Your search keyword '"Ahuva Odenheimer-Bergman"' showing total 11 results

1. Correction: Gifsy-1 Prophage IsrK with Dual Function as Small and Messenger RNA Modulates Vital Bacterial Machineries.

Author

Tal Hershko-Shalev, Ahuva Odenheimer-Bergman, Maya Elgrably-Weiss, Tamar Ben-Zvi, Sutharsan Govindarajan, Hemda Seri, Kai Papenfort, Jörg Vogel, and Shoshy Altuvia

Subjects

Genetics, QH426-470

Abstract

[This corrects the article DOI: 10.1371/journal.pgen.1005975.].

Published

2017

2. Gifsy-1 Prophage IsrK with Dual Function as Small and Messenger RNA Modulates Vital Bacterial Machineries.

Author

Tal Hershko-Shalev, Ahuva Odenheimer-Bergman, Maya Elgrably-Weiss, Tamar Ben-Zvi, Sutharsan Govindarajan, Hemda Seri, Kai Papenfort, Jörg Vogel, and Shoshy Altuvia

Subjects

Genetics, QH426-470

Abstract

While an increasing number of conserved small regulatory RNAs (sRNAs) are known to function in general bacterial physiology, the roles and modes of action of sRNAs from horizontally acquired genomic regions remain little understood. The IsrK sRNA of Gifsy-1 prophage of Salmonella belongs to the latter class. This regulatory RNA exists in two isoforms. The first forms, when a portion of transcripts originating from isrK promoter reads-through the IsrK transcription-terminator producing a translationally inactive mRNA target. Acting in trans, the second isoform, short IsrK RNA, binds the inactive transcript rendering it translationally active. By switching on translation of the first isoform, short IsrK indirectly activates the production of AntQ, an antiterminator protein located upstream of isrK. Expression of antQ globally interferes with transcription termination resulting in bacterial growth arrest and ultimately cell death. Escherichia coli and Salmonella cells expressing AntQ display condensed chromatin morphology and localization of UvrD to the nucleoid. The toxic phenotype of AntQ can be rescued by co-expression of the transcription termination factor, Rho, or RNase H, which protects genomic DNA from breaks by resolving R-loops. We propose that AntQ causes conflicts between transcription and replication machineries and thus promotes DNA damage. The isrK locus represents a unique example of an island-encoded sRNA that exerts a highly complex regulatory mechanism to tune the expression of a toxic protein.

Published

2016

3. Plasma metagenomic sequencing to detect and quantify bacterial DNA in ICU patients suspected of sepsis: A proof-of-principle study

Author

Bellal Joseph, Zain Khalpey, Terence O'Keeffe, Paul Keim, Ahuva Odenheimer-Bergman, Tania Contente-Cuomo, Mehreen T. Kisat, Ali Salim, Havell Markus, Muhammed Murtaza, Reza Askari, Sridhar Nonavinkere Srivatsan, and Peter Rhee

Subjects

DNA, Bacterial, medicine.medical_specialty, Treatment response, Icu patients, Critical Care, Critical Illness, Critical Care and Intensive Care Medicine, Proof of Concept Study, Gastroenterology, Sepsis, Internal medicine, medicine, BDNA test, Humans, Bacteria, business.industry, Reproducibility of Results, Sequence Analysis, DNA, Assay sensitivity, medicine.disease, Quality Improvement, Intensive Care Units, Metagenomics, Surgery, business, Quantitative analysis (chemistry), Bacterial dna

