The equivalence trial

NATIONAL VETERINARY S C H O O L T O U L O U S E The equivalence trial Didier Concordet d.concordet@envt.fr

Comparison of two treatments Aim of all trials : to compare treatments on the population of individuals Population of animals Treatment effect R = 17.8 T =16.8 Impossible in practice

A two-steps method Sampling Sample of animals Population of animals

Effect of sampling Sample of animals Treatment effect XR = 16.2 XT =17.8

A two-steps method Inference Population of animals Sample of animals

Effect of inference Truth in the population Observed on the samples R = 17.8 XR = 16.2 T =16.8 XT =17.8 Lead to a wrong conclusion Ref > New Treatment T New Treatment T > Ref

A good trial Minimize the risk of bias in sampling Minimize the risk of a wrong conclusion in inference - All Randomised Study Animals - Per Protocol Set of Study Animals - Response Variable - Experimental (study) design - Consumer Risk - Producer Risk - Relevant difference

Tree kinds of study R - D1 T Non inferiority R + D1 T Superiority D1T- R D2 Equivalence study

Non inferiority R - D1 Values of T R R - D1 T Unacceptable for primary efficacy variable in clinical trial Does not prove that the treatment T works

Superiority R + D1 Values of T R R + D1 T Primary efficacy variable in clinical trials

Equivalence Values of T R + D2 R - D1 R Equivalence range Does not prove that the treatment T works For secondary efficacy variables in clinical trials

Equivalence Equivalence range Clinical effect Values of T R R - D1 R + D2

Equivalence Clinical effect Values of T R R - D1 R + D2

Even with a good question, a poor design leads to poor conclusions Superiority clinical trials REFERENCE New TRT Cure rate = 79% N = 2100 Cure rate = 83% N = 2400 Reference < New TRT (P<0.001)

Even with a good question, a poor design leads to poor conclusions Superiority trials Clinical trial 1 Clinical trial 2 REFERENCE New TRT REFERENCE New TRT Cure rate = 90% N = 2000 Cure rate = 96% N = 1000 Cure rate = 50% N = 400 Cure rate = 63% N = 1100 New TRT < Ref P<0.001 New TRT< Ref P<0.001 Conclusion : Reference > New TRT

Even with a good question, a poor design leads to poor conclusions Superiority clinical trials REFERENCE New TRT X = 39 N = 100 SD = 1 X = 37 N = 100 SD = 1 Reference < New TRT (P<0.001)

Even with a good question, a poor design leads to poor conclusions Superiority trials Clinical trial 1 Clinical trial 2 REFERENCE New TRT REFERENCE New TRT X = 30 N = 10 SD = 1 X = 32 N = 50 SD = 1 X = 40 N = 90 SD = 1 X = 42 N = 50 SD = 1 New TRT < Ref P<0.001 New TRT< Ref P<0.001 Conclusion : Reference > New TRT

N 3 3 Usual statistical tests are not intended to answer to useful questions Efficacy variable on two groups of dogs Student t-test Ref Test P = 0.23 20.0 Mean 15.4 2.6 2.4 SD Conclusion : “EQUIVALENCE” In the population R = 14.5 ; T =19.7 this difference is clinically important

N 15 15 Comparison of two treatments Efficacy variable on two groups of dogs Student t-test Ref Test P = 0.03 Study 1 18.1 Mean 16.0 2.6 2.4 SD Conclusion : NO EQUIVALENCE In the population R = 16.8 ; T =17.8 This difference is not clinically important

N 15 15 Comparison of two formulations Efficacy variable on two groups of dogs Ref Test Student t-test P = 0.26 Study 2 18.1 Mean 16.0 5.1 4.9 SD Conclusion : EQUIVALENCE In the population R = 16.8 ; T =17.8 This difference is not clinically important

Consequences Small sample size Large variability "Equivalence" Large samples size Small variability Penalty for companies to show equivalence An ill-posed problem that encourages poor trials A bad answer to a wrong question

Too restrictive and not relevant Tand R are close A wrong question? Classical hypotheses for student t-test T = population mean for test treatment R =population mean for reference treatment H 0 : T= R Treatments areequivalent H 1 : T R Treatments arenotequivalent

A bad answer ? Classical test of null hypothesis (student t-test) H 0 : T= R Treatments areequivalent H 1 : T R Treatments arenotequivalent The controlled risk a = risk to wrongly reject H0 = risk to declare not equivalent formulations that are equivalent = risk for drug companies Not important from a regulatory point of view The consumer risk is uncontrolled

Bioequivalence : objectives Check that T and R are close with regard to clinical relevance Control the consumer risk risk to declare equivalent treatments that are not

Check that T andR are close Close in an absolute way D1T- R D2 bioequivalence T- R< D1 or D2 < T- R bioinequivalence Close in a relative way bioequivalence bioinequivalence [D1 ; D2] = equivalence range (to be discussed)

Bioinequivalence H0 Bioinequivalence H0 D1 D2 T- R Possible values of Equivalence range Control the consumer risk A test controls the risk to wrongly choose the H1 hypothesis Consumer risk : the risk to wrongly conclude to bioequivalence Bioequivalence H1

H0 : H1 : Hypotheses of a bioequivalence study Additive hypotheses H0 : T- R< D1 or D2 < T- R bioinequivalence H1 : D1T- R D2 bioequivalence Multiplicative hypotheses bioinequivalence bioequivalence [D1 ; D2] = equivalence range

The equivalence trial

The equivalence trial

Presentation Transcript

Equivalence Relations

Logical equivalence

Equivalence Testing

Equivalence Testing

Equivalence Partitioning

Ensemble equivalence

Equivalence Classes

Logical Equivalence

Ambivalent Equivalence

Fault Equivalence

Equivalence:

The Newtonian equivalence principle

Equivalence Relations

Equivalence Relations

CONFOUNDING EQUIVALENCE

Equivalence Checking

Equivalence Relations

Equivalence Testing

Equivalence Relations

Equivalence

Equivalence Theory

The Newtonian equivalence principle