Targeted high throughput sequencing in clinical cancer Settings: formaldehyde fixed-paraffin embedded (FFPE) tumor tissues, input amount and tumor heterogeneity

Kerick, Martin; Isau, Melanie; Timmermann, Bernd; Sültmann, Holger; Herwig, Ralf; Krobitsch, Sylvia; Schaefer, Georg; Verdorfer, Irmgard; Bartsch, Georg; Klocker, Helmut; Lehrach, Hans; Schweiger, Michal R.

doi:10.1186/1755-8794-4-68

Cited by 166 publications

(152 citation statements)

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“…A recent study by Forshew et al 18 found a similar background frequency of nonreference base changes in 47 FFPE samples enriched by multiplex PCR. In another study, Kerick et al 21 reported a false-positive rate of 0.98% for SNV calls from low coverage (Â20) NGS data from FFPE tissue; the authors note, however, that the false-positive rate can be reduced with increased (> Â80) coverage. Although we detected differences in the spectrum of base changes in our FFPE data, including an increase in the frequency of transitions, the differences were small (0.041% of high-quality discrepancies in FFPE versus 0.035% in frozen samples), the overall frequency of discrepancies was not increased between sample A: Percentage of mapped, on-target, and unique reads for a single surgical resection specimen that was snap frozen (red) or subjected to 24-hour (light purple), 48-hour (medium purple), or 72-hour (dark purple) formalin fixation.…”

Section: Discussionmentioning

confidence: 99%

“…6,18e21 Prior work has suggested that deamination and other damage caused by fixation could account for as many as 1% of the SNV calls in low-coverage sequence data (eg, 20-fold coverage) and may skew the transition to transversion ratio in sequence data from FFPE tissue samples. 19,21 Although these studies have limitations, such as the use of cell lines and unrelated specimens as controls rather than paired fresh tissue, they raise the possibility that damage caused by fixation could result in erroneous clinical test results.…”

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confidence: 99%

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Comparison of Clinical Targeted Next-Generation Sequence Data from Formalin-Fixed and Fresh-Frozen Tissue Specimens

Spencer

Sehn

Abel

et al. 2013

The Journal of Molecular Diagnostics

179

156

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Next-generation sequencing (NGS) has emerged as a powerful technique for the detection of genetic variants in the clinical laboratory. NGS can be performed using DNA from FFPE tissue, but it is unknown whether such specimens are truly equivalent to unfixed tissue for NGS applications. To address this question, we performed hybridization-capture enrichment and multiplexed Illumina NGS for 27 cancerrelated genes using DNA from 16 paired fresh-frozen and routine FFPE lung adenocarcinoma specimens and conducted extensive comparisons between the sequence data from each sample type. This analysis revealed small but detectable differences between FFPE and frozen samples. Compared with frozen samples, NGS data from FFPE samples had smaller library insert sizes, greater coverage variability, and an increase in C to T transitions that was most pronounced at CpG dinucleotides, suggesting interplay between DNA methylation and formalin-induced changes; however, the error rate, library complexity, enrichment performance, and coverage statistics were not significantly different. Comparison of base calls between paired samples demonstrated concordances of >99.99%, with 96.8% agreement in the single-nucleotide variants detected and >98% accuracy of NGS data when compared with genotypes from an orthogonal single-nucleotide polymorphism array platform. This study demonstrates that routine processing of FFPE samples has a detectable but negligible effect on NGS data and that these samples can be a reliable substrate for clinical NGS testing. Next-generation sequencing (NGS) has recently emerged as a cost-effective method for identifying clinically actionable genetic variants across many genes in a single test. This approach has now been successfully applied to detect somatic mutations in hematopoietic malignant tumors, solid tumors, and constitutional mutations in genes associated with inherited cancer predisposition syndromes, among other clinical testing applications. 1e5 Further, numerous studies have demonstrated that NGS techniques are able to detect the full range of DNA variation, including single-nucleotide variants (SNVs), insertions/deletions, translocations, and copy number changes, 4,6e11 in the research setting. Thus, clinical NGS-based diagnostics offer an improvement over current molecular methods, such as PCR and Sanger sequencing, by which only a limited spectrum of mutations can be identified at a single genomic locus.Implementing NGS methods for routine clinical testing requires validation across the range of variables encountered in a clinical diagnostics laboratory, including the various specimen types that may be submitted for testing. The preferred specimen for most molecular tests is fresh tissue (eg, blood anticoagulated with EDTA or fresh tissue from a surgical biopsy or excision in saline) because this minimizes processing and Supported by the

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

Comparison of Clinical Targeted Next-Generation Sequence Data from Formalin-Fixed and Fresh-Frozen Tissue Specimens