Abstract

BACKGROUND Timely recognition of sepsis and identification of pathogens can improve outcomes in critical care patients but microbial cultures have low accuracy and long turnaround times. In this proof-of-principle study, we describe metagenomic sequencing and analysis of nonhuman DNA in plasma. We hypothesized that quantitative analysis of bacterial DNA (bDNA) levels in plasma can enable detection and monitoring of pathogens. METHODS We enrolled 30 patients suspected of sepsis in the surgical trauma intensive care unit and collected plasma samples at the time of diagnostic workup for sepsis (baseline), and 7 days and 14 days later. We performed metagenomic sequencing of plasma DNA and used computational classification of sequencing reads to detect and quantify total and pathogen-specific bDNA fraction. To improve assay sensitivity, we developed an enrichment method for bDNA based on size selection for shorter fragment lengths. Differences in bDNA fractions between samples were evaluated using t test and linear mixed-effects model, following log transformation. RESULTS We analyzed 72 plasma samples from 30 patients. Twenty-seven samples (37.5%) were collected at the time of infection. Median total bDNA fraction was 1.6 times higher in these samples compared with samples with no infection (0.011% and 0.0068%, respectively, p < 0.001). In 17 patients who had active infection at enrollment and at least one follow-up sample collected, total bDNA fractions were higher at baseline compared with the next sample (p < 0.001). Following enrichment, bDNA fractions increased in paired samples by a mean of 16.9-fold. Of 17 samples collected at the time when bacterial pathogens were identified, we detected pathogen-specific DNA in 13 plasma samples (76.5%). CONCLUSION Bacterial DNA levels in plasma are elevated in critically ill patients with active infection. Pathogen-specific DNA is detectable in plasma, particularly after enrichment using selection for shorter fragments. Serial changes in bDNA levels may be informative of treatment response. LEVEL OF EVIDENCE Epidemiologic/Prognostic, Level V.

Published

2021

4. Biology of Circulating DNA in Health and Disease

Author

Ahuva Odenheimer-Bergman, Havell Markus, and Muhammed Murtaza

Published

2022

5. Analysis of recurrently protected genomic regions in cell-free DNA found in urine

Author

Bethine Moore, Kendall Van Keuren-Jensen, Daniel D. Von Hoff, Havell Markus, Tania Contente-Cuomo, Ahuva Odenheimer-Bergman, Elizabeth Hutchins, Elizabeth A. Raupach, Bradon R. McDonald, Michelle D. Stephens, Michelina C. de la Maza, Patrick Pirrotte, Muhammed Murtaza, Sydney Connor, Carlos Becerra, Pooja Hingorani, Ajay Goel, Scott Celinski, Marissa McGilvrey, and Jun Zhao

Subjects

Analyte, Base pair, Sequence analysis, Genomics, General Medicine, Urine, DNA, DNA Fragmentation, Sequence Analysis, DNA, Biology, Molecular biology, Article, chemistry.chemical_compound, chemistry, DNA fragmentation, Humans, Fragmentation (cell biology), Cell-Free Nucleic Acids

Abstract

Cell-free DNA (cfDNA) in urine is a promising analyte for noninvasive diagnostics. However, urine cfDNA is highly fragmented. Whether characteristics of these fragments reflect underlying genomic architecture is unknown. Here, we characterized fragmentation patterns in urine cfDNA using whole-genome sequencing. Size distribution of urine cfDNA fragments showed multiple strong peaks between 40 and 120 base pairs (bp) with a modal size of 81- and sharp 10-bp periodicity, suggesting transient protection from complete degradation. These properties were robust to preanalytical perturbations, such as at-home collection and delay in processing. Genome-wide sequencing coverage of urine cfDNA fragments revealed recurrently protected regions (RPRs) conserved across individuals, with partial overlap with nucleosome positioning maps inferred from plasma cfDNA. The ends of cfDNA fragments clustered upstream and downstream of RPRs, and nucleotide frequencies of fragment ends indicated enzymatic digestion of urine cfDNA. Compared to plasma, fragmentation patterns in urine cfDNA showed greater correlation with gene expression and chromatin accessibility in epithelial cells of the urinary tract. We determined that tumor-derived urine cfDNA exhibits a higher frequency of aberrant fragments that end within RPRs. By comparing the fraction of aberrant fragments and nucleotide frequencies of fragment ends, we identified urine samples from cancer patients with an area under the curve of 0.89. Our results revealed nonrandom genomic positioning of urine cfDNA fragments and suggested that analysis of fragmentation patterns across recurrently protected genomic loci may serve as a cancer diagnostic.

