The SEQTEST Procedure

Example 90.3 Testing an Effect with Early Stopping to Accept $H_0$

This example demonstrates a two-sided group sequential test that uses an error spending design with early stopping to accept the null hypothesis $H_0$ . The example is similar to Example 90.2 but with early stopping to accept $H_0$ .

A study is conducted to examine the effects of Age (years), Weight (kg), RunTime (time in minutes to run 1.5 miles), RunPulse (heart rate while running), and MaxPulse (maximum heart rate recorded while running) on Oxygen (oxygen intake rate, ml per kg body weight per minute). The primary interest is whether oxygen intake rate is associated with weight.

The hypothesis is tested using the following linear model:

$\mr{Oxygen} = \mr{Age} + \mr{Weight} + \mr{RunTime} + \mr{RunPulse} + \mr{MaxPulse}$

The null hypothesis is $H_{0}: \beta _{w}= 0$ , where $\beta _{w}$ is the regression parameter for the variable Weight. Suppose that $\beta _{w}= 0.10$ is the reference improvement that should be detected at a 0.90 level. Then the maximum information $I_{X}$ can be derived in the SEQDESIGN procedure.

Following the derivations in the section "Test for a Parameter in the Regression Model" in the chapter "The SEQDESIGN Procedure," the required sample size can be derived from

$N = I_{X} \, \, \frac{\sigma ^{2}_{y}}{(1 - r^{2}_{x}) \, \sigma ^{2}_{x}}$

where $\sigma ^{2}_{y}$ is the variance of the response variable in the regression model, $r^{2}_{x}$ is the proportion of variance of Weight explained by other covariates, and $\sigma ^{2}_{x}$ is the variance of Weight.

Further suppose that from past experience, $\sigma ^{2}_{y}=5$ , $r^{2}_{x}=0.10$ , and $\sigma ^{2}_{x}=64$ . Then the required sample size can be derived using the SAMPLESIZE statement in the SEQDESIGN procedure.

The following statements invoke the SEQDESIGN procedure and request a three-stage group sequential design for normally distributed data to test the null hypothesis of a regression parameter $H_{0}: \beta _{w}= 0$ against the alternative $H_{1}: \beta _{w} \neq 0$ :

ods graphics on;
proc seqdesign altref=0.10;
   OBFErrorFunction: design method=errfuncgamma
                            stop=accept
                            nstages=3
                            info=cum(2 3 4);

   samplesize model=reg( variance=5 xvariance=64 xrsquare=0.10);
   ods output Boundary=Bnd_Fit;
run;
ods graphics off;

By default (or equivalently if you specify ALPHA=0.05 and BETA=0.10), the procedure uses a Type I error probability 0.05 and a Type II error probability 0.10. The ALTREF=0.10 option specifies a power of $1-\beta = 0.90$ at the alternative hypothesis $H_{1}: \beta _{w}= \pm 0.10$ . The INFO=CUM(2 3 4) option specifies that the study perform the first interim analysis with information proportion $2/4=0.5$ —that is, after half of the total observations are collected.

The ODS OUTPUT statement with the BOUNDARY=BND_FIT option creates an output data set named BND_FIT which contains the resulting boundary information for the subsequent sequential tests.

The "Design Information" table in Output 90.3.1 displays design specifications and derived statistics. Since the alternative reference is specified, the maximum information is derived.

Output 90.3.1: Error Spending Design Information

The SEQDESIGN Procedure

Design: OBFErrorFunction

Design Information
Statistic Distribution	Normal
Boundary Scale	Standardized Z
Alternative Hypothesis	Two-Sided
Early Stop	Accept Null
Method	Error Spending
Boundary Key	Both
Alternative Reference	0.1
Number of Stages	3
Alpha	0.05
Beta	0.1
Power	0.9
Max Information (Percent of Fixed Sample)	103.9245
Max Information	1091.972
Null Ref ASN (Percent of Fixed Sample)	75.00521
Alt Ref ASN (Percent of Fixed Sample)	101.8099

The "Boundary Information" table in Output 90.3.2 displays information level, alternative reference, and boundary values at each stage.

