therascreen EGFR Plus RGQ PCR Kit

For detection and identification of 42 mutations in exons 18, 19, 20 and 21 of the EGFR gene

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therascreen EGFR Plus RGQ PCR Kit (24)

Cat. No. / ID: 874611

For 24 reactions: T790M & L861Q Mix, Insertions & G719X Mix, L858R & C797S Mix, Deletions & S768I Mix, PCR Master Mix, EGFR Positive Control, RNase/DNase-free Water

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ProductKitInstrumentSoftware

therascreen EGFR Plus RGQ PCR Kit (24)

QIAsymphony DSP DNA Mini Kit

Rotor-Gene Q MDx HRM

Rotor-Gene Q MDx HRM Platform

Rotor-Gene AssayManager

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The therascreen EGFR Plus RGQ PCR Kit is intended for in vitro diagnostic use.

✓ 24/7 automatic processing of online orders

✓ Knowledgeable and professional Product & Technical Support

✓ Fast and reliable (re)-ordering

Features

Detection of TKI resistance biomarkers, including T790M and C797S
Run FFPE and liquid biopsy samples in the same PCR run
Reliable, sensitive and specific detection of clinically relevant EGFR mutations
Automated sample preparation option with QIAsymphony SP
Automated analysis and next-day result reporting with Rotor-Gene Assay Manager software

Product Details

The therascreen EGFR Plus RGQ PCR Kit is an in vitro diagnostic real-time PCR test intended for the qualitative detection and identification of 42 mutations in exons 18, 19, 20 and 21 of the epidermal growth factor receptor (EGFR) gene in DNA samples extracted from plasma or formalin-fixed paraffin-embedded (FFPE) tumor tissue taken from non-small cell lung cancer (NSCLC) patients.

Furthermore, the kit also indicated for the semi-quantitative measurement of mutations in exons 18, 20 and 21 of the EGFR gene in DNA samples extracted from human plasma as an aid in the clinical management of NSCLC patients.

The test is intended to be used as an aid in selecting patients with NSCLC for therapy with an EGFR tyrosine kinase inhibitor (TKI).

Performance

When compared to the analytical reference method, there was a high level of concordance between therascreen EGFR Plus RGQ PCR Kit and the analytical accuracy method(s). The reference and discrepancy resolution methods used were: PNA qPCR, Sanger bi-directional sequencing; next-generation sequencing, therascreen EGFR RGQ PCR Kit V2 (cat. no. 874111) and therascreen EGFR Plasma RGQ PCR Kit (cat. no. 870311).

Results were analyzed to assess the positive percent agreement (PPA), negative percent agreement (NPA) and overall percent agreement (OPA) regarding EGFR mutation status (mutant; MT or wild-type; WT) and EGFR target (mutation identification) for FFPE and plasma samples between therascreen EGFR Plus RGQ PCR Kit and respective reference method and following discrepancy resolution method.

FFPE samples

In the study 170 FFPE samples were tested, of which 48 gave valid interpretable results (148 sample status and 155 target status).

When the results of the therascreen EGFR Plus RGQ PCR Kit were compared to the results of the respective reference method, four EGFR sample status (MT or WT) showed discordance. Following discrepancy resolution method analysis, the number of discordant samples statuses (MT or WT) decreased to one discrepant, false-negative sample status. The PPA, NPA and OPA with the corresponding two-sided 95% confidence intervals (CI) are summarized in Table 1 and Table 2.

Table 1. Analysis of agreement of overall mutation status per sample: therascreen EGFR Plus RGQ PCR Kit and reference method comparison for FFPE samples

		Lower limit 95% CI	Upper limit 95% CI
OPA	97.30%	93.22%	99.26%
PPA (sensitivity)	93.65%	84.53%	98.24%
NPA (specificity)	100.00%	95.75%	100.00%

Table 2. Analysis of agreement of overall mutation status per sample after discordant investigation for FFPE samples

		Lower limit 95% CI	Upper limit 95% CI
OPA	99.32%	96.29%	99.98%
PPA (sensitivity)	98.33%	91.06%	99.96%
NPA (specificity)	100.00%	95.89%	100.00%

Plasma samples

In the study, 106 plasma samples were tested and 106 gave valid interpretable results (106 sample status and 121 target status).