Published

2021

6. Personalized circulating tumor DNA analysis to detect residual disease after neoadjuvant therapy in breast cancer

Author

Patricia A. Cronin, Suet-Feung Chin, Bradon R. McDonald, Heidi E. Kosiorek, Stephen John Sammut, Donald W. Northfelt, Barbara A. Pockaj, Karen S. Anderson, Muhammed Murtaza, Maria Farooq, Thomas P. Slavin, Carlos Caldas, Ahuva Odenheimer-Bergman, Tania Contente-Cuomo, Ann E. McCullough, Nieves Perdigones, Jeffrey N. Weitzel, Rosa Mejia, Brenda Ernst, and Bhavika K. Patel

Subjects

Oncology, Treatment response, medicine.medical_specialty, Neoplasm, Residual, medicine.medical_treatment, Breast Neoplasms, Disease, Circulating Tumor DNA, Breast cancer, Internal medicine, medicine, Humans, Neoplasm, Neoadjuvant therapy, Neoplasm Staging, business.industry, Cancer, Sequence Analysis, DNA, General Medicine, Reference Standards, medicine.disease, Neoadjuvant Therapy, ROC Curve, Circulating tumor DNA, Molecular Response, Mutation, Biological Assay, Female, business

Abstract

Longitudinal analysis of circulating tumor DNA (ctDNA) has shown promise for monitoring treatment response. However, most current methods lack adequate sensitivity for residual disease detection during or after completion of treatment in patients with nonmetastatic cancer. To address this gap and to improve sensitivity for minute quantities of residual tumor DNA in plasma, we have developed targeted digital sequencing (TARDIS) for multiplexed analysis of patient-specific cancer mutations. In reference samples, by simultaneously analyzing 8 to 16 known mutations, TARDIS achieved 91 and 53% sensitivity at mutant allele fractions (AFs) of 3 in 104 and 3 in 105, respectively, with 96% specificity, using input DNA equivalent to a single tube of blood. We successfully analyzed up to 115 mutations per patient in 80 plasma samples from 33 women with stage I to III breast cancer. Before treatment, TARDIS detected ctDNA in all patients with 0.11% median AF. After completion of neoadjuvant therapy, ctDNA concentrations were lower in patients who achieved pathological complete response (pathCR) compared to patients with residual disease (median AFs, 0.003 and 0.017%, respectively, P = 0.0057, AUC = 0.83). In addition, patients with pathCR showed a larger decrease in ctDNA concentrations during neoadjuvant therapy. These results demonstrate high accuracy for assessment of molecular response and residual disease during neoadjuvant therapy using ctDNA analysis. TARDIS has achieved up to 100-fold improvement beyond the current limit of ctDNA detection using clinically relevant blood volumes, demonstrating that personalized ctDNA tracking could enable individualized clinical management of patients with cancer treated with curative intent.

Published

2019

7. Abstract A51: Personalized monitoring of treatment response using Targeted Digital Sequencing of circulating tumor DNA

Author

Heidi E. Kosiorek, Ann E. McCullough, Nieves Perdigones, Suet-Feung Chin, Bradon R. McDonald, Maria Farooq, Karen S. Anderson, Donald W. Northfelt, Patricia A. Cronin, Stephen John Sammut, Carlos Caldas, Tania Contente-Cuomo, Muhammed Murtaza, Bhavika K. Patel, Barbara A. Pockaj, Michelle D. Stephens, Jeffrey N. Weitzel, Rosa Mejia, Brenda Ernst, Ahuva Odenheimer-Bergman, and Thomas P. Slavin

Subjects

Oncology, Cancer Research, Treatment response, medicine.medical_specialty, business.industry, medicine.medical_treatment, Cancer, Disease, medicine.disease, Breast cancer, Circulating tumor DNA, Internal medicine, Pancreatic cancer, medicine, Stage (cooking), business, Neoadjuvant therapy