Output 90.3.2: Boundary Information

Boundary Information (Standardized Z Scale) Null Reference = 0
_Stage_				Alternative		Boundary Values
	Information Level			Reference		Lower	Upper
	Proportion	Actual	N	Lower	Upper	Beta	Beta
1	0.5000	545.9862	47.39463	-2.33663	2.33663	-0.44937	0.44937
2	0.7500	818.9792	71.09195	-2.86178	2.86178	-1.13583	1.13583
3	1.0000	1091.972	94.78926	-3.30450	3.30450	-1.91428	1.91428

With ODS Graphics enabled, a detailed boundary plot with the rejection and acceptance regions is displayed, as shown in Output 90.3.3. The boundary plot also displays the information level and critical value for the corresponding fixed-sample design.

Output 90.3.3: Boundary Plot

With the MODEL=REG option in the SAMPLESIZE statement, the "Sample Size Summary" table in Output 90.3.4 displays the parameters for the sample size computation.

Output 90.3.4: Required Sample Size Summary

Sample Size Summary
Test	Reg Parameter
Parameter	0.1
Variance	5
X Variance	64
R Square (X)	0.1
Max Sample Size	94.78926
Expected Sample Size (Null Ref)	68.41207
Expected Sample Size (Alt Ref)	92.86057

The "Sample Sizes" table in Output 90.3.5 displays the required sample sizes for the group sequential clinical trial.

Output 90.3.5: Required Sample Sizes

Sample Sizes (N) Z Test for Regression Parameter
_Stage_	Fractional N		Ceiling N
_Stage_	N	Information	N	Information
1	47.39	546.0	48	553.0
2	71.09	819.0	72	829.4
3	94.79	1092.0	95	1094.4

Thus, 48, 72, and 95 individuals are needed in stages 1, 2, and 3, respectively. Since the sample sizes are derived from estimated values of $\sigma ^{2}_{y}$ , $r^{2}_{x}$ , and $\sigma ^{2}_{x}$ , the actual information levels might not achieve the target information levels. Thus, instead of specifying sample sizes in the protocol, you can specify the maximum information levels. Then if an actual information level is much less than the target level, you can increase the sample sizes for the remaining stages to achieve the desired information levels and power.

Suppose that 48 individuals are available at stage 1. Output 90.3.6 lists the first 10 observations of the trial data.

Output 90.3.6: Clinical Trial Data

First 10 Obs in the Trial Data

Obs	Oxygen	Age	Weight	RunTime	RunPulse	MaxPulse
1	54.5521	44	87.7676	11.6949	178.435	181.607
2	52.2821	40	75.4853	9.8872	184.433	183.667
3	62.1871	44	89.0638	8.7950	155.540	167.108
4	65.3269	42	67.7310	8.4577	162.926	173.877
5	59.9809	37	93.1902	9.3228	179.033	180.144
6	52.5588	47	75.9044	12.0385	177.753	175.033
7	51.7838	40	73.5422	11.6607	175.838	178.140
8	57.0024	43	81.2861	11.2219	160.963	171.770
9	48.0775	44	85.2290	13.1789	173.722	176.548
10	68.3357	38	80.2490	8.5066	171.824	184.011

The following statements use the REG procedure to estimate the slope $\beta _{w}$ and its associated standard error at stage 1:

proc reg data=Fit_1;
   model Oxygen=Age Weight RunTime RunPulse MaxPulse;
   ods output ParameterEstimates=Parms_Fit1;
run;

The following statements create and display (in Output 90.3.7) the input data set that contains slope $\beta _{w}$ and its associated standard error for the SEQTEST procedure:

data Parms_Fit1;
   set Parms_Fit1;
   if Variable='Weight';
   _Scale_='MLE';
   _Stage_= 1;
   keep _Scale_ _Stage_ Variable Estimate StdErr;
run;

proc print data=Parms_Fit1;
   title 'Statistics Computed at Stage 1';
run;

