Mark Pletcher 6/10/2011

1. Quantifying Treatment Effects Mark Pletcher 6/10/2011

2. Rationale • Any treatment involves tradeoffs • Weigh benefits against risks/costs Benefit $$ Harm

3. Rationale • Sometimes the decision is difficult! $$ Harm Benefit

4. Rationale And this one? How big is this box? $$ Harm Benefit

5. Rationale • Tests can help us understand who is most likely to benefit from a treatment And this one? How big is this box? $$ Harm Benefit

6. Rationale • Tests can help us understand who is most likely to benefit from a treatment • Rapid strep to decide who will benefit from penicillin • BNP to decide who will benefit from furosemide • CRP to decide who will benefit from statins

7. Rationale • The utility of a test depends on: • How beneficial the treatment is • How harmful the treatment is • How much the test tells us about these benefits and harms in a given individual • Risk of harm from the test itself

8. Rationale • The utility of a test depends on: • How beneficial the treatment is • How harmful the treatment is • How much the test tells us about these benefits and harms in a given individual • Risk of harm from the test itself The topic for this lecture

9. Outline • Is an intervention really beneficial? • How beneficial is it? • Pitfalls • Examples

10. Is the intervention beneficial? • Randomized trials compare an outcome in treated to untreated persons • MI in 10% vs. 15% • Duration of flu symptoms 3 vs. 5 days

11. Is the intervention beneficial? • Randomized trials compare an outcome in treated to untreated persons • MI in 10% vs. 15% • Duration of flu symptoms 3 vs. 5 days • *Statistics* are used to decide if should reject the “null hypothesis” and accept that the intervention is beneficial

12. Is the intervention beneficial? • But statistics cannot help us interpret effect size

13. Quantifying the Benefit • Effect size • How do we summarize and communicate this? • What is really important for clinicians and policymakers?

14. Quantifying the Benefit • Effect size • How do we summarize and communicate this? • What is really important for clinicians and policymakers? • Example: MI in 10% vs. 15% • Q: What do we do with these two numbers?

15. Quantifying the Benefit • Two simple possibilities: • 10% / 15% = 0.66 • 15% - 10% = 5%

16. Quantifying the Benefit • Two simple possibilities: • 10% / 15% = 0.66 • 15% - 10% = 5% Relative Risk (RR) Absolute Risk Reduction (ARR)

17. Quantifying the Benefit • Relative risk as a measure of effect size • RR = 0.66 – is this big or small?

18. Quantifying the Benefit • Relative risk as a measure of effect size • RR = 0.66 – is this big or small? • MI: 10% vs. 15% in 10 years • Death: 50% vs. 75% in 3 years • Basal Cell CA: 2% vs. 3% in lifetime

19. Quantifying the Benefit • Relative risk as a measure of effect size • RR = 0.66 – is this big or small? • MI: 10% vs. 15% in 10 years • Death: 50% vs. 75% in 3 years • Basal Cell CA: 2% vs. 3% in lifetime Medium Big Small

20. Quantifying the Benefit • Relative risk as a measure of effect size • RR = 0.66 – is this big or small? • MI: 10% vs. 15% in 10 years • Death: 50% vs. 75% in 3 years • Basal Cell CA: 2% vs. 3% in lifetime • RR is NOT the best measure of effect size

21. Quantifying the Benefit • Absolute risk reduction (ARR) is better • ARR = Risk difference = Risk2 – Risk1

22. Quantifying the Benefit • Absolute risk reduction (ARR) is better RRARR MI: 10% vs. 15% in 10 years .66 5% Death: 50% vs. 75% in 3 years .66 25% Basal Cell CA: 2% vs. 3% in lifetime .66 1%

23. Q: What does the 34% reduction mean?

24. Nimotop® Ad Graph Risk1 = 61/278 = 21.8% Risk2 = 92/276 = 33% RR = 22%/33% = .66 ARR = 33% - 22% = 11% 33% 22%

25. Nimotop® Ad Graph Risk1 = 61/278 = 21.8% Risk2 = 92/276 = 33% RR = 22%/33% = .66 ARR = 33% - 22% = 11% 33% 22% What is 34%?

26. Nimotop® Ad Graph Risk1 = 61/278 = 21.8% Risk2 = 92/276 = 33% RR = 22%/33% = .66 ARR = 33% - 22% = 11% 33% 22% Relative risk reduction (RRR) = 1 – RR = 1-.66 = .34 or 34%

27. Quantifying the Benefit • RRR is no better than RR RRRRR MI: 10% vs. 15% in 10 years .66 34% Death: 50% vs. 75% in 3 years .66 34% Basal Cell CA: 2% vs. 3% in lifetime .66 34%

28. Quantifying the Benefit • RRR is ALWAYS bigger than ARR • (unless untreated risk is 100%)

29. Quantifying the Benefit • BEWARE of risk reduction language!! • ARR or RRR? • “We reduced risk by 34%” • “Risk was 34% lower”

30. Quantifying the Benefit • BEWARE of risk reduction language!! • ARR or RRR? • “We reduced risk by 34%” can’t tell • “Risk was 34% lower” can’t tell • Very hard to be unambiguous!

