between start of PCR set up and start of the RGQ run was assessed to determine the effect of temperature on the stability of the reaction mixes/Taq with the DNA sample. Room temperature and 2-8°C were tested. 3. The time between start of PCR set up and start of the RGQ run was assessed to determine the stability of the reaction mixes/Taq with the DNA sample added. Tubes were kept for 1 hour, 2 hours, 7 hours or overnight (18 hours). The following samples were tested: (1) Positive Control - Sample guaranteed to give a Ct value within the acceptable range. (2) Wild type and 3X LOD samples - Samples aimed to challenge the assay (i.e., low positive Control). (3) No Template control - Negative Samples The impact of time and temperature on the performance of the KRAS Kit was assessed by comparing the Ct values generated for all samples across 11 experimental conditions (interchangeable times and temperatures described above). Each known mutation sample was tested with its appropriate reaction mix while the WT sample was tested with the Control reaction mix. Each assay was run in triplicate. The data demonstrates that pre- and post-setup, the KRAS Kit can be stored on the bench-top or at 4°C for sufficient periods of time to allow {25} customers flexibility in the working day. The times within which the KRAS Kit can be stored both for pre- and post-setup are detailed in the table below. Times within which the KRAS Kit can be stored for pre- and post-setup | Thaw Time | | Storage Temp after PCR setup | PCR Setup and Storage time | | --- | --- | --- | --- | | Minimum | Maximum | | | | 1 hour | 4.5 hours | Room Temperature | 7 hours | | 1 hour | 4.5 hours | 2-8°C | 18 hours | Note: PCR setup is to be performed at room temperature. 'Storage' refers to the time between completion of PCR setup and start of the PCR run on the RGQ platform. # 14. Cross-Contamination Studies were performed to demonstrate the absence of cross-contamination between test samples. Two FFPE cell lines were used for this study: one containing WT cells only, and the other containing cells harboring the 12ALA mutation. The 12ALA mutation was selected for this study because the 12ALA reaction is the most sensitive reaction in the KRAS Kit as determined in the analytical sensitivity studies, and therefore most prone to exhibit false positive results from contamination. Multiple serial $5 - \mu \mathrm{m}$ sections were prepared and mounted onto glass slides for testing. DNA was extracted and assayed using one lot of reagents and one RGQ instrument according to protocol. Each extract was tested in 7 replicates using input concentrations based on control Ct in the midrange (approximating Ct 26). The study consisted of ten test runs designed to investigate the potential for contamination both within and between runs. The 10 runs were divided between two sets (5 runs per set) where the sequence in which reagents are added to reaction wells differed; for set "a" the No Template Control preceded the positive control according to instructions for use, and for set "b" the No Template Control preceded the test sample to maximize the opportunity to detect cross-contamination. Results were summarized by Ct, $\Delta \mathrm{Ct}$ and call. The results demonstrated one invalid result from a WT sample replicate. No false positive results were detected. No false positive results were detected. The results of this study indicate no detectable contamination. # 15. Stability-Specimen # a) Clinical Specimen, Slide-Mounted To assess the stability of slides prepared from FFPE CRC tissue samples to determine limits of suitability for the KRAS Kit, ten $5 - \mu \mathrm{m}$ sections were cut from each of eight FFPE CRC specimens (one for each mutation and one wild-type), mounted onto glass slides, and stored in the dark at room temperature for four weeks. The acceptance criteria were that at each time point, the mutation status must agree with that determined at initial baseline testing, and for each time point the change in $\Delta C_t$ relative to the corresponding baseline time point must not be statistically different, or the {26} upper 95% CI for the absolute mean change ΔCt must