A robust Bayesian meta-analytic approach to incorporate animal data into phase I oncology trials

Abstract

Before a first-in-man trial is conducted, preclinical studies are performed in animals to help characterise the safety profile of the new medicine. We propose a robust Bayesian hierarchical model to synthesise animal and human toxicity data, using scaling factors to translate doses administered to different animal species onto an equivalent human scale. After scaling doses, the parameters of dose-toxicity models intrinsic to different animal species can be interpreted on a common scale. A prior distribution is specified for each translation factor to capture uncertainty about differences between toxicity of the drug in animals and humans. Information from animals can then be leveraged to learn about the relationship between dose and risk of toxicity in a new phase I trial in humans. The model allows human dose-toxicity parameters to be exchangeable with the study-specific parameters of animal species studied so far or non-exchangeable with any of them. This leads to robust inferences, enabling the model to give greatest weight to the animal data with parameters most consistent with human parameters or discount all animal data in the case of non-exchangeability. The proposed model is illustrated using a case study and simulations. Numerical results suggest that our proposal improves the precision of estimates of the toxicity rates when animal and human data are consistent, while it discounts animal data in cases of inconsistency.

Keywords

Bayesian hierarchical model historical data oncology phase I clinical trials robustness

Get full access to this article

View all access options for this article.

References

Viele

Berry

Neuenschwander

, et al. Use of historical control data for assessing treatment effects in clinical trials. Pharm Stat 2014; 13: 41–54.

Neuenschwander

Roychoudhury

Schmidli

. On the use of co-data in clinical trials. Stat Biopharm Res 2016; 8: 345–354.

van Rosmalen

Dejardin

van Norden

, et al. Including historical data in the analysis of clinical trials: is it worth the effort?. Stat Method Med Res 2018; 27: 3167–3182. .

Eichler

Pétavy

Pignatti

, et al. Access to patient-level trial data – a boon to drug developers. N Engl J Med 2013; 369: 1577–1579.

Eichler

Bloechl-Daum

Bauer

, et al. “Threshold-crossing”: a useful way to establish the counterfactual in clinical trials?. Clin Pharm Ther 2016; 100: 699–712.

Hobbs

Carlin

Sargent

. Adaptive adjustment of the randomization ratio using historical control data. Clin Trial 2013; 10: 430–440.

French

Wang

Warnock

, et al. Historical control monotherapy design in the treatment of epilepsy. Epilepsia 2010; 51: 1936–1943.

French

Temkin

Shneker

, et al. Lamotrigine XR conversion to monotherapy: first study using a historical control group. Neurotherapeutics 2012; 9: 176–184.

Wadsworth

Hampson

Jaki

. Extrapolation of efficacy and other data to support the development of new medicines for children: a systematic review of methods. Stat Method Med Res 2018; 27: 398–413.

10.

Dane

Wetherington

. Statistical considerations associated with a comprehensive regulatory framework to address the unmet need for new antibacterial therapies. Pharm Stat 2014; 13: 222–228.

11.

Takeda

Morita

. Bayesian dose-finding phase I trial design incorporating historical data from a preceding trial. Pharm Stat 2018; 17: 372–382. .

12.

Cunanan

Koopmeiners

. Hierarchical models for sharing information across populations in phase I dose-escalation studies. Stat Method Med Res 2018; 27: 3447–3459.

13.

Ibrahim

Chen

. Power prior distributions for regression models. Stat Sci 2000; 15: 46–60.

14.

Duan

Smith

. Using power priors to improve the binomial test of water quality. J Agric Biol Environ Stat 2006; 11: 151–168.

15.

Hobbs

Carlin

Mandrekar

, et al. Hierarchical commensurate and power prior models for adaptive incorporation of historical information in clinical trials. Biometrics 2011; 67: 1047–1056.

16.

Hobbs

Sargent

Carlin

. Commensurate priors for incorporating historical information in clinical trials using general and generalized linear models. Bayesian Anal 2012; 7: 639–674.

17.

Neuenschwander

Capkun-Niggli

Branson

, et al. Summarizing historical information on controls in clinical trials. Clin Trial 2010; 7: 5–18.

18.

Schmidli

Gsteiger

Roychoudhury

, et al. Robust meta-analytic-predictive priors in clinical trials with historical control information. Biometrics 2014; 70: 1023–1032.

19.

O'Quigley

Pepe

Fisher

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

20.

Paoletti

Kramar

. A comparison of model choices for the continual reassessment method in phase I cancer trials. Stat Med 2009; 28: 3012–3028.

21.

Babb

Rogatko

Zacks

. Cancer phase I clinical trials: efficient dose escalation with overdose control. Stat Med 1998; 17: 1103–1120.

22.