Abstract

Background: Accurate circulating biomarkers for detecting residual disease can help guide therapy decisions, particularly in early-stage cancer patients. However, currently available methods lack the sensitivity required to confidently assess the presence of residual disease in patients with low tumor burden. To address this need, we have developed TARDIS (Targeted Digital Sequencing), a personalized, multiplexed amplicon sequencing method capable of tracking as many as 100 or more mutations simultaneously. Methods: We obtained tumor biopsies and longitudinal plasma samples from patients with early-stage breast cancer, glioblastoma, and pancreatic cancer. Each tumor biopsy was analyzed whole-exome sequencing. Founder mutations were selected, accounting for copy number alterations (analyzed using sequenza) and a consensus allele fraction approach that combined pyclone and custom in-house methods. Patient-specific TARDIS primers were designed to detect these mutations in plasma cfDNA. Error suppression in TARDIS was achieved using a combination of unique molecular identifiers and fragment sizes to group sequencing reads into read families. Results: In 33 patients with early-stage breast cancer treated with neoadjuvant therapy, we targeted between 3 and 116 (mean 30) mutations per patient and analyzed between 1 and 4 longitudinal plasma samples using TARDIS. Prior to treatment, we detected ctDNA in 100% patients with Stage I-III breast cancer (n=32, 95% CI= 89%-100%). We detected tumor-specific mutations in 100% of baseline breast cancer plasma samples. After completion of neoadjuvant therapy and before surgery, ctDNA levels were significantly lower in patients with pathologic complete response (pathCR, no evidence of disease at surgery) compared to patients with residual disease (median tumor fractions 0.003% and 0.017%, respectively, p=0.0058, AUC=0.83). Conclusions: TARDIS enables highly sensitive detection of ctDNA in patients with nonmetastatic cancers. Analysis of longitudinal plasma samples using TARDIS holds promise for personalizing the extent of treatment in patients with curable disease. Multiple clinical validation studies across cancer types are ongoing to define quantitative thresholds for changes in ctDNA levels that could improve clinical decision making. Citation Format: Bradon R. McDonald, Tania Contente-Cuomo, Stephen-John Sammut, Michelle D. Stephens, Ahuva Odenheimer-Bergman, Brenda Ernst, Nieves Perdigones, Suet-Feung Chin, Maria Farooq, Rosa Mejia, Patricia A. Cronin, Karen S. Anderson, Heidi E. Kosiorek, Donald W. Northfelt, Ann E. McCullough, Bhavika K. Patel, Jeffrey N. Weitzel, Thomas P. Slavin, Carlos Caldas, Barbara A. Pockaj, Muhammed Murtaza. Personalized monitoring of treatment response using Targeted Digital Sequencing of circulating tumor DNA [abstract]. In: Proceedings of the AACR Special Conference on Advances in Liquid Biopsies; Jan 13-16, 2020; Miami, FL. Philadelphia (PA): AACR; Clin Cancer Res 2020;26(11_Suppl):Abstract nr A51.

Published

2020

8. Abstract PR14: Sub-nucleosomal fragmentation in urine cell-free DNA

Author

Daniel D. Von Hoff, Marissa McGilvrey, Elizabeth Hutchins, Elizabeth A. Raupach, Tania Contente-Cuomo, Pooja Hingorani, Muhammed Murtaza, Ajay Goel, Kendall Van Keuren-Jensen Van Jensen, Patrick Pirrotte, Ahuva Odenheimer-Bergman, Sydney Connor, Bradon R. McDonald, Michelina C. de la Maza, Carlos Becerra, Havell Markus, Jun Zhao, and Scott Celinski

Subjects

Cancer Research, Oncology, Cell-free fetal DNA, Chemistry, Biophysics, Fragmentation (cell biology)