be less than 1. For each time point tested, DNA was extracted from 2 slides, pooled and tested in 5 replicates on Day 7, Day 14 and Day 28. The wild-type slides met the stability criteria across all time points based upon consistent mutation status. Slides from 4 of the 7 mutations (12ALA, 12CYS, 12SER, and 12VAL) were demonstrated to meet stability criteria across all 4 time points. Slides from the 12ASP and 12ARG mutations met all acceptance criteria for all time points where valid results were obtained. No trend in the values was observed for the FFPE samples tested. The results of this study overall support the claim that slides prepared from FFPE samples can be stored for up to 4 weeks at room temperature in the dark prior to testing with the KRAS Kit. ## b) Extracted Clinical Specimen DNA To assess the stability of DNA extracted from FFPE CRC samples (representing 7 mutations and 1 wild-type) using the QIAamp® DSP FFPE Tissue Kit, samples were stored at 2°C to 8°C for 7 days followed by storage at -18°C to -22°C for 5 weeks. During storage at -18°C to -22°C, the samples were subjected to multiple freeze-thaw cycles. DNA extracts were freeze/thawed over 2 hours at room temperature and then returned to freezer. DNA extracts were tested on days 14, 21, and 35. Five test replicates of all DNA extracts at each time point were evaluated. The acceptance criteria were that the upper limit of the 95% CI cannot exceed the baseline value by more than 1ΔCt). Determination of mutation status was demonstrated to be consistent under the conditions of the study. There was 1 replicate that resulted in false positive call that was attributed to human error. The acceptance criteria were met. DNA extracted from FFPE samples is stable and suitable for use with the KRAS Kit when stored for up to 7 days at 4°C with additional storage at -20°C up to 5 weeks with multiple freeze thaws. ## 16. Stability-Reagents The Stability studies conducted for both the therascreen® KRAS RGQ PCR Kit and the QIAamp DSP DNA Extraction Kit include (1) Real-time storage conditions for closed bottle conditions, open bottle, and open bottle simulating multiple time use by the user for both the KRAS Kit and the Extraction Kit; (2) Transport conditions (extreme temperatures during storage and shipping, including inversion of reagents), and (3) Stress (freeze/thaw) conditions. FFPE CRC clinical samples and FFPE cell lines were used for this investigation. DNA was extracted according to protocol and each mutation DNA extract was normalized with wild-type DNA to provide test samples corresponding to 3x and 9x the LoD of each of the 7 mutation reactions. Testing was conducted in triplicate with the exception of the open-bottle (multi-use studies) which is run in singleicate. The acceptance criteria for each time point are that (1) the correct call is made, and (2) the ΔCt values of each sample, when plotted against time, do not indicate a statistically significant trend following regression analysis. Testing was conducted at 4 months and is planned to continue to 36 months for the KRAS Kit 27 {27} and 24 months for the Extraction Kit. Freeze thaw studies up to 4 months were conducted 12 times. The data supports the following stability claims: - Storage and shelf life for the KRAS Kit is 4 months at $-20^{\circ}\mathrm{C} \pm 5^{\circ}\mathrm{C}$ - When used with this assay and the modified protocol, storage and shelf life for the QIAamp kit is 4 months at ambient temperature at $15^{\circ}\mathrm{C}$ to $25^{\circ}\mathrm{C}$ except for QIAamp MinElute Columns $(5^{\circ}\mathrm{C} \pm 3^{\circ}\mathrm{C})$ . Overview of the Stability Studies and Temperatures | Study* | Storage condition | | Cycling condition | | | --- | --- | --- | --- | --- | | | definition | temperature | definition | temperature | | Closed bottle | Real time | -20°C±5°C | n.a. | n.a. | | Open bottle | Real time | -20°C±5°C | n.a. | n.a. | | Open bottle (light sensitivity) | Ambient temperature | 22°C±3°C (Incubator) | n.a. | n.a. | | Transport simulation study KRAS kit | Real time | -20°C±5°C | Extreme cold | -90°C to -65°C | | | | | Interim storage | -20°C±5°C | | | | | Thawing | 