Spencer

Sehn

Abel

et al. 2013

The Journal of Molecular Diagnostics

179

156

View full text Add to dashboard Cite

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“…While the power of these approaches is being realized for FF tumors, [11][12][13] there are currently few studies to have realized this potential for FFPE samples, owing to the inherent problems of working with chemically modified and damaged DNA, the requirements for larger amounts of genomic DNA and/or high depth of sequencing coverage to minimize ambiguous read mapping and the subsequent added bioinformatics challenges that this brings. 28,[32][33][34][35] Large consortia such as the ICGC and TCGA also continue to analyze tumor genomes by SNP arrays as an important support tool for CNA detection and assessment of tumor cellularity, [11][12][13] and so for these reasons it remains important to optimize CGH platforms for whole-genome CNA detection of FFPE tumor samples.…”

Section: Discussionmentioning

confidence: 99%

Evaluating the repair of DNA derived from formalin-fixed paraffin-embedded tissues prior to genomic profiling by SNP–CGH analysis

Hosein

Song

Reed

et al. 2013

Laboratory Investigation

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Pathology archives contain vast resources of clinical material in the form of formalin-fixed paraffin-embedded (FFPE) tissue samples. Owing to the methods of tissue fixation and storage, the integrity of DNA and RNA available from FFPE tissue is compromized, which means obtaining informative data regarding epigenetic, genomic, and expression alterations can be challenging. Here, we have investigated the utility of repairing damaged DNA derived from FFPE tumors prior to single-nucleotide polymorphism (SNP) arrays for whole-genome DNA copy number analysis. DNA was extracted from FFPE samples spanning five decades, involving tumor material obtained from surgical specimens and postmortems. Various aspects of the protocol were assessed, including the method of DNA extraction, the role of Quality Control quantitative PCR (qPCR) in predicting sample success, and the effect of DNA restoration on assay performance, data quality, and the prediction of copy number aberrations (CNAs). DNA that had undergone the repair process yielded higher SNP call rates, reduced log R ratio variance, and improved calling of CNAs compared with matched FFPE DNA not subjected to repair. Reproducible mapping of genomic break points and detection of focal CNAs representing highlevel gains and homozygous deletions (HD) were possible, even on autopsy material obtained in 1974. For example, DNA amplifications at the ERBB2 and EGFR gene loci and a HD mapping to 13q14.2 were validated using immunohistochemistry, in situ hybridization, and qPCR. The power of SNP arrays lies in the detection of allele-specific aberrations; however, this aspect of the analysis remains challenging, particularly in the distinction between loss of heterozygosity (LOH) and copy neutral LOH. In summary, attempting to repair DNA that is damaged during fixation and storage may be a useful pretreatment step for genomic studies of large archival FFPE cohorts with long-term follow-up or for understanding rare cancer types, where fresh frozen material is scarce.

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“…Another strategy is to increase sequencing depth. In a whole-exome sequencing study, a high rate of discordant loci as false positives in FFPE tissues compared to paired snap-frozen tissues was detected at 20× coverage [187]. While false positives were reduced but still present at 40× coverage, no discordance was observed at 80× coverage.…”

Section: Issues With Tumor Samplesmentioning

confidence: 99%

“…While false positives were reduced but still present at 40× coverage, no discordance was observed at 80× coverage. Hence, it is seen that accurate detection of somatic mutations in FFPE tumor samples can be achieved at high coverages, especially using targeted sequencing approaches [187,188].…”

Section: Issues With Tumor Samplesmentioning

confidence: 99%

Next-generation sequencing in the clinic: Promises and challenges

et al. 2013

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The advent of next generation sequencing (NGS) technologies has revolutionized the field of genomics, enabling fast and cost-effective generation of genome-scale sequence data with exquisite resolution and accuracy. Over the past years, rapid technological advances led by academic institutions and companies have continued to broaden NGS applications from research to the clinic. A recent crop of discoveries have highlighted the medical impact of NGS technologies on Mendelian and complex diseases, particularly cancer. However, the everincreasing pace of NGS adoption presents enormous challenges in terms of data processing, storage, management and interpretation as well as sequencing quality control, which hinder the translation from sequence data into clinical practice. In this review, we first summarize the technical characteristics and performance of current NGS platforms. We further highlight advances in the applications of NGS technologies towards the development of clinical diagnostics and therapeutics. Common issues in NGS workflows are also discussed to guide the selection of NGS platforms and pipelines for specific research purposes.

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Targeted high throughput sequencing in clinical cancer Settings: formaldehyde fixed-paraffin embedded (FFPE) tumor tissues, input amount and tumor heterogeneity

Cited by 166 publications

References 42 publications

Comparison of Clinical Targeted Next-Generation Sequence Data from Formalin-Fixed and Fresh-Frozen Tissue Specimens

Comparison of Clinical Targeted Next-Generation Sequence Data from Formalin-Fixed and Fresh-Frozen Tissue Specimens

Evaluating the repair of DNA derived from formalin-fixed paraffin-embedded tissues prior to genomic profiling by SNP–CGH analysis

Next-generation sequencing in the clinic: Promises and challenges

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