Whitehead

Using Bayesian decision theory in dose-escalation studies [chapter 7]. In: Chevret

(eds). Statistical methods for dose-finding experiments: statistics in practice, Chichester, UK: Wiley-Blackwell, 2006, pp. 149–171. .

23.

Storer

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

24.

Jaki

Clive

Weir

. Principles of dose finding studies in cancer: a comparison of trial designs. Cancer Chemother Pharmacol 2013; 71: 1107–1114.

25.

Whitehead

Williamson

. Bayesian decision procedures based on logistic regression models for dose-finding studies. J Biopharm Stat 1998; 8: 445–467.

26.

Neuenschwander

Branson

Gsponer

. Critical aspects of the Bayesian approach to phase I cancer trials. Stat Med 2008; 27: 2420–2439.

27.

FDA. Estimating the maximum safe starting dose in initial clinical trials for therapeutics in adult healthy volunteers, Rockville, MD: US Food and Drug Administration, 2005.

28.

Reigner

Blesch

. Estimating the starting dose for entry into humans: principles and practice. Eur J Clin Pharmacol 2001; 57: 835–845.

29.

Neuenschwander

Matano

Tang

, et al., A Bayesian industry approach to phase I combination trials in oncology [chapter 6]. In: Zhao

Yang

(eds). Statistical methods in drug combination studies, Boca Raton, FL: Chapman & Hall, 2014.

30.

Kamrin

. Toxicology – a primer on toxicology principles and applications, Chelsea, US: CRC Press, 1988. .

31.

West

Brown

. The origin of allometric scaling laws in biology from genomes to ecosystems: towards a quantitative unifying theory of biological structure and organization. J Exp Biol 2005; 208: 1575–1592.

32.

Sharma

McNeill

. To scale or not to scale: the principles of dose extrapolation. Br J Pharmacol 2009; 157: 907–921.

33.

Baker

Verweij

Rowinsky

, et al. Role of body surface area in dosing of investigational anticancer agents in adults, 1991–2001. J Natl Cancer Inst 2002; 94: 1883–1888.

34.

Lunn

Spiegelhalter

Thomas

, et al. The bugs project: evolution, critique and future directions. Stat Med 2009; 28: 3049–3067.

35.

Roman

VerHoeve

Schadt

, et al. Ocular toxicity of auy922 in pigmented and albino rats. Toxicol Appl Pharmacol 2016; 309(Suppl C): 55–62.

36.

Sessa

Shapiro

Bhalla

, et al. First-in-human phase I dose-escalation study of the hsp90 inhibitor auy922 in patients with advanced solid tumors. Clin Cancer Res 2013; 19: 3671–3680.

37.

Gelman

Jakulin

Pittau

, et al. A weakly informative default prior distribution for logistic and other regression models. Ann Appl Stat 2008; 2: 1360–1383.

38.

Morita

Thall

Müller

. Determining the effective sample size of a parametric prior. Biometrics 2008; 64: 595–602.

39.

Zhou

Whitehead

. Practical implementation of Bayesian dose-escalation procedures. Drug Inform J 2003; 37: 45–59.

40.

O'Quigley

Paoletti

Maccario

. Non-parametric optimal design in dose finding studies. Biostatistics 2002; 3: 51–56.

41.

Dresser

. First-in-human trial participants: not a vulnerable population, but vulnerable nonetheless. J Law Med Ethics 2009; 37: 38–50.

42.

Cook

Hansen

Siu

, et al. Early phase clinical trials to identify optimal dosing and safety. Mol Oncol 2015; 9: 997–1007.

43.

Gueorguieva

Aarons

Rowland

. Diazepam pharamacokinetics from preclinical to phase I using a Bayesian population physiologically based pharmacokinetic model with informative prior distributions in winbugs. J Pharmacokinet Pharmacodyn 2006; 33: 571–594.

44.

Kouno

Katsumata

Mukai

, et al. Standardization of the body surface area (BSA) formula to calculate the dose of anticancer agents in Japan. Jpn J Clin Oncol 2003; 33: 309–313.

45.

Gerina-Berzina

Vikmanis

Teibe

, et al. Anthropometric measurements of the body composition of cancer patients determine the precise role of the body surface area and the calculation of the dose of chemotherapy. Pap Anthropol 2012; 21: 56–71.

46.

Department of Health. Expert scientific group on phase one clinical trials: final report. London: HMSO, 2006. Available at: http://www.dh.gov.uk/en/Publicationsandstatistics/Publications/PublicationsPolicyAndGuidance/DH_063117 (accessed 18 December 2018).

47.

Tang

Persky

Hochhaus

, et al. Pharmacokinetic aspects of biotechnology products. J Pharm Sci 2004; 93: 2184–2204.

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

0.18 MB