Your search keyword '"Arthur Baca"' showing total 6 results

1. Analytical validation of a tissue agnostic ctDNA MRD assay using tumor specific methylation and somatic variant profiles in early-stage CRC

Author

Farsheed Ghadiri, Anna Hartwig, Dustin Hite, Marisa Juntilla, Mahmoud Dahdouli, Jordan E. Burke, Tracy Nance, Sweta Sharma, Darya Chudova, AmirAli Talasaz, Jessica Kurata, Carlo Artieri, Saiyou Ohshima, Yupeng He, Oscar Westesson, Ariel Jaimovich, Haley Axelrod, Arthur Baca, and Yu Kong

Subjects

Cancer Research, business.industry, Colorectal cancer, Somatic cell, Tumor specific, Methylation, medicine.disease, Minimal residual disease, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, Oncology, chemistry, 030220 oncology & carcinogenesis, Cancer research, Medicine, Liquid biopsy, Stage (cooking), business, DNA, 030215 immunology

Abstract

e15549 Background: Liquid biopsy is a candidate for detection of minimal residual disease (MRD) in early colorectal cancer. Detection of circulating tumor (ct)DNA in early stage cancer is challenging given the low abundance of ctDNA molecules. We developed a tissue agnostic MRD Test to optimize sensitivity and specificity of ctDNA detection by integrating tumor-specific genomic mutation and DNA methylation signatures coupled to noise-reduction of non-tumor background cfDNA signals. Methods: This MRD Test was developed following CLIA, Nex-StoCT Working Group, and AMP/CAP guidance and validation principles. Using a single input plasma sample, data from somatic and epigenomic targeted capture panels are integrated to generate a final test result: ctDNA detected or ctDNA not detected. ctDNA detected is defined by the presence of mutation or epigenomic classifier inputs exceeding a defined threshold. Quality control (QC) measures were implemented in both process and final sequencing results. Analytical specificity, sensitivity, and accuracy were determined using 130 samples. Results: The MRD Test specificity was 95% (70/74) using colonoscopy screened negative samples.A retrospective review of the clinical histories of these false positive samples showed high risk clinical features such as smoking, family history of CRC, and sub-optimal bowel prep prior to the colonoscopy. Analytical sensitivity (LoD) was established by diluting late stage CRC samples at two clinically relevant cfDNA inputs at three dilutions (30ng or 10ng, ranging 0.1% to 0.75% tumor fraction). The 95% LoD was determined to be 0.3% for 10ng and < 0.1% for 30ng, the lowest level tested for each input. Accuracy was determined by diluting advanced CRC samples to 0.5-0.75% MAF tested at 30ng or 10ng cfDNA with a detection result of 100% (38/38). Conclusions: We present a CLIA validated assay with performance characteristics sufficient to detect residual disease in Stage II/III CRC post-curative intent therapy. This assay is currently being used in multiple interventional clinical trials.

Published

2020

2. The Landscape of Actionable Genomic Alterations in Cell-Free Circulating Tumor DNA from 21,807 Advanced Cancer Patients

Author

David R. Gandara, Darya Chudova, Rebecca J. Nagy, Stefanie Mortimer, Helmy Eltoukhy, Justin I. Odegaard, Kimberly C. Banks, James V. Vowles, Stephen R. Fairclough, AmirAli Talasaz, Arthur Baca, Oliver A. Zill, Richard B. Lanman, Philip C. Mack, and Reza Mokhtari

Subjects

0301 basic medicine, Male, Cancer Research, DNA Copy Number Variations, Colorectal cancer, Cell, Genomics, Biology, Somatic evolution in cancer, Circulating Tumor DNA, Clonal Evolution, 03 medical and health sciences, 0302 clinical medicine, Germline mutation, Neoplasms, medicine, Biomarkers, Tumor, Humans, Gene, business.industry, Cancer, High-Throughput Nucleotide Sequencing, DNA, Neoplasm, medicine.disease, Advanced cancer, 030104 developmental biology, medicine.anatomical_structure, Oncology, Circulating tumor DNA, 030220 oncology & carcinogenesis, Mutation, Cancer research, Female, business, Cell-Free Nucleic Acids