22°C±3°C*** | | | | | Freezing | -20°C±5°C | | Transport simulation study QIAamp kit | Real time | 25°C±3°C (incubator) | Extreme cold | -20°C±5°C | | | | | Extreme warm | 45°C±3°C | | Stress test | Real time | -20°C±5°C | Thawing | 22°C±5°C*** | | | | | Freezing | -20°C±5°C | * QIAamp kit stored at $(25^{\circ}\mathrm{C} \pm 3^{\circ}\mathrm{C},$ incubator), QIAamp MinElute Columns at $(5^{\circ}\mathrm{C} \pm 3^{\circ}\mathrm{C})$ . The cycling for the transport simulation studies performed with all kit components including the QIAamp MinElute columns. *** Tubes are inverted. Stability- Open bottle study (light sensitivity/ reaction mix + enzyme stability): Master mixes were prepared (Reaction mix + enzyme) in clear tubes and used at predefined times following preparation up to 3 hours. The results indicate that KRAS Kit Master Mix is stable for at least two hours when stored at $32^{\circ}\mathrm{C}$ . # B. Animal Studies None. # C. Additional Studies None. {28} 29 # X. SUMMARY OF PRIMARY CLINICAL STUDIES A clinical performance study was conducted to generate data to support the clinical utility of the therascreen® KRAS RGQ PCR Kit (referred to as KRAS Kit) as a companion diagnostic test that aids in the identification of patients for treatment with cetuximab (Erbitux®). The objective of the study was to assess whether K-Ras status as determined by the therascreen KRAS RGQ PCR Kit can be used to select patients with metastatic colorectal cancer (mCRC) who will benefit from cetuximab treatment. CA225025 (ClinicalTrials.gov number NCT00079066) was a randomized, multicenter, open-label, Phase 3 study of cetuximab combined with best supportive care (BSC) versus BSC alone in patients with previously treated, epidermal growth factor receptor (EGFR) - expressing, recurrent or metastatic colorectal cancer (mCRC). The study was conducted by the National Cancer Institute of Canada Clinical Trials Group (NCIC CTG). Banked tumor samples from patients in study CA225025 were tested with the KRAS Kit to identify two subgroups: K-Ras mutation-positive and K-Ras mutation-negative (wild-type), according to whether at least one or none of seven K-Ras mutations in codons 12 and 13 of exon 2 in the K-Ras oncogene was detected. In retrospective analyses, efficacy data from study CA225025 were stratified by K-Ras subgroup. **Note:** The KRAS Kit is designed to specifically detect 7 K-Ras mutations in codon 12 and 13 of the K-Ras gene. It is not designed to specifically detect the wild-type sequence at these codons. The results of the test are reported out as “Mutation-positive” and “No mutation detected.” Generally, discussions of patient response to cetuximab therapy in the context of K-Ras status have referred to two groups; K-Ras wild-type and K-Ras mutant. In the report that follows, the therascreen “no mutation detected” result is referred to as K-Ras mutation-negative (wild-type) to be consistent with the pharmaceutical manufacturer’s designations in the cetuximab product label. Patients in the clinical study who were K-Ras mutation-positive tested positive for one or more of the 7 mutations detected by the therascreen KRAS RGQ PCR Kit (G12A, G12D, G12R, G12C, G12S, G12V, G13D). Patients in the clinical study who were K-Ras mutation-negative (wild-type) tested negative for the 7 mutations detected by the therascreen KRAS Kit. However they may have harbored mutations in the K-Ras gene not identified by the KRAS Kit such as 13CYS, or elsewhere in the gene such as codon 61). The data presented in this PMA support the clinical utility of the therascreen KRAS RGQ PCR Kit and support corresponding changes to the cetuximab (Erbitux®) labeling for the mCRC indication. The results demonstrated that the efficacy of cetuximab in prolonging overall survival (OS) and progression-free survival (PFS) was statistically significant in patients with K-Ras mutation-negative (wild-type) status. In patients with K-Ras mutation-positive tumors, no statistically significant difference was observed between the two treatment groups in OS or PFS. {29} 30 A. Study Design 1. CA225025 Trial CA225025 was initiated on August 28, 2003 and closed to randomization on August 26, 