31. Quantifying the Benefit • Another reason that ARR is better: • Translate it into “Number Needed to Treat” • NNT = 1/ARR

32. Why is NNT = 1/ARR? 100 SAH patients treated 67 no stroke anyway 33 strokes with no treatment R2 11 strokes prevented R1 22 strokes with with treatment 22 strokes with Nimotop®

33. Why is NNT 1/ARR? Treat 100 SAH patients  prevent 11 strokes Ratio manipulation: 100 treated 1 treated 9.1 treated 11 prevented .11 prevented 1 prevented = =

34. Why is NNT 1/ARR? Treat 100 SAH patients  prevent 11 strokes Ratio manipulation: 100 treated 1 treated 9.1 treated 11 prevented .11 prevented 1 prevented = = 1/ARR = NNT

35. Why is NNT 1/ARR? NNT best expressed in a sentence: “Need to treat 9.1 persons with SAH using nimodipine to prevent 1 cerebral infarction”

36. Quantifying the Benefit • NNT calculation practice RRARRNNT? MI: 10% vs. 15% in 10 years .66 5% Death: 50% vs. 75% in 3 years .66 25% Basal Cell CA: 2% vs. 3% in lifetime .66 1%

37. Quantifying the Benefit • NNT calculation practice RRARRNNT? MI: 10% vs. 15% in 10 years .66 5% 20 Death: 50% vs. 75% in 3 years .66 25% Basal Cell CA: 2% vs. 3% in lifetime .66 1%

38. Quantifying the Benefit • NNT calculation practice RRARRNNT? MI: 10% vs. 15% in 10 years .66 5% 20 Death: 50% vs. 75% in 3 years .66 25% 4 Basal Cell CA: 2% vs. 3% in lifetime .66 1%

39. Quantifying the Benefit • NNT calculation practice RRARRNNT? MI: 10% vs. 15% in 10 years .66 5% 20 Death: 50% vs. 75% in 3 years .66 25% 4 Basal Cell CA: 2% vs. 3% in lifetime .66 1% 100

40. Quantifying the Benefit • NNT expression practice RRARRNNT? MI: 10% vs. 15% in 10 years .66 5% 20 Death: 50% vs. 75% in 3 years .66 25% 4 Basal Cell CA: 2% vs. 3% in lifetime .66 1% 100 Statins Chemo Sunscreen every day

41. Quantifying the Benefit • NNT expression practice “Need to treat 20 patients with statins for 10 years to prevent 1 MI” “Need to treat 4 patients with chemo for 3 years to prevent 1 death” “Need to treat 100 patients with sunscreen every day for their whole life to prevent 1 basal cell”

42. Example 1 • Randomized controlled trial of the effects of hip replacement vs. screws on re-operation in elderly patients with displaced hip fractures. Parker MH et al. Bone Joint Surg Br. 84(8):1150-1155.

43. Example 1 Parker MH et al. Bone Joint Surg Br. 84(8):1150-1155.

44. Example 1

45. Example 1 RR = R1/R2 = 5.2% / 39.8% = .13 RRR = 1-RR = 1-.13 = 87% ARR = R2 – R1 = 39.8% - 5.2% = 34.6% NNT = 1/ARR = 1/.346 = 3 “Need to treat 3 patients with hip replacement instead of screws to prevent 1 from needing a re-do operation”

46. Example 2 • JUPITER: Randomized controlled trial of high dose rosuvastatin in patients with LDL<130 and CRP>2.0 Ridker et al. NEJM 2008; 359:2195-207

47. Example 2 Ridker et al. NEJM 2008; 359:2195-207

48. Example 2 Ridker et al. NEJM 2008; 359:2195-207

49. Example 2 HR = (R1/R2) (from regression) = .56 RRR = 1-HR = 1-.56 = 44% ARR = R2 – R1 = 1.36 - 0.77 = .59 / 100py* = .0059 / py NNT = 1/ARR = 1/.0059 = 100/.59 = 169 pys “Need to treat 169 patients for a year to prevent 1 CVD event” Or better: “Need to treat 85 patients for 2 years to prevent 1 CVD event” (average treatment duration in trial was 1.9 years) * py = person-years

50. Example 4 Warfarin vs. placebo for atrial fibrillation WarfarinPlacebo Risk of major bleed (/yr) 1.2% 0.7% Ann Intern Med 1999; 131:492-501