Abstract

Purpose: Cell-free DNA (cfDNA) sequencing provides a noninvasive method for obtaining actionable genomic information to guide personalized cancer treatment, but the presence of multiple alterations in circulation related to treatment and tumor heterogeneity complicate the interpretation of the observed variants.Experimental Design: We describe the somatic mutation landscape of 70 cancer genes from cfDNA deep-sequencing analysis of 21,807 patients with treated, late-stage cancers across >50 cancer types. To facilitate interpretation of the genomic complexity of circulating tumor DNA in advanced, treated cancer patients, we developed methods to identify cfDNA copy-number driver alterations and cfDNA clonality.Results: Patterns and prevalence of cfDNA alterations in major driver genes for non–small cell lung, breast, and colorectal cancer largely recapitulated those from tumor tissue sequencing compendia (The Cancer Genome Atlas and COSMIC; r = 0.90–0.99), with the principal differences in alteration prevalence being due to patient treatment. This highly sensitive cfDNA sequencing assay revealed numerous subclonal tumor-derived alterations, expected as a result of clonal evolution, but leading to an apparent departure from mutual exclusivity in treatment-naïve tumors. Upon applying novel cfDNA clonality and copy-number driver identification methods, robust mutual exclusivity was observed among predicted truncal driver cfDNA alterations (FDR = 5 × 10−7 for EGFR and ERBB2), in effect distinguishing tumor-initiating alterations from secondary alterations. Treatment-associated resistance, including both novel alterations and parallel evolution, was common in the cfDNA cohort and was enriched in patients with targetable driver alterations (>18.6% patients).Conclusions: Together, these retrospective analyses of a large cfDNA sequencing data set reveal subclonal structures and emerging resistance in advanced solid tumors. Clin Cancer Res; 24(15); 3528–38. ©2018 AACR.

Published

2017

3. Analytical validation of a tumor-agnostic integrated multianalyte circulating tumor DNA (ctDNA) assay in early-stage cancer

Author

Aparna Raj Parikh, Ariel Jaimovich, Ryan B. Corcoran, Emily E. Van Seventer, AmirAli Talasaz, Carlo G. Artieri, Anna Hartwig, and Arthur Baca

Subjects

Cancer Research, Early-stage cancer, Oncology, business.industry, Somatic cell, Circulating tumor DNA, Cancer research, Medicine, In patient, business, Early stage disease

Abstract

3057 Background: ctDNA sequencing has been rapidly adopted for the identification of targetable somatic alterations (alts) in patients with advanced cancers. However, early stage disease detection has been hindered by low levels of ctDNA in circulation and the presence of confounding non-tumor-related somatic alts. We developed and validated a ctDNA assay that combines somatic and epigenomic signals to detect early stage tumors without tumor tissue or white blood cells (WBC). Methods: Using a single input sample, our assay integrates the sensitive detection of genomic alts with quantification of epigenomic signals associated with cancer. Non-tumor alts (e.g., clonal hematopoiesis of indeterminate potential; CHIP) are excluded using a newly developed bioinformatic classifier. To assess analytical sensitivity, specificity, and positive and negative reproducibility, we tested 337 clinical and contrived samples. Results: Clinical specificity was determined using 80 plasma samples from 50-75 year old presumptive cancer-free donors, and resulted in a single false positive (99% specificity). Analytical sensitivity (limit of detection) was established using a dilution series of 4 different late stage CRC pts tested in triplicate at a clinically relevant DNA input (30 ng) across multiple batches. 100% sensitivity was maintained even at the lowest tested level (estimated 0.1% tumor level). Positive/negative reproducibility was assessed by testing triplicates of diluted late stage samples and age-matched healthy donors, respectively, across different cfDNA inputs, and multiple reagent lots. Both positive and negative calls were 100% concordant across all replicates. Independent estimation of tumor levels from epigenomic or genomic signals produced highly concordant results (correlation r-value: 0.82, p-value: 3e-16). Conclusions: We designed and validated a highly specific ctDNA assay that integrates both genomic and epigenomic signals to allow for accurate and quantitative tumor level detection in early stages of the disease without requiring tumor tissue or WBC.