When the results of therascreen EGFR Plus RGQ PCR Kit were compared to the results of the respective reference method, nine EGFR sample status (MT or WT) showed discordance. Following discrepancy resolution method analysis, the number of discordant samples status (MT or WT) decreased to three discrepant, one false-negative, and two false-positive sample status. The PPA, NPA, and OPA with the corresponding two-sided 95% confidence intervals (CI) are summarized in Table 3 and Table 4.

Table 3. Analysis of agreement of overall mutation status per sample: therascreen EGFR Plus RGQ PCR Kit and reference method comparison for plasma samples

		Lower limit 95% CI	Upper limit 95% CI
OPA	91.51%	84.49%	96.04%
PPA (sensitivity)	87.27%	75.52%	94.73%
NPA (specificity)	96.08%	86.54%	99.52%

Table 4. Analysis of agreement of overall mutation status per sample after discordant investigation for plasma samples

		Lower limit 95% CI	Upper limit 95% CI
OPA	97.17%	91.95%	99.41%
PPA (sensitivity)	97.96%	89.15%	99.95%
NPA (specificity)	96.49%	89.89%	99.57%

Principle

The therascreen EGFR Plus RGQ PCR Kit comprises four triplex assays, each containing all the oligonucleotides (primers, probes and oligonucleotide clamp, where applicable) necessary to amplify and detect the targeted EGFR mutations. In each assay, two target mutations and one internal amplification control are assayed to determine the presence or absence of mutant DNA and to identify reaction failures due to suboptimal DNA input, or the presence of inhibitory substances in the sample matrix.

Allele-specific technology allows accurate and highly reproducible detection of mutations. DNA is selectively amplified using ARMS primers, probes and PCR clamps, with sensitive signal detection using the Rotor-Gene Q MDx 5plex HRM instrument. Result reporting is fully automated using Rotor-Gene AssayManager v2.1 software. If both the positive and no template controls are valid and the sample internal controls are valid, the EGFR mutation status will be displayed in the software.

Procedure

Flexibility is key to the therascreen EGFR Plus RGQ PCR System – with a choice of sample types and DNA extraction methods before real-time PCR.

DNA extraction from FFPE tissue or plasma samples can be performed manually or automated on the QIAsymphony SP, for walkaway sample processing. DNA is extracted from FFPE tissue samples manually using the QIAamp DSP DNA FFPE Tissue Kit, while automated processing uses the QIAsymphony DSP DNA Mini Kit. Plasma samples are processed manually using the QIAamp DSP Circulating Nucleic Acid Kit, while the QIAsymphony DSP Circulating DNA Kit offers automated DNA purification.

Following DNA extraction and quantification, sensitive real-time PCR is performed on the Rotor-Gene Q MDx 5plex HRM instrument. Automated data analysis displays qualitative results in Rotor-Gene AssayManager software, informing the system operator if one or more of the 42 mutations detected by the kit are present. The assay can be completed in ~8 hours, providing next-day results and informing earlier treatment decisions.

Applications

The therascreen EGFR Plus RGQ PCR Kit enables qualitative detection of 42 mutations in the EGFR gene for in vitro diagnostic use. It is an IVD assay to support treatment decisions when selecting NSCLC patients for therapy with an EGFR tyrosine kinase inhibitor (TKI).

Supporting data and figures

CE-marked.

Resources

For creation of Rotor-Gene AssayManager assay profiles (only available for the User Defined Test [UDT] mode)

For installation and setup of Rotor-Gene AssayManager

For use of Rotor-Gene AssayManager in User Defined Test (UDT) mode in combination with the UDT Basic Plug-in

For use with Rotor-Gene Q Software version 2.3.4

QIAsymphony DSP DNA Kit Performance Characteristics_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

DNA_Blood_200_V7_DSP protocol

QIAsymphony DSP DNA Kit Protocol Sheet_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

DNA_Buffy_Coat_200_V7 DSP protocol

QIAsymphony DSP DNA Kit Protocol Sheet_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

VirusBlood200_V5_DSP protocol

QIAsymphony DSP DNA Kit Protocol Sheet_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

Tissue_LC_200_V7_DSP and Tissue_HC_200_V7_DSP protocols

QIAsymphony DSP DNA Kit Protocol Sheet_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

For use with software version 4.0 or higher

QIAsymphony DSP DNA Kit Handbook_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

For verification of thermal accuracy of Rotor-Gene real-time cyclers

Tissue_LC_200_V7_DSP and Tissue_HC_200_V7_DSP; Version 2

Version 01

For use on the Rotor-Gene Q. Rotor-Gene Q software 2.3.5 is compatible with Windows 7 and Windows 10 operating systems.