Output 90.3.7: Statistics Computed at Stage 1

Statistics Computed at Stage 1

Obs	Variable	Estimate	StdErr	_Scale_	_Stage_
1	Weight	0.04660	0.04308	MLE	1

The following statements invoke the SEQTEST procedure to test for early stopping at stage 1:

ods graphics on;
proc seqtest Boundary=Bnd_Fit
             Parms(testvar=Weight)=Parms_Fit1
             infoadj=none
             errspendadj=errfuncgamma
             stopprob
             order=lr
             ;
   ods output Test=Test_Fit1;
run;
ods graphics off;

The BOUNDARY= option specifies the input data set that provides the boundary information for the trial at stage 1, which was generated in the SEQDESIGN procedure. The PARMS=PARMS_FIT1 option specifies the input data set PARMS_FIT1 that contains the test statistic and its associated standard error at stage 1, and the TESTVAR=WEIGHT option identifies the test variable WEIGHT in the data set. The INFOADJ=NONE option maintains the information level for stage 2 at the value provided in the BOUNDARY= data set.

The ORDER=LR option uses the LR ordering to derive the p-value, the unbiased median estimate, and the confidence limits for the regression slope estimate. The ERRSPENDADJ=ERRFUNCGAMMA option adjusts the boundaries with the updated error spending values generated from a gamma cumulative error spending function.

The ODS OUTPUT statement with the TEST=TEST_FIT1 option creates an output data set named TEST_FIT1 which contains the updated boundary information for the test at stage 1. The data set also provides the boundary information that is needed for the group sequential test at the next stage.

The "Design Information" table in Output 90.3.8 displays the design specifications. By default (or equivalently if you specify BOUNDARYKEY=ALPHA), the boundary values are modified for the new information levels to maintain the Type I $\alpha$ level. The maximum information remains the same as in the BOUNDARY= data set, but the derived Type II error probability $\beta$ and power $1-\beta$ are different because of the new information level.

Output 90.3.8: Design Information

The SEQTEST Procedure

Design Information
BOUNDARY Data Set	WORK.BND_FIT
Data Set	WORK.PARMS_FIT1
Statistic Distribution	Normal
Boundary Scale	Standardized Z
Alternative Hypothesis	Two-Sided
Early Stop	Accept Null
Number of Stages	3
Alpha	0.05
Beta	0.10007
Power	0.89993
Max Information (Percent of Fixed Sample)	103.9498
Max Information	1091.97232
Null Ref ASN (Percent of Fixed Sample)	75.15846
Alt Ref ASN (Percent of Fixed Sample)	101.8296

With the STOPPROB option, the "Expected Cumulative Stopping Probabilities" table in Output 90.3.9 displays the expected stopping stage and the cumulative stopping probability of accepting the null hypothesis at each stage under various hypothetical references $\theta = c_{i} \theta _{1}$ , where $\theta _{1}$ is the alternative reference and $c_{i}=0, 0.5, 1, 1.5$ by default. You can specify other values for $c_{i}$ with the CREF= option.

Output 90.3.9: Stopping Probabilities

Expected Cumulative Stopping Probabilities Reference = CRef * (Alt Reference)
CRef	Expected Stopping Stage	Source	Stopping Probabilities
CRef	Expected Stopping Stage	Source	Stage_1	Stage_2	Stage_3
0.0000	1.895	Accept Null	0.33304	0.76607	0.95000
0.5000	2.409	Accept Null	0.17680	0.40947	0.62828
1.0000	2.918	Accept Null	0.02636	0.05453	0.10007
1.5000	2.997	Accept Null	0.00109	0.00166	0.00242

The "Test Information" table in Output 90.3.10 displays the boundary values for the test statistic. By default (or equivalently if you specify BOUNDARYSCALE=STDZ), these statistics are displayed with the standardized Z scale. The information level at stage 1 is derived from the standard error $s_{1}$ in the PARMS= data set,

$I_{1} = \frac{1}{s^{2}_{1}} = \frac{1}{0.04308^{2}} = 538.8$

Output 90.3.10: Sequential Tests

Test Information (Standardized Z Scale) Null Reference = 0
_Stage_			Alternative		Boundary Values		Test
	Information Level		Reference		Lower	Upper	Weight
	Proportion	Actual	Lower	Upper	Beta	Beta	Estimate	Action
1	0.4934	538.7887	-2.32118	2.32118	-0.43033	0.43033	1.08174	Continue
2	0.7500	818.9792	-2.86178	2.86178	-1.13623	1.13623	.
3	1.0000	1091.972	-3.30450	3.30450	-1.91431	1.91431	.