Abstract

Cell-free DNA (cfDNA) in plasma has been shown to be a promising analyte for noninvasive diagnostics. The collection of blood plasma requires venipuncture, and plasma volume obtainable at a single point is limited. In contrast, cfDNA in urine can be collected noninvasively, with minimal assistance and in larger volumes. However, so far there has been limited success in diagnostic development using urine cfDNA as urine cfDNA is highly fragmented, and whether the characteristics of these fragments reflect underlying genomic architecture is unknown. Here, we perform a comprehensive characterization of fragmentation patterns in urine cfDNA using high-depth whole-genome sequencing from 30 healthy volunteers. We show the distribution of fragment sizes and genome-wide distribution of urine cfDNA fragments are consistent with transient protection from complete degradation by stable intermediates of nucleosome disassembly. Genome-wide nucleosome occupancy and fragment sizes in urine cfDNA are informative of the cell of origin and renal epithelial cells are among the highest contributors in urine. Based on a reference nucleosome map for urine cfDNA positioning, we developed a computational method to measure the fraction of urine cfDNA fragments with aberrant ends at unexpected genomic loci. We observe a higher fraction of fragments with aberrant ends in pediatric and adult cancer patients, distinguishing cancer samples with an area under the curve of 0.89. Our results demonstrate genomic architecture is preserved to an unexpected degree in urine cfDNA and are proof of principle that genome-wide fragmentation analysis of urine cfDNA can enable cancer diagnostics. This abstract is also being presented as Poster B12. Citation Format: Havell Markus, Jun Zhao, Tania Contente-Cuomo, Elizabeth Raupach, Ahuva Odenheimer-Bergman, Sydney Connor, Bradon McDonald, Elizabeth Hutchins, Marissa McGilvrey, Michelina C. de la Maza, Kendall Van Keuren-Jensen Van Jensen, Patrick Pirrotte Pirrotte, Ajay Goel, Carlos Becerra, Daniel D. Von Hoff, Scott Celinski, Pooja Hingorani, Muhammed Murtaza. Sub-nucleosomal fragmentation in urine cell-free DNA [abstract]. In: Proceedings of the AACR Special Conference on Advances in Liquid Biopsies; Jan 13-16, 2020; Miami, FL. Philadelphia (PA): AACR; Clin Cancer Res 2020;26(11_Suppl):Abstract nr PR14.

Published

2020

9. Detection of residual disease after neoadjuvant therapy in breast cancer using personalized circulating tumor DNA analysis

Author

Tania Contente-Cuomo, Barbara A. Pockaj, Suet-Feung Chin, Karen S. Anderson, Donald W. Northfelt, Stephen John Sammut, Heidi E. Kosiorek, Muhammed Murtaza, Brenda Ernst, Ahuva Odenheimer-Bergman, Patricia A. Cronin, Ann E. McCullough, Nieves Perdigones, Maria Farooq, Bradon R. McDonald, Bhavika K. Patel, and Carlos Caldas

Subjects

Oncology, medicine.medical_specialty, medicine.diagnostic_test, business.industry, medicine.medical_treatment, Disease, Odds ratio, Molecular Complete Response, Residual, medicine.disease, Minimal residual disease, Breast cancer, Internal medicine, medicine, Blood test, business, Neoadjuvant therapy

Abstract

Accurate detection of minimal residual disease (MRD) can guide individualized management of early stage cancer patients, but current diagnostic approaches lack adequate sensitivity. Circulating tumor DNA (ctDNA) analysis has shown promise for recurrence monitoring but MRD detection immediately after neoadjuvant therapy or surgical resection has remained challenging. We have developed TARgeted DIgital Sequencing (TARDIS) to simultaneously analyze multiple patient-specific cancer mutations in plasma and improve sensitivity for minute quantities of residual tumor DNA. In 77 reference samples at 0.03%-1% mutant allele fraction (AF), we observed 93.5% sensitivity. Using TARDIS, we analyzed ctDNA in 34 samples from 13 patients with stage II/III breast cancer treated with neoadjuvant therapy. Prior to treatment, we detected ctDNA in 12/12 patients at 0.002%-1.04% AF (0.040% median). After completion of neoadjuvant therapy, we detected ctDNA in 7/8 patients with residual disease observed at surgery and in 1/5 patients with pathological complete response (odds ratio, 18.5, Fisher’s exact p=0.032). These results demonstrate high accuracy for a personalized blood test to detect residual disease after neoadjuvant therapy. With additional clinical validation, TARDIS could identify patients with molecular complete response after neoadjuvant therapy who may be candidates for nonoperative management.One Sentence SummaryA personalized ctDNA test achieves high accuracy for residual disease.