QIAsymphony DSP DNA Kit Labware List_V2_In Vitro Diagnostic use according to the Regulation (EU) 2017/746 on in vitro diagnostics medical devices

For use with software version 5.0 or higher

FAQ

Please refer to section 'Guidelines for effective multiplex assays' under "Important Notes" in the Rotor-Gene Multiplex PCR Handbook for suitable combinations of reporter dyes, or visit our Multiplex real-time PCR Resource site for additional information.

FAQ ID -9028

Human plasma that has been collected in EDTA blood collection tubes or ccfDNA stabilized blood collection tubes can be used as sample material. In addition, human urine (non-stabilized or stabilized) can also be used.

Serum is not recommended as sample material because it contains a large background of genomic DNA.

FAQ ID - 3702

Reaction volumes suitable for use on the Rotor-Gene Q are:

Rotor-Disc 100: 30 µl x 100-wells, 10-25 µl reaction volume
Rotor-Disc 72: 0.1 ml x 72-wells, 15-25 µl reaction volume
Strip Tubes 0.1 ml: 0.1 ml x 72-wells, 10-30 µl reaction volume, strips of 4 tubes and caps
PCR Tubes 0.2 ml: 0.2 ml x 36-wells, 15-50 µl reaction volume, individual tubes with caps

FAQ ID -9030

Tissue and FFPE tissue can be processed using the tissue protocols and the QIAsymphony DSP DNA Mini Kit on the QIAsymphony SP.

FAQ ID -2925

It is strongly advised to follow the recommendations for preparing sample material provided in the corresponding Protocol Sheet to ensure reliable results.

Plasma: It is recommended to perform plasma separation immediately after blood collection when using EDTA as anticoagulant to prevent the release of genomic DNA into the plasma fraction.

Urine: Because circulating cell-free DNA in non-stabilized urine samples is rapidly degraded after sample collection due to high nuclease activity, eluates may contain no DNA or exhibit low DNA concentration. Therefore, it is recommended to stabilize urine samples. Even when using stabilized urine, it is recommended to perform a centrifugation step immediately after stabilization to prevent the release of genomic DNA from cells. Alternatively, non-stabilized urine samples can be processed immediately after collection and centrifugation using ATL pretreatment and automated DNA extraction as described in the corresponding Protocol Sheet.

FAQ ID - 3699

Open reagent cartridges can be used for up to 4 weeks without affecting performance. After 4 weeks, circulating cell-free DNA yields are expected to decrease. To ensure the best performance, carefully seal buffer troughs of a partially used reagent cartridge with Reuse Seal Strips when not in use; incomplete sealing of reagent cartridge can reduce the performance.

FAQ ID - 3706

Tissue: If no information about the expected yield is available, we recommend starting with 25 mg sample material. Depending on the yield obtained, the sample size can be increased in subsequent preparations to a maximum of 50 mg.

FFPE: Up to 4 sections, each with a thickness of up to 10 µm, or 8 sections with a thickness of up to 5 µm and a surface area of up to 250 mm2, can be combined in one preparation.

FAQ ID -2927

At least 2.4 ml sample for the 2 ml protocol or 4.5 ml for the 4 ml protocol should be loaded.

Loading smaller volumes increases the risk of “unclear” flagged samples. As described in the corresponding labware list, volumes of 1.4–2.4 ml and 3.5–4.5 ml, respectively, will be processed but flagged “unclear” (“Enable less sample” mode).

Loading volumes less than recommended increases the risk that samples are not transferred (“invalid” flagging). If the sample volume is insufficient, add PBS to the required sample volume before loading the sample.

When using FIX labware (instrument does not perform liquid-level detection and reporting), load at least 2.1 ml for the 2 ml protocol and at least 4.1 ml for the 4 ml protocol. Because the instrument does not detect sample volumes using FIX labware, insufficient volumes might result in bubble formation during sample transfer and/or the subsequent binding step. If the sample volume is insufficient, add PBS to the required sample volume before loading the sample.

