Real-World Performance of a Comprehensive Genomic Profiling Test Optimized for Small Tumor Samples

Scott A Tomlins; Daniel H Hovelson; Jennifer M Suga; Daniel M Anderson; Han A Koh; Elizabeth C Dees; Brendan McNulty; Mark E Burkard; Michael Guarino; Jamil Khatri; Malek M Safa; Marc R Matrana; Eddy S Yang; Alex R Menter; Benjamin M Parsons; Jennifer N Slim; Michael A Thompson; Leon Hwang; William J Edenfield; Suresh Nair; Adedayo Onitilo; Robert Siegel; Alan Miller; Timothy Wassenaar; William J Irvin; William Schulz; Arvinda Padmanabhan; Vallathucherry Harish; Anneliese Gonzalez; Abdul Hai Mansoor; Andrew Kellum; Paul Harms; Stephanie Drewery; Jayson Falkner; Andrew Fischer; Jennifer Hipp; Kat Kwiatkowski; Lorena Lazo de la Vega; Khalis Mitchell; Travis Reeder; Javed Siddiqui; Hana Vakil; D Bryan Johnson; Daniel R Rhodes

doi:10.1200/PO.20.00472

Real-World Performance of a Comprehensive Genomic Profiling Test Optimized for Small Tumor Samples

JCO Precis Oncol. 2021 Aug 19:5:PO.20.00472. doi: 10.1200/PO.20.00472. eCollection 2021 Aug.

Authors

Scott A Tomlins¹, Daniel H Hovelson¹, Jennifer M Suga², Daniel M Anderson³, Han A Koh⁴, Elizabeth C Dees⁵, Brendan McNulty⁶, Mark E Burkard⁷, Michael Guarino⁸, Jamil Khatri⁸, Malek M Safa⁹, Marc R Matrana¹⁰, Eddy S Yang¹¹, Alex R Menter¹², Benjamin M Parsons¹³, Jennifer N Slim¹⁴, Michael A Thompson¹⁵, Leon Hwang¹⁶, William J Edenfield¹⁷, Suresh Nair¹⁸, Adedayo Onitilo¹⁹, Robert Siegel²⁰, Alan Miller²¹, Timothy Wassenaar²², William J Irvin²³, William Schulz²⁴, Arvinda Padmanabhan²⁵, Vallathucherry Harish²⁶, Anneliese Gonzalez²⁷, Abdul Hai Mansoor²⁸, Andrew Kellum²⁹, Paul Harms³⁰, Stephanie Drewery¹, Jayson Falkner¹, Andrew Fischer¹, Jennifer Hipp¹, Kat Kwiatkowski¹, Lorena Lazo de la Vega^{1

31}, Khalis Mitchell¹, Travis Reeder¹, Javed Siddiqui¹, Hana Vakil¹, D Bryan Johnson¹, Daniel R Rhodes¹

Affiliations

¹ Strata Oncology, Ann Arbor, MI.
² Kaiser Permanente, Dept of Medical Oncology, Vallejo, CA.
³ Metro-Minnesota Community Oncology Research Consortium (MMCORC), St Louis Park, MN.
⁴ Kaiser Permanente, Bellflower, CA.
⁵ The University of North Carolina Lineberger Comprehensive Cancer Center, Chapel Hill, NC.
⁶ UNC Rex Healthcare, Raleigh, NC.
⁷ University of Wisconsin Carbone Cancer Center, Madison, WI.
⁸ ChristianaCare's Helen F. Graham Cancer Center & Research Institute, Newark, DE.
⁹ Kettering Cancer Center, Kettering, OH.
¹⁰ Ochsner Cancer Institute, New Orleans, LA.
¹¹ University of Alabama at Birmingham, Birmingham, AL.
¹² Kaiser Permanente Medical Group, Denver, CO.
¹³ Gundersen Health System, La Crosse, WI.
¹⁴ MultiCare, Auburn, WA.
¹⁵ Advocate Aurora Health Care, Milwaukee, WI.
¹⁶ Kaiser Permanente Mid Atlantic, Rockville, MD.
¹⁷ Prisma Health Cancer Institute, Greenville, SC.
¹⁸ Lehigh Valley Health Network, Allentown, PA.
¹⁹ Marshfield Clinic, Marshfield WI.
²⁰ Bon Secours St Francis Cancer Center, Greenville, SC.
²¹ SCL Health Colorado, Broomfield, CO.
²² ProHealth Care, Waukesha, WI.
²³ Bon Secours St Francis Medical Center Midlothian, Midlothian, VA.
²⁴ Swedish American, Rockford, IL.
²⁵ Baptist Health, Lexington, KY.
²⁶ High Point Medical Center, High Point, NC.
²⁷ UT Health-Memorial Hermann Cancer Institute, Houston, TX.
²⁸ Kaiser Permanente Northwest, Portland, OR.
²⁹ North Mississippi Medical Center, Tupelo, MS.
³⁰ University of Michigan Health Systems, Ann Arbor, MI.
³¹ Current address: Brigham & Women's Hospital, Boston, MA.

Abstract

Purpose: Tissue-based comprehensive genomic profiling (CGP) is increasingly used for treatment selection in patients with advanced cancer; however, tissue availability may limit widespread implementation. Here, we established real-world CGP tissue availability and assessed CGP performance on consecutively received samples.

Materials and methods: We conducted a post hoc, nonprespecified analysis of 32,048 consecutive tumor tissue samples received for StrataNGS, a multiplex polymerase chain reaction (PCR)-based comprehensive genomic profiling (PCR-CGP) test, as part of an ongoing observational trial (NCT03061305). Sample characteristics and PCR-CGP performance were assessed across all tested samples, including exception samples not meeting minimum input quality control (QC) requirements (< 20% tumor content [TC], < 2 mm² tumor surface area [TSA], DNA or RNA yield < 1 ng/µL, or specimen age > 5 years). Tests reporting ≥ 1 prioritized alteration or meeting TC and sequencing QC were considered successful. For prostate carcinoma and lung adenocarcinoma, tests reporting ≥ 1 actionable or informative alteration or meeting TC and sequencing QC were considered actionable.

Results: Among 31,165 (97.2%) samples where PCR-CGP was attempted, 10.7% had < 20% TC and 59.2% were small (< 25 mm² tumor surface area). Of 31,101 samples evaluable for input requirements, 8,089 (26.0%) were exceptions not meeting requirements. However, 94.2% of the 31,101 tested samples were successfully reported, including 80.5% of exception samples. Positive predictive value of PCR-CGP for ERBB2 amplification in exceptions and/or sequencing QC-failure breast cancer samples was 96.7%. Importantly, 84.0% of tested prostate carcinomas and 87.9% of lung adenocarcinomas yielded results informing treatment selection.

Conclusion: Most real-world tissue samples from patients with advanced cancer desiring CGP are limited, requiring optimized CGP approaches to produce meaningful results. An optimized PCR-CGP test, coupled with an inclusive exception testing policy, delivered reportable results for > 94% of samples, potentially expanding the proportion of CGP-testable patients and impact of biomarker-guided therapies.

Publication types

Multicenter Study
Observational Study
Research Support, Non-U.S. Gov't

MeSH terms

Biomarkers, Tumor / genetics
Genome, Human*
Genomics / methods
High-Throughput Nucleotide Sequencing / methods
Humans
Multiplex Polymerase Chain Reaction / methods
Neoplasms / genetics*
Neoplasms / pathology
Prospective Studies

Substances

Biomarkers, Tumor

Associated data

ClinicalTrials.gov/NCT03061305