Published

2018

10. Gifsy-1 Prophage IsrK with Dual Function as Small and Messenger RNA Modulates Vital Bacterial Machineries

Author

Tal Hershko-Shalev, Ahuva Odenheimer-Bergman, Maya Elgrably-Weiss, Tamar Ben-Zvi, Sutharsan Govindarajan, Hemda Seri, Kai Papenfort, Jörg Vogel, and Shoshy Altuvia

Subjects

DNA, Bacterial, Salmonella typhimurium, Cancer Research, Transcription, Genetic, lcsh:QH426-470, Prophages, Ribonuclease H, Regulatory Sequences, Ribonucleic Acid, Open Reading Frames, Viral Proteins, Bacterial Proteins, Genetics, Escherichia coli, RNA Isoforms, Bacteriophages, RNA, Messenger, Promoter Regions, Genetic, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Correction, Gene Expression Regulation, Bacterial, Rho Factor, RNA, Bacterial, lcsh:Genetics, Mutagenesis, RNA, Small Untranslated

Abstract

While an increasing number of conserved small regulatory RNAs (sRNAs) are known to function in general bacterial physiology, the roles and modes of action of sRNAs from horizontally acquired genomic regions remain little understood. The IsrK sRNA of Gifsy-1 prophage of Salmonella belongs to the latter class. This regulatory RNA exists in two isoforms. The first forms, when a portion of transcripts originating from isrK promoter reads-through the IsrK transcription-terminator producing a translationally inactive mRNA target. Acting in trans, the second isoform, short IsrK RNA, binds the inactive transcript rendering it translationally active. By switching on translation of the first isoform, short IsrK indirectly activates the production of AntQ, an antiterminator protein located upstream of isrK. Expression of antQ globally interferes with transcription termination resulting in bacterial growth arrest and ultimately cell death. Escherichia coli and Salmonella cells expressing AntQ display condensed chromatin morphology and localization of UvrD to the nucleoid. The toxic phenotype of AntQ can be rescued by co-expression of the transcription termination factor, Rho, or RNase H, which protects genomic DNA from breaks by resolving R-loops. We propose that AntQ causes conflicts between transcription and replication machineries and thus promotes DNA damage. The isrK locus represents a unique example of an island-encoded sRNA that exerts a highly complex regulatory mechanism to tune the expression of a toxic protein.

Published

2017

11. Abstract P4-01-21: Multiplexed targeted digital sequencing of circulating tumor DNA to detect minimal residual disease in early and locally advanced breast cancer

Author

Barbara A. Pockaj, Heidi E. Kosiorek, C Caldas, S-F Chin, Bhavika Patel, Donald W. Northfelt, Tania Contente-Cuomo, Muhammed Murtaza, Bradon R. McDonald, Maria Farooq, S.J. Sammut, Patricia A. Cronin, Karen S. Anderson, Ann E. McCullough, Nieves Perdigones, Ahuva Odenheimer-Bergman, and Brenda Ernst

Subjects

Oncology, Cancer Research, medicine.medical_specialty, business.industry, medicine.medical_treatment, medicine.disease, Minimal residual disease, chemistry.chemical_compound, Breast cancer, chemistry, Nat, Internal medicine, medicine, Multiplex, Ligation, business, DNA, Exome sequencing, Neoadjuvant therapy