2005 after 572 patients were randomized to either cetuximab + BSC or BSC alone. Randomization was stratified by center and Eastern Cooperative Oncology Group (ECOG) performance status (PS) (0 or 1 vs. 2). The study was open label, i.e., patients and investigators were not blinded to treatment assignment. Investigators at 30 centers in Canada and 28 centers in Australia, New Zealand, and Singapore enrolled at least 1 patient. Cetuximab was administered on a weekly dosing schedule until disease progression or until other conditions including unacceptable toxicity, symptomatic disease progression, and need for standard radiation treatment for index lesions, led to discontinuation from protocol treatment. The study was completed on March 6, 2006. An application to the FDA (CDER) in support of this indication was approved on October 2, 2007 (BLA 125084). The study demonstrated a clinically relevant and highly significant improvement in overall survival (OS), as well as longer progression-free survival (PFS) and higher overall response rates. Assessment of K-Ras mutation status was not prospectively planned in the original protocol for the CA225025 study because evidence for the impact of K-Ras mutation on therapeutic response was unavailable at the time. However, based on emerging data demonstrating K-Ras mutation status as a potential predictive biomarker for EGFR-targeted monoclonal antibody therapies, available tumor samples from patients in the CA225025 study were tested using bidirectional sequencing to investigate if K-Ras status predicted patient response to cetuximab treatment (1). The results are the basis for the development of planned, retrospective analyses evaluating the influence of K-Ras mutation status on OS and PFS with a specific KRAS companion diagnostic (i.e., the KRAS Kit). 2. Patients Patients were males and females who were at least 16 years of age and had EGFR positive colorectal cancer tissue and an ECOG PS of 0 to 2. All patients were individuals who had failed all available chemotherapeutic agents, including an irinotecan-containing regimen and an oxaliplatin-containing regimen, for treatment of metastatic disease, and for whom no standard anticancer therapy was available. The only remaining standard available therapy as recommended by the investigator was BSC. 3. Tumor Specimens and Testing Tumor tissue blocks and sections were collected prior to enrollment in CA225025. The median age of sample at testing was close to 8.5 years. Tumor samples were mostly from primary tumor specimens (~90%). However, a small number of samples were derived from metastatic lesions. The average tumor content was close to 50% and less than 10% of the samples required macrodissection. Most patients (~81%) had necrosis scored on the tumor sample. {30} Tissue reserves were in the form of formalin-fixed paraffin embedded (FFPE) blocks or unstained slides containing sections from FFPE blocks. HistoGeneX laboratories (Antwerp, Belgium) performed the K-Ras evaluations using the KRAS Kit without knowledge of the subject’s site, identification number, or clinical outcome, including tumor response. For all CA225025 subjects with sufficient tissue reserves, 5-micron sections adhered on glass slides underwent fresh hematoxylin and eosin (H&amp;E) staining and pathologist verification to make determinations regarding necrosis and tumor content in sample prior to K-Ras assessment using the KRAS Kit. When tumor content was deemed $\leq 20\%$ in H&amp;E stained sections, the pathologist marked tumor borders to facilitate macro-dissection of tumor tissue from 1 or more 5-micron sections for a total area of $\geq 4$ mm² tumor in accordance with the KRAS Kit labeling recommendations. Descriptive information about the tumor samples was collected and summarized across the treatment arms and by K-Ras status for the purpose of evaluating the potential for bias in the analyses. A summary of the information is provided below. 31 {31} | | FRAS Wild-type | | FRAS Mutant | | | --- | --- | --- | --- | --- | | | C+BSC N = 117 | BSC N = 128 | C+BSC N = 108 | BSC N = 100 | | Age of sample at testing, years N | 104 | 107 | 93 | 88 | | Median | 8.7 |…