Sage Journals: Discover world-class research

Abstract

Background:

Phase I and Phase II clinical trials aim at identifying a dose that is safe and active. Both phases are increasingly combined. For Phase I/II trials, two main types of designs are debated: a dose-escalation stage to select the maximum tolerated dose, followed by an expansion cohort to investigate its activity (dose-escalation followed by an expansion cohort), or a joint modelling to identify the best trade-off between toxicity and activity (efficacy–toxicity). We explore this question in the context of a paediatric Phase I/II platform trial.

Methods:

In series of simulations, we assessed the operating characteristics of dose-escalation followed by an expansion cohort (DE-EC) designs without and with reassessment of the maximum tolerated dose during the expansion cohort (DE-ECext) and of the efficacy–toxicity (EffTox) design. We investigated the probability to identify an active and tolerable agent, that is, the percentage of correct decision, for various dose-toxicity activity scenarios.

Results:

For a large therapeutic index, the percentage of correct decision reached 96.0% for efficacy–toxicity versus 76.1% for dose-escalation followed by an expansion cohort versus 79.6% for DE-ECext. Conversely, when all doses were deemed not active, the percentage of correct decision was 47% versus 55.9% versus 69.2%, respectively, for efficacy–toxicity, dose-escalation followed by an expansion cohort and DE-ECext. Finally, in the case of a narrow therapeutic index, the percentage of correct decision was 48.0% versus 64.3% versus 67.2%, respectively, efficacy–toxicity, dose-escalation followed by an expansion cohort and DE-ECext.

Conclusion:

As narrow indexes are common in oncology, according to the present results, the sequential dose-escalation followed by an expansion cohort is recommended. The importance to re-estimate the maximum tolerated dose during the expansion cohort is confirmed. However, despite their theoretical advantages, Phase I/II designs are challenged by the variations in populations between the Phase I and the Phase II parts and by the lagtime in the evaluation of toxicity and activity.

Keywords

Phase I-II design dose-finding expansion cohort efficacy–toxicity design simulations

Get full access to this article

View all access options for this article.

References

Moreno

Pearson

ADJ

Paoletti

, et al. Early phase clinical trials of anticancer agents in children and adolescents: an ITCC perspective. Nat Rev Clin Oncol 2017; 14(8): 497–507.

Iasonos

O’Quigley

Design considerations for dose-expansion cohorts in phase I trials. J Clin Oncol 2013; 31(31): 4014–4021.

Yin

Bayesian dose-finding in phase I/II clinical trials using toxicity and efficacy odds ratios. Biometrics 2006; 62(3): 777–784.

Thall

Cook

JD.

Dose-finding based on efficacy-toxicity trade-offs. Biometrics 2004; 60(3): 684–693.

Wages

Conaway

MR.

Phase I/II adaptive design for drug combination oncology trials. Stat Med 2014; 33(12): 1990–2003.

Paoletti

Postel-Vinay

Phase I-II trial designs: how early should efficacy guide the dose recommendation process. Ann Oncol 2018; 29(3): 540–541.

Gupta

Hunsberger

Boerner

, et al. Meta-analysis of the relationship between dose and benefit in phase I targeted agent trials. J Natl Cancer Inst 2012; 104(24): 1860–1866.

Geoerger

Schleiermacher

Pierron

, et al. Abstract CT004: European pediatric precision medicine program in recurrent tumors: first results from MAPPYACTS molecular profiling trial towards AcSé-ESMART proof-of-concept study. Cancer Res 2017; 77(13 Suppl.): CT004.

O’Quigley

Pepe

Fisher

Continual reassessment method: a practical design for phase I clinical trials in cancer. Biometrics 1990; 46(1): 33–48.

10.

Ensign

Gehan

Kamen

, et al. An optimal three-stage design for phase II clinical trials. Stat Med 1994; 13(17): 1727–1736.

11.