Abstract

Background: Circulating tumor DNA (ctDNA) analysis holds potential for minimal residual disease (MRD) detection in early stage breast cancer. However, sensitivity for MRD is limited due to low ctDNA levels in early stage patients and limited blood volumes. Loss of input DNA during library preparation, limited multiplexing or low sensitivity of current molecular methods further limit accuracy. To address this gap, we have developed TARgeted DIgital Sequencing (TARDIS), a novel method for simultaneous analysis of multiple patient-specific mutations in plasma DNA. Methods: Using tumor exome sequencing, we identify and prioritize somatic founder mutations, design nested primers and evaluate them for multiplex performance. Using 5-10 ng input plasma DNA, we perform 1) targeted linear pre-amplification to improve downstream molecular conversion, 2) single-stranded adapter ligation to incorporate unique molecular identifiers (UMIs) and 3) targeted PCR to prepare sequencing-ready libraries. The resulting sequencing reads have fixed target-specific ends and variable ligation ends. We utilize fragment size and UMIs to group sequencing reads into read families. To ensure specificity, we require targeted mutations are supported by 2 or more read families. Results: To assess analytical performance, we targeted 8 mutations in cell-free DNA reference samples with 0.25%-2% mutation allele fractions (AFs). Precision across 7-16 replicates at each AF level agreed with expectations of Poisson distribution, demonstrating effective analysis of ˜70% of input DNA. At 2%, 1%, 0.5% and 0.25% AFs, variant-level sensitivity was 96.4%, 96.4%, 91.1% and 65.8%, approaching the theoretical limit given input DNA. At 0.25% AF, 3-7 mutations were detected per sample, achieving 100% sample-level sensitivity. In 16 wild-type replicates, no targeted mutations were called (100% specificity). Averaging multiple mutations improved precision in sample-level AF estimates. Mean AFs from 8 mutations for the 2% sample were 2.34%-2.80% (5.8% CV). In 6 patients with breast cancer treated with neoadjuvant therapy (NAT), we analyzed 8-18 patient-specific mutations (mean 11.8). Before treatment, ctDNA was detected in 5/6 patients at mean AFs of 0.02%-1.19% (mean 0.40%), supported by 2-10 mutations (mean 5.6). Of these 5 patients, 4 had residual disease after NAT and ctDNA was detected pre-operatively or during NAT in 3/4 patients. 1 patient achieved pathological Complete Response and ctDNA was undetectable after NAT. Conclusions: Preliminary results suggest TARDIS enables accurate MRD detection after neoadjuvant therapy in patients with early stage breast cancer. On-going work is expanding this analysis to include additional patients and investigate the clinical validity of peri-operative ctDNA monitoring. Summary of clinical resultsPatientPre-NAT Stage (TNM)SubtypeNo. of Mutations TargetedBaseline ctDNA (AF%, No. of Mutations)ctDNA after or during NAT (AF%, No. of Mutations)Residual Tumor (TNM)1T3 N1ER+ PR+ HER2-8+ (0.02%, 2)-T2 N12T3 N0TNBC12+ (0.29%, 6)+ (0.01%, 1)T1a N03T2 N1TNBC18+ (1.19%, 10)+ (0.01%, 1)T1mi N04T3 N1TNBC10+ (0.02%, 3)+ (0.05%, 3)T3 N15T2 N0TNBC9+ (0.46%, 7)-pathCR6T1c N1TNBC14--pathCR Citation Format: McDonald BR, Contente-Cuomo T, Sammut S-J, Ernst B, Odenheimer-Bergman A, Perdigones N, Chin S-F, Farooq M, Cronin PA, Anderson KS, Kosiorek H, Northfelt D, McCullough A, Patel B, Caldas C, Pockaj B, Murtaza M. Multiplexed targeted digital sequencing of circulating tumor DNA to detect minimal residual disease in early and locally advanced breast cancer [abstract]. In: Proceedings of the 2018 San Antonio Breast Cancer Symposium; 2018 Dec 4-8; San Antonio, TX. Philadelphia (PA): AACR; Cancer Res 2019;79(4 Suppl):Abstract nr P4-01-21.

Published

2019