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Abstract

Background/Aims:

In pediatric oncology, a Phase II trial often utilizes a safety run-in phase followed by an efficacy phase that enrolls at the dose level selected based on the safety run-in. Different from a Phase I trial, a Phase II safety run-in often assesses a very small number of dose levels. In the context of a safety run-in that assesses two or three dose levels, this article aims to compare three design methods, including the algorithm-based designs 3 + 3 and Rolling 6, and the model-assisted designs such as the Bayesian optimal interval design.

Methods:

Extensive simulations were conducted to evaluate and compare operating characteristics of the three design methods for a safety run-in with two or three dose levels, varying the starting dose level.

Results:

The performance of algorithm-based and model-assisted designs can be influenced by selection of the starting dose level, with trials starting at a lower dose level having a higher probability of selecting a low dose or considering all doses as toxic. The impact is larger for 3 + 3 and Rolling 6 but to a lesser extent for Bayesian optimal interval design. For a safety run-in with two dose levels, using 3 + 3 or Rolling 6 and starting at the higher dose often lead to similar performance to Bayesian optimal interval design. For safety run-in with three dose levels, starting at the middle dose with 3 + 3, Rolling 6 or Bayesian optimal interval design is a good compromise between improving correct dose selection and imposing a toxic dose to less patients.

Conclusions:

Despite being sensitive to the starting dose level, the 3 + 3, Rolling 6 and Bayesian optimal interval designs overall demonstrate reasonable performance, which can be further improved with wise selection of the starting dose level. The Rolling 6 design remains the recommended design method especially if pharmacokinetics is important or required with this design having the feature of treating six patients per dose level. When designing a safety run-in, selection of a design method or selection of a starting dose should consider both the performance of the design approaches with different choices of a starting dose level and the magnitude of safety concerns with the dose levels under investigation.

Keywords

Phase II safety run-in design algorithm-based model-assisted starting dose level dose-finding

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References

Lee

Skolnik

Adamson

PC.

Pediatric phase I trials in oncology: an analysis of study conduct efficiency. J Clin Oncol 2005; 23(33): 8431–8441.

Storer

BE.

Design and analysis of phase I clinical trials. Biometrics 1989; 45(3): 925–937.

Skolnik

Barrett

Jayaraman

, et al. Shortening the timeline of pediatric phase I trials: the rolling six design. J Clin Oncol 2008; 26(2): 190–195.

Onar-Thomas

Xiong

A simulation-based comparison of the traditional method, Rolling-6 design and a frequentist version of the continual reassessment method with special attention to trial duration in pediatric phase I oncology trials. Contemp Clin Trials 2010; 31(3): 259–270.

Liu

Yuan

Bayesian optimal interval designs for phase I clinical trials. J R Stat Soc Ser C Appl Stat 2015; 64: 507–523.

Liu

, et al. A modified toxicity probability interval method for dose-finding trials. Clin Trials 2010; 7(6): 653–663.

Yuan

Lee

Hilsenbeck

SG.

Model-assisted designs for early-phase clinical trials: simplicity meets superiority. JCO Precis Oncol 2019; 3: PO.19.00032.

O’Quigley

Zohar

Retrospective robustness of the continual reassessment method. J Biopharm Stat 2010; 20(5): 1013–1025.

O’Quigley

Conaway

Continual reassessment and related dose-finding designs. Stat Sci 2010; 25(2): 202–216.

10.

O’Quigley

Chevret

Methods for dose finding studies in cancer clinical trials: a review and results of a Monte Carlo study. Stat Med 1991; 10(11): 1647–1664.

11.

O’Quigley

Pepe

Fisher

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

12.

Guo

Wang

Yang

, et al. A Bayesian interval dose-finding design addressing Ockham’s razor: mTPI-2. Contemp Clin Trials 2017; 58: 23–33.

13.

Garrett-Mayer

The continual reassessment method for dose-finding studies: a tutorial. Clin Trials 2006; 3(1): 57–71.

14.

Collins

Zaharko

Dedrick

, et al. Potential roles for preclinical pharmacology in phase I clinical trials. Cancer Treat Rep 1986; 70(1): 73–80.