Le Tourneau

Lee

Siu

. Dose escalation methods in phase I cancer clinical trials. J Natl Cancer Inst 2009; 101(10): 708–720.

12.

Doussau

Asselain

LeDeley

, et al. Dose-finding designs in pediatric phase I clinical trials: comparison by simulations in a realistic timeline framework. Contemp Clin Trials 2012; 33(4): 657–665.

13.

Iasonos

Wilton

Riedel

, et al. A Comprehensive comparison of the continual reassessment method to the standard 3 + 3 dose escalation scheme in phase I dose-finding studies. Clin Trials 2008; 5(5): 465–477.

14.

Fleming

TR.

One-sample multiple testing procedure for phase II clinical trials. Biometrics 1982; 38(1): 143–151.

15.

Thall

Cook

Estey

EH.

Adaptive dose selection using efficacy-toxicity trade-offs: illustrations and practical considerations. J Biopharm Stat 2006; 16(5): 623–638.

16.

Paoletti

Kramar

A comparison of model choices for the Continual Reassessment Method in phase I cancer trials. Stat Med 2009; 28(24): 3012–3028.

17.

Cheung

YK.

Dose finding by the continual reassessment method. New York: Chapman & Hall; CRC Press, 2011.

18.

MD Anderson Cancer Center. Software download kiosk: EffTox, https://biostatistics.mdanderson.org/softwaredownload/SingleSoftware.aspx?Software_Id=2 (2017, accessed 20 June 2018).

19.

Sleijfer

Wiemer

Dose selection in phase I studies: why we should always go for the top. J Clin Oncol 2008; 26(10): 1576–1578.

20.

Roberts

Jr Goulart

Squitieri

, et al. Trends in the risks and benefits to patients with cancer participating in phase 1 clinical trials. JAMA 2004; 292(17): 2130–2140.

21.

Yuan

Nguyen

Thall

PF.

Bayesian designs for phase I-II clinical trials. New York: Chapman & Hall; CRC Biostatistics Series, 2017, p. 316.

22.

Yan

Thall

, et al. Phase I-II clinical trial design: a state-of-the-art paradigm for dose finding. Ann Oncol 2018; 29(3): 694–699.

23.

European Medicines Agency/Committee for Medicinal Products for Human (EMA/CHMP) Use. Guideline on the evaluation of anticancer medicinal products in man, 2016, http://www.ema.europa.eu/docs/en_GB/document_library/Scientific_guideline/2016/03/WC500203320.pdf

24.

Jin

Liu

Thall

, et al. Using data augmentation to facilitate conduct of phase I-II clinical trials with delayed outcomes. J Am Stat Assoc 2014; 109(506): 525–536.

25.

US Food & Drug Administration. Approved drugs – modification of the dosage regimen for nivolumab, https://www.fda.gov/drugs/informationondrugs/approveddrugs/ucm520871.htm (2016, accessed 19 March 2019).

26.

Boonstra

Shen

Taylor

JMG

, et al. A statistical evaluation of dose expansion cohorts in phase I clinical trials. J Natl Cancer Inst 2015; 107(3). DOI: 10.1093/ jnci/dju429.

27.

Boonstra

Braun

Taylor

JMG

, et al. Statistical controversies in clinical research: building the bridge to phase II – efficacy estimation in dose-expansion cohorts. Ann Oncol 2017; 28(7): 1427–1435.

28.

Food and Drug Administration. Expansion cohorts: use in first-in-human clinical trials to expedite development of oncology drugs and biologics guidance for industry, https://www.fda.gov/media/115172/download (2018, accessed 19 March 2019).

Supplementary Material

Please find the following supplemental material available below.

For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.

For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.

0.00 MB

0.15 MB

Sequential or combined designs for Phase I/II clinical trials? A simulation study

Abstract

Background:

Methods:

Results:

Conclusion:

Keywords

Get full access to this article

References

Supplementary Material