Published

2019

4. Abstract 5705: Analytical validation of Guardant360 v2.10

Author

James V. Vowles, Stephen R. Fairclough, Stefanie Mortimer, Diana Abdueva, Justin I. Odegaard, Arthur Baca, Reza Bayat Mokhtari, AmirAli Talasaz, and Marcin Sikora

Subjects

0301 basic medicine, Cancer Research, Serial dilution, In silico, Adult Solid Tumor, Cancer, Context (language use), Computational biology, Biology, medicine.disease, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Oncology, 030220 oncology & carcinogenesis, Genotype, medicine, False positive rate, Indel

Abstract

Guardant360 is a cell-free circulating tumor DNA (ctDNA) test that genotypes all guideline-recommended solid tumor somatic genomic treatment targets from a single non-invasive blood draw. The new version, v2.10, was redesigned to enhance sensitivity and specificity across 73 cancer-related genes. It detects all four major variant classes (single nucleotide variants, SNVs, in all 73 genes; indels in 23 genes; gene amplifications, CNAs, in 18 genes; and fusions in 6 genes). Analytical performance was assessed throughout the reportable range via multiple serial dilution studies of orthogonally-characterized contrived and patient samples. Analytical specificity was assessed by calculating the false positive rate in pre-characterized healthy donor sample mixtures serially diluted. Positive predictive value (PPV) was estimated as a function of allelic fraction/copy number from pre-characterized samples and prevalence-adjusted using a cohort of 2,585 consecutive clinical samples. Confirmation was performed using ddPCR. Analytical specificity was 100% for SNVs, fusions, and CNAs and 96% for indels across 25 defined samples. Relative to Guardant360v2.9, v2.10 demonstrated 20-50% increase in fusion molecule recovery. Retrospective in silico analysis of 2,585 consecutive clinical samples demonstrated a 15% increase in actionable fusion detection, a 6%-15% increase in actionable indel detection (excluding newly reportable indels), and a 3%-6% increase in actionable SNV detection. AlterationsReportable Range95% Limit of DetectionAllelic Fraction / Copy NumberAnalytical SensitivityAllelic Fraction / Copy numberPPVSNVs≥0.04%0.25%≥0.25%>99.9%≥0.25%98.7%0.05–0.25%63.8%99.9%≥0.25%98.4%0.05–0.25%67.8% Guardant360 analytical performance characteristics based on standard cfDNA input (30ng). Analytical sensitivity/limit of detection estimates are provided for clinically actionable variants and may vary by sequence context and cfDNA input. PPV is estimated across entire reportable panel space (PPV was 100% for clinically actionable variants). Conclusion: Guardant360 v2.10 comprehensively detects all adult solid tumor guideline-recommended somatic genomic variants with unparalleled sensitivity, accuracy, and specificity. Citation Format: James Vowles, Justin Odegaard, Stefanie Mortimer, Stephen Fairclough, Marcin Sikora, Diana Abdueva, Reza Mokhtari, Arthur Baca, AmirAli Talasaz. Analytical validation of Guardant360 v2.10 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2017; 2017 Apr 1-5; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2017;77(13 Suppl):Abstract nr 5705. doi:10.1158/1538-7445.AM2017-5705

Published

2017

5. Abstract 4343: Comparison of over 10,000 clinical NGS circulating tumor DNA profiles to tissue-derived genomic compendia

Author

Coyt Jackson, Becky Nagy, Oliver A. Zill, Richard B. Lanman, AmirAli Talasaz, Helmy Eltoukhy, Kimberly C. Banks, Arthur Baca, and Stefanie Mortimer

Subjects

Neuroblastoma RAS viral oncogene homolog, Cancer Research, Mutation, medicine.diagnostic_test, Cancer, Drug resistance, Biology, medicine.disease, Bioinformatics, medicine.disease_cause, Oncology, Biopsy, medicine, Cancer research, KRAS, Liquid biopsy, Gene