At stage 1, the standardized Z statistic 1.08174 is greater than the upper $\beta$ boundary 0.43033, so the trial continues to the next stage.

With ODS Graphics enabled, a boundary plot with test statistics is displayed, as shown in Output 90.3.11. As expected, the test statistic is in the continuation region.

Output 90.3.11: Sequential Test Plot

The following statements use the REG procedure to estimate the slope $\beta _{w}$ and its associated standard error at stage 2:

proc reg data=Fit_2;
   model Oxygen=Age Weight RunTime RunPulse MaxPulse;
   ods output ParameterEstimates=Parms_Fit2;
run;

Note that the data set Fit_2 contains both the data from stage 1 and the data from stage 2,

The following statements create and display (in Output 90.3.12) the input data set that contains slope $\beta _{w}$ and its associated standard error at stage 2 for the SEQTEST procedure:

data Parms_Fit2;
   set Parms_Fit2;
   if Variable='Weight';
   _Scale_='MLE';
   _Stage_= 2;
   keep _Scale_ _Stage_ Variable Estimate StdErr;
run;


proc print data=Parms_Fit2;
   title 'Statistics Computed at Stage 2';
run;

Output 90.3.12: Statistics Computed at Stage 2

Statistics Computed at Stage 2

Obs	Variable	Estimate	StdErr	_Scale_	_Stage_
1	Weight	0.02925	0.03490	MLE	2

The following statements invoke the SEQTEST procedure to test for early stopping at stage 2:

ods graphics on;
proc seqtest Boundary=Test_Fit1
             Parms(testvar=Weight)=Parms_Fit2
             errspendadj=errfuncgamma
             order=lr
             pss
             plots=(asn power)
             ;
   ods output Test=Test_Fit2;
run;
ods graphics off;

The BOUNDARY= option specifies the input data set that provides the boundary information for the trial at stage 2, which was generated by the SEQTEST procedure at the previous stage. The PARMS= option specifies the input data set that contains the test statistic and its associated standard error at stage 2, and the TESTVAR= option identifies the test variable in the data set.

Since the data set PARMS_FIT2 does not contain the test information at stage 1, the information level at stage 1 in the TEST_FIT1 data set is used to generate boundary values for the test.

The ORDER=LR option uses the LR ordering to derive the p-value, unbiased median estimate, and confidence limits for the regression slope estimate.

The ODS OUTPUT statement with the TEST=TEST_FIT2 option creates an output data set named TEST_FIT2 which contains the updated boundary information for the test at stage 2. The data set also provides the boundary information that is needed for the group sequential test at the next stage.

The "Design Information" table in Output 90.3.13 displays design specifications. By default (or equivalently if you specify BOUNDARYKEY=ALPHA), the boundary values are modified for the new information levels to maintain the Type I $\alpha$ level.

Output 90.3.13: Design Information

The SEQTEST Procedure

Design Information
BOUNDARY Data Set	WORK.TEST_FIT1
Data Set	WORK.PARMS_FIT2
Statistic Distribution	Normal
Boundary Scale	Standardized Z
Alternative Hypothesis	Two-Sided
Early Stop	Accept Null
Number of Stages	3
Alpha	0.05
Beta	0.10009
Power	0.89991
Max Information (Percent of Fixed Sample)	103.9566
Max Information	1091.97232
Null Ref ASN (Percent of Fixed Sample)	75.18254
Alt Ref ASN (Percent of Fixed Sample)	101.8349

The derived Type II error probability $\beta$ and power $1-\beta$ are different because of the new information levels.