15.

Faries

Practical modifications of the continual reassessment method for phase I cancer clinical trials. J Biopharm Stat 1994; 4(2): 147–164.

16.

Korn

Midthune

Chen

, et al. A comparison of two phase I trial designs. Stat Med 1994; 3013(18): 1799–1806.

17.

Goodman

Zahurak

Piantadosi

Some practical improvements in the continual reassessment method for phase I studies. Stat Med 1995; 14(11): 1149–1161.

18.

Moller

An extension of the continual reassessment methods using a preliminary up-and-down design in a dose finding study in cancer patients, in order to investigate a greater range of doses. Stat Med 1995; 14(9–10): 911–22. Discussion 923.

19.

Piantadosi

Fisher

Grossman

Practical implementation of a modified continual reassessment method for dose-finding trials. Cancer Chemother Pharmacol 1998; 41(6): 429–436.

20.

Heyd

Carlin

BP.

Adaptive design improvements in the continual reassessment method for phase I studies. Stat Med 1999; 18(11): 1307–1321.

21.

O’Quigley

Continual reassessment designs with early termination. Biostatistics 2002; 3(1): 87–99.

22.

Zhou

Murray

Pan

, et al. Comparative review of novel model-assisted designs for phase I clinical trials. Stat Med 2018; 37(14): 2208–2222.

23.

Le Tourneau

Lee

Siu

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

24.

Arbuck

SG.

Workshop on phase I study design. Ann Oncol 1996; 7(6): 567–573.

25.

Lin

Shih

WJ.

Statistical properties of the traditional algorithm-based designs for phase I cancer clinical trials. Biostatistics 2001; 2(2): 203–215.

26.

Nebiyou Bekele

Dose-finding in phase I clinical trials based on toxicity probability intervals. Clin Trials 2007; 4(3): 235–244.

27.

Ivanova

Escalation, group and A + B designs for dose-finding trials. Stat Med 2006; 25(21): 3668–3678.

28.

Takeda

Komatsu

Morita

Bayesian dose-finding phase I trial design incorporating pharmacokinetic assessment in the field of oncology. Pharm Stat 2018; 17(6): 725–733.

29.

Hogan

Rheingold

Bhatla

, et al. Induction toxicities are more frequent in young adults compared to children treated on the Children’s Oncology Group (COG) first relapse B-lymphoblastic leukemia clinical trial AALL1331. Blood 2018; 132 (Suppl. 1): 1382.

30.

Gupta

Anderson

Pappo

, et al. Patterns of chemotherapy-induced toxicities in younger children and adolescents with rhabdomyosarcoma: a report from the Children’s Oncology Group Soft Tissue Sarcoma Committee. Cancer 2012; 118(4): 1130–1137.

31.

Boissel

Baruchel

Acute lymphoblastic leukemia in adolescent and young adults: treat as adults or as children?

Blood 2018; 132(4): 351–361.

32.

Athauda

Nankivell

Langley

, et al. Impact of sex and age on chemotherapy efficacy, toxicity and survival in localised oesophagogastric cancer: a pooled analysis of 3265 individual patient data from four large randomised trials (OE02, OE05, MAGIC and ST03). Eur J Cancer 2020; 137: 45–56.

33.

Dahi

Lee

Devlin

, et al. Toxicities of high-dose chemotherapy and autologous hematopoietic cell transplantation in older patients with lymphoma. Blood Adv 2021; 5(12): 2608–2618.

34.

Mirsoian

Bouchlaka

Sckisel

, et al. Impact of age and body fat on increased toxicity following systemic immunotherapy (P1235). J Immunol 2013; 190(1 Suppl.): 188. 20.

35.

Løhmann

Abrahamsson

, et al. Effect of age and body weight on toxicity and survival in pediatric acute myeloid leukemia: results from NOPHO-AML 2004. Haematologica 2016; 101(11): 1359–1367.

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Comparison of design methods for a safety run-in phase of a phase II clinical trial

Abstract

Background/Aims:

Methods:

Results:

Conclusions:

Keywords

Get full access to this article

References

Supplementary Material