Association of Biomarker-Based Treatment Strategies With Response Rates and Progression-Free Survival in Refractory Malignant Neoplasms: A Meta-analysis.

Schwaederle M; Zhao M; Lee JJ; Lazar V; Leyland-Jones B; Schilsky RL; Mendelsohn J; Kurzrock R

doi:10.1001/jamaoncol.2016.2129

Association of Biomarker-Based Treatment Strategies With Response Rates and Progression-Free Survival in Refractory Malignant Neoplasms: A Meta-analysis.

Affiliations

1. Center for Personalized Cancer Therapy, Division of Hematology and Oncology, University of California, San Diego.
Authors
Schwaederle M¹
Zhao M¹
(2 authors)
2. Department of Biostatistics, University of Texas MD Anderson Cancer Center, Houston.
Authors
Lee JJ²
(1 author)
3. Worldwide Innovative Network for Personalized Cancer Therapy, Villejuif, France.
Authors
Lazar V³
(1 author)
4. Avera Cancer Institute, Sioux Falls, South Dakota.
Authors
Leyland-Jones B⁴
(1 author)
5. Worldwide Innovative Network for Personalized Cancer Therapy, Villejuif, France5American Society of Clinical Oncology, Alexandria, Virginia.
Authors
Schilsky RL⁵
(1 author)

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ORCIDs linked to this article

JAMA Oncology, 01 Nov 2016, 2(11):1452-1459
https://doi.org/10.1001/jamaoncol.2016.2129 PMID: 27273579

Abstract

Importance

The impact of a biomarker-based (personalized) cancer treatment strategy in the setting of phase 1 clinical trials was analyzed.

Objective

To compare patient outcomes in phase 1 studies that used a biomarker selection strategy with those that did not.

Data sources

PubMed search of phase 1 cancer drug trials (January 1, 2011, through December 31, 2013).

Study selection

Studies included trials that evaluated single agents, and reported efficacy end points (at least response rate [RR]).

Data extraction and synthesis

Data were extracted independently by 2 investigators.

Main outcomes and measures

Response rate and progression-free survival (PFS) were compared for arms that used a personalized strategy (biomarker selection) vs those that did not. Overall survival was not analyzed owing to insufficient data.

Results

A total of 346 studies published in the designated 3-year time period were included in the analysis. Multivariable analysis (meta-regression and weighted multiple regression models) demonstrated that the personalized approach independently correlated with a significantly higher median RR (30.6% [95% CI, 25.0%-36.9%] vs 4.9% [95% CI, 4.2%-5.7%]; P < .001) and a longer median PFS (5.7 [95% CI, 2.6-13.8] vs 2.95 [95% CI, 2.3-3.7] months; P < .001). Targeted therapy arms that used a biomarker-based selection strategy (n = 57 trials) were associated with statistically improved RR compared with targeted therapy arms (n = 177 arms) that did not (31.1% [95% CI, 25.4%-37.4%] vs 5.1% [95% CI, 4.3%-6.0%]; P < .001). Nonpersonalized targeted arms had outcomes comparable with those that tested a cytotoxic agent (median RR, 5.1% [95% CI, 4.3%-6.0%] vs 4.7% [95% CI, 3.6%-6.2%]; P = .63; respectively; median PFS, 3.3 [95% CI, 2.6-4.0] months vs 2.5 [95% CI, 2.0-3.7] months; P = .22). Personalized arms using a "genomic (DNA) biomarker" had higher median RR than those using a "protein biomarker" (42.0% [95% CI, 33.7%-50.9%] vs 22.4% [95% CI, 15.6%-30.9%]; P = .001). The median treatment-related mortality was not statistically different for arms that used a personalized strategy vs not (1.89% [95% CI, 1.36%-2.61%] vs 2.27% [95% CI, 1.97%-2.62%]; P = .31).

Conclusions and relevance

In this meta-analysis, most phase 1 trials of targeted agents did not use a biomarker-based selection strategy. However, use of a biomarker-based approach was associated with significantly improved outcomes (RR and PFS). Response rates were significantly higher with genomic vs protein biomarkers. Studies that used targeted agents without a biomarker had negligible response rates.

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Read article at publisher's site: https://doi.org/10.1001/jamaoncol.2016.2129

Read article for free, from open access legal sources, via Unpaywall: https://jamanetwork.com/journals/jamaoncology/articlepdf/2527365/coi160039.pdf

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Funding

Funders who supported this work.

NCI NIH HHS (1)

Grant ID: P30 CA016672
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