Abstract

Analysis of cell-free circulating tumor DNA (ctDNA) enables non-invasive and serially repeatable genomic profiling of advanced cancer patients, providing options when tissue biopsy is contra-indicated or of insufficient quantity (20-25% of solid tumor patients). Liquid biopsy studies to-date have been limited to modest-sized cohorts and case studies. Here we present genomic profiling results from liquid biopsies of >10,000 advanced cancer patients in whom Guardant360TM (G360) was ordered for clinical care. G360 provides deep-coverage (15,000x average) and highly accurate sequencing of ctDNA across a 70-gene target-capture panel. It detects single nucleotide variants, indels, gene amplifications, and fusions across all NCCN-recommended solid tumor genomic alterations with analytic specificity >99.9999% and analytic sensitivity Of the >10,000 patients (>50 solid cancer types), 80% of patients had at least one somatic alteration detected in ctDNA (median = 3; mean = 4.3 alterations). The most common cancers were lung (32%), gastrointestinal (23%), and breast (14%). Mutational spectra across the 70 analyzed genes were similar to TCGA results with the notable exception of increased prevalence of resistance mutations in the liquid biopsy cohort, likely owing to ongoing/prior therapy. Canonical drivers in NSCLC patients were generally mutually exclusive, although activating EGFR or RAS mutations were observed in 12.5% of patients with fusions (5/40). Colorectal cancers showed both mutual exclusivity among KRAS, NRAS, and BRAF drivers, and convergent evolution toward downstream pathway activation under anti-EGFR therapy, with some samples showing multiple resistance mechanisms. Mutation patterns for the most frequently mutated genes were generally well correlated between ctDNA and published tissue data, including for commonly altered tumor suppressor genes (for TP53: Pearson r = 0.94, Spearman ρ = 0.80). G360 is ordered prior to initial treatment when biopsy tissue is exhausted, unobtainable or under-genotyped, but more often is ordered upon progression to identify evolving resistance mechanisms that may be targetable. Thus, relative frequencies of genomic alterations were expected to differ from published frequencies established in unselected, early-stage, treatment-naïve cohorts. Nonetheless, the specific patterns of alterations in ctDNA from this unprecedented liquid biopsy cohort largely recapitulated patterns observed in published tissue sequencing studies. Moreover, ctDNA sequencing clearly and robustly identified convergent evolution of drug resistance occurring under therapy. Citation Format: Oliver A. Zill, Kimberly C. Banks, Coyt Jackson, Stefanie Mortimer, Arthur Baca, Becky Nagy, Richard B. Lanman, Helmy Eltoukhy, AmirAli Talasaz. Comparison of over 10,000 clinical NGS circulating tumor DNA profiles to tissue-derived genomic compendia. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr 4343.

Published

2016

6. Somatic genomic landscape of over 15,000 patients with advanced-stage cancer from clinical next-generation sequencing analysis of circulating tumor DNA

Author

Arthur Baca, Stefanie Mortimer, Rebecca J. Nagy, Joseph Z. Ye, Oliver A. Zill, Razelle Kurzrock, Richard B. Lanman, AmirAli Talasaz, Helmy Eltoukhy, Kimberly C. Banks, Darya Chudova, and Coyt Jackson

Subjects

0301 basic medicine, Oncology, medicine.medical_specialty, Cancer Research, Somatic cell, Advanced stage, Biology, Mutually exclusive events, Bioinformatics, DNA sequencing, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, Circulating tumor DNA, 030220 oncology & carcinogenesis, Internal medicine, medicine, Liquid biopsy, Solid tumor, Gene

Abstract

LBA11501 Background: Next-generation sequencing (NGS) of circulating tumor DNA (ctDNA) enables non-invasive profiling of solid tumor cancers. Liquid biopsy studies to date have been limited to modest-size cohorts and case studies. Methods: Somatic genomic profiles of over 15,000 patients with advanced-stage clinical cancer were determined by a highly accurate, deep-coverage (15,000x) ctDNA NGS test targeting 70 genes (Guardant360). Frequencies of somatic ctDNA alterations per gene were compared to those previously described in tissue sequencing projects (e.g., TCGA). Accuracy of ctDNA sequencing (PPV) was assessed by comparing with matched tissue tests for 386 patients. Results: The cohort consisted of lung (37%), breast (14%), colorectal (10%) and other cancers (38%), with ctDNA clinical sensitivity of 86%, 83%, 85%, and 78%, respectively. Cancer-type-specific frequencies and mutual exclusivity patterns among major driver alterations largely recapitulated those seen in tissue sequencing studies. Mutation frequencies per codon correlated well between ctDNA and published tissue data, both for commonly altered tumor suppressors and for oncogenes (Pearson correlations: TP53, r = 0.94; KRAS, r = 0.99; PIK3CA, r = 0.99). The overall accuracy of ctDNA sequencing in comparison with matched tissue tests was 87% (336/386). The accuracy increased to 98% when blood and tumor were collected less than six months apart. Four distinct classes of clinical outcome benefits have been observed by liquid biopsy: 1) actionable mutations in cases with tissue QNS ( ALK fusion, or EGFR or BRAF activating mutations in lung; ERBB2 amp in gastric), 2) actionable resistance mutations at time of progression ( MET amp or EGFRT790M in lung), 3) evolution of sensitivity upon progression ( ERBB2-amplified metastatic breast cancer with triple negative primary), 4) under-genotyped tumors ( BRAFV600E or ERBB2indel in lung). Conclusions: Somatic alteration patterns in ctDNA samples largely agree with tissue alteration patterns, with the exception of resistance mutations. Clinical outcome benefits have been observed for patients treated based on ctDNA findings.

Published

2016