With the PSS option, the "Power and Expected Sample Sizes" table in Output 90.3.14 displays powers and expected mean sample sizes under various hypothetical references $\theta = c_{i} \theta _{1}$ , where $\theta _{1}$ is the alternative reference and $c_{i}=0, 0.5, 1, 1.5$ are the default values in the CREF= option.

Output 90.3.14: Power and Expected Sample Size Information

Powers and Expected Sample Sizes Reference = CRef * (Alt Reference)
CRef	Power	Sample Size
CRef	Power	Percent Fixed-Sample
0.0000	0.02500	75.1825
0.5000	0.37154	88.5975
1.0000	0.89991	101.8349
1.5000	0.99758	103.8843

With the PLOTS=ASN option, the procedure displays a plot of expected sample sizes under various hypothetical references, as shown in Output 90.3.15. By default, expected sample sizes under the hypotheses $\theta = c_{i} \, \theta _{1}$ , $c_{i}= 0, 0.01, 0.02, \ldots , 1.50$ , are displayed, where $\theta _{1}$ is the alternative reference.

Output 90.3.15: ASN Plot

With the PLOTS=POWER option, the procedure displays a plot of the power curves under various hypothetical references for all designs simultaneously, as shown in Output 90.3.16. By default, powers under hypothetical references $\theta = c_{i} \, \theta _{1}$ are displayed, where $c_{i}= 0, 0.01, 0.02, \ldots , 1.50$ by default. You can specify $c_{i}$ values with the CREF= option. The $c_{i}$ values are displayed on the horizontal axis.

Output 90.3.16: Power Plot

Under the null hypothesis, $c_{i}=0$ , the power is 0.025, which is the upper Type I error probability. Under the alternative hypothesis, $c_{i}=1$ , the power is 0.89991, which is one minus the Type II error probability, as displayed in the "Design Information" table in Output 90.3.13.

The "Test Information" table in Output 90.3.17 displays the boundary values for the test statistic with the default standardized Z scale. At stage 2, the standardized slope estimate 0.83805 is between the lower and upper $\beta$ boundary values. The trial stops to accept the null hypothesis that the variable Weight has no effect on the oxygen intake rate after adjusting for other covariates.

Output 90.3.17: Sequential Tests

Test Information (Standardized Z Scale) Null Reference = 0
_Stage_			Alternative		Boundary Values		Test
	Information Level		Reference		Lower	Upper	Weight
	Proportion	Actual	Lower	Upper	Beta	Beta	Estimate	Action
1	0.4934	538.7887	-2.32118	2.32118	-0.43033	0.43033	1.08174	Continue
2	0.7517	820.8509	-2.86505	2.86505	-1.14239	1.14239	0.83805	Accept Null
3	1.0000	1091.972	-3.30450	3.30450	-1.91408	1.91408	.

Since the data set PARMS_FIT2 contains the test information only at stage 2, the information level at stage 1 in the TEST_FIT1 data set is used to generate boundary values for the test.

With ODS Graphics enabled, a boundary plot with test statistics is displayed, as shown in Output 90.3.18. As expected, the test statistic is in the acceptance region between the lower and upper $\alpha$ boundaries at the final stage.

Output 90.3.18: Sequential Test Plot

After a trial is stopped, the "Parameter Estimates" table in Output 90.3.19 displays the stopping stage, parameter estimate, unbiased median estimate, confidence limits, and the p-value under the null hypothesis $H_{0}: \beta _{w} = 0$ . As expected, the p-value 0.3056 is not significant at the $\alpha = 0.05$ level, and the confidence interval does contain the value zero. The p-value, unbiased median estimate, and confidence limits depend on the ordering of the sample space $(k, z)$ , where k is the stage number and z is the standardized Z statistic. With the specified LR ordering, the p-values are computed with the ordering $(k’, z’) \succ (k, z)$ if $z’ > z$ . See the section Available Sample Space Orderings in a Sequential Test for a detailed description of the LR ordering.

Output 90.3.19: Parameter Estimates

Parameter Estimates LR Ordering
Parameter	Stopping Stage	MLE	p-Value for H0:Parm=0	Median Estimate	95% Confidence Limits
Weight	2	0.029251	0.3056	0.037080	-0.03368	0.10532