FAQ ID - 3701

Please make data are collected in the appropriate fluorescent channel. Also check the gain is optimized.

If the issue persists, please send the original run file with extension .rex to QIAGEN Technical Service for further assistance.

FAQ ID -9023

Sample volumes of 2 ml and 4 ml can be used without affecting the number of preps per kit (i.e., 192 samples per kit).

FAQ ID - 3700

After pretreatment, 220 µl of the lysates must be transferred to the QIAsymphony SP to ensure that 200 µl of sample is processed.

FAQ ID -2992

Please send the original OTV run file to QIAGEN Technical Service for further assistance.

FAQ ID -9022

Lysis time varies depending on the tissue type processed. For recommended lysis times refer to the tissue protocol sheets. If lysis is incomplete after recommended lysis time, as indicated by the presence of insoluble material or highly viscous lysates, lysis time can be prolonged or insoluble material can be removed by centrifugation. Overnight lysis is possible and does not affect the preparation.

FAQ ID -2993

For hardware related issues, please send the support package to QIAGEN Technical Service. Within the Rotor-gene Q software, click Help and select Send Support Email. In the new window, select the file that relates to the issue and email it to QIAGEN Technical Service.

FAQ ID - 9024

QIAGEN recommends the annual inspection service on Rotor-gene instruments, during which all application-critical modules of the Rotor-gene are inspected and tested and an OTV check is conducted. Performed tests and test results are documented in a GMP/GLP-compliant Report. In addition, the end users can perform the temperature calibration in the lab as needed using the Rotor-Disc OTV kit.

Note: The Rotor-Disc OTV kit requires the Rotor-Disc 72 Rotor and Rotor-Disc 72 locking ring.

FAQ ID -9025

Generation of size-distribution profiles for circulating cell-free DNA (ccfDNA) from eluates can be used to check the quality of fragmented ccfDNA and potential genomic DNA background. However, due to the limited sensitivity of these assays, they are not recommended for quantification of ccfDNA. Samples with low ccfDNA eluate concentration and, thus, low ccfDNA yields might exhibit no peak at approximately 165 bp in size-distribution profile results.

FAQ ID - 3705

Small amounts of RNA and DNA may be difficult to measure spectrophotometrically. Fluorometric measurements, or quantitative RT-PCR and PCR are more sensitive and accurate methods to quantify low amounts of RNA or DNA.

Fluorometric measurements are carried out using nucleic acid binding dyes, such as RiboGreen® RNA Quantitation Reagent for RNA, and PicoGreen® DNA Quantitation Reagent for DNA (Molecular Probes, Inc.).

FAQ ID -728

Tissues will give increased DNA yields when processed with the high content protocol, but the low content protocol in combination with a small elution volume (50µl) may be used if high DNA concentration is required. For FFPE tissue we recommend using the low content protocol.

FAQ ID -2989

Typically, a yield of 7.5 ng/ml plasma or urine can be expected. This yield results in <1 ng/µl eluate. However, the yield will vary from sample to sample, due to large donor-dependent variations in circulating cell-free DNA (ccfDNA) concentration in plasma: variation can be approximately 20-fold for healthy blood donors and 1000-fold for both clinical samples and urine.

Because of the very low concentrations of ccfDNA in sample materials (e.g., 0.1 ng/µl eluate is not unusual), measurement of DNA with a spectrophotometer is not recommended. A sensitive and accurate fluorescence-based quantitation assay or a real-time PCR assay should be used for ccfDNA-concentration determination.

FAQ ID - 3704

Yes. The DNA tissue protocols on the QIAsymphony SP purify genomic and mitochondrial DNA.

FAQ ID -2991

When an elution volume of 60 µl is selected, the instrument transfers 75 µl elution buffer to ensure that at least 60 µl eluate is available for downstream analysis. In most cases, the eluate volume is 60–70 µl, depending on temperature, humidity and how long the eluate remains on the instrument before being removed. To calculate total yield or recovery of an internal control, an elution volume of 75 µl should be used.

FAQ ID - 3703

Yes, all empty positions in the rotor of the Rotor-Gene Q have to be filled with empty tubes. This guarantees optimal temperature repartition in the Rotor-Gene Q chamber.

FAQ ID -9029