Computational

Let:

Y_ijkt be the response of subject j in sequence i at time t with treatment k.

Phoenix_UserDocs_Bioequivalence_Object_image3111 be a vector of responses for subject j in sequence i. The components of Y are arranged in the ascending order of time.

Phoenix_UserDocs_Bioequivalence_Object_image3113 .be the design vector of treatment T in sequence i.

Phoenix_UserDocs_Bioequivalence_Object_image3115 be a design vector for treatment R in sequence i.

n_i > 1 be the number of subjects in sequence i.

Assume the mean responses of Phoenix_UserDocs_Bioequivalence_Object_image3117 , follow a linear model:

Phoenix_UserDocs_Bioequivalence_Object_image3119

where m_T, m_R are the population mean responses of Y with treatments T and R respectively, and X_iare design/model matrices.

Let:

Phoenix_UserDocs_Bioequivalence_Object_image3121

be the number of occasions T is assigned to the subjects in sequence i.

Phoenix_UserDocs_Bioequivalence_Object_image3123

be the number of occasions R is assigned to the subjects in sequence i.

Then:

Phoenix_UserDocs_Bioequivalence_Object_image3125

Assume that the covariances:

Phoenix_UserDocs_Bioequivalence_Object_image3127

follow the model:

Phoenix_UserDocs_Bioequivalence_Object_image3129

where the parameters:

Phoenix_UserDocs_Bioequivalence_Object_image3131

are defined as follows:

Phoenix_UserDocs_Bioequivalence_Object_image3133

intra-subject correlation coefficients are:

Phoenix_UserDocs_Bioequivalence_Object_image3135

intra-subject covariances are:

Phoenix_UserDocs_Bioequivalence_Object_image3137

intra-subject variances are:

Phoenix_UserDocs_Bioequivalence_Object_image3139

For PBE and IBE investigations, it is useful to define additional parameters:

Phoenix_UserDocs_Bioequivalence_Object_image3141

Except for s_D^*, all the quantities above are non-negative when they exist. It satisfies the equation:

Phoenix_UserDocs_Bioequivalence_Object_image3143

In general, this s_D^* may be negative. This method for PBE/IBE is based on the multivariate model. This method is applicable to a variety of higher-order two-treatment crossover designs including TR/RT/TT/RR (the Balaam Design), TRT/RTR, or TxRR/xRTT/RTxx/TRxx/xTRR/RxTT (Table 5.7 of Jones and Kenward, page 205).

Given the i^th sequence, let:

Phoenix_UserDocs_Bioequivalence_Object_image3145

where:

Phoenix_UserDocs_Bioequivalence_Object_image3147 is the sample mean of the i^th sequence.

V_i is the within-sequence sample covariance matrix.

It can be shown that:

Phoenix_UserDocs_Bioequivalence_Object_image3149

Furthermore, it can be shown that {S_iT, S_iR} (for PBE) are statistically independent from {D} and {S_iWT, S_iWR}, and that the four statistics D, S_iI, S_iWT, S_iWR (for IBE) are statistically independent.

Let a_i be sets of normalized weights, chosen to yield the method of moments estimates of the h. Then define the estimators of the components of the linearized criterion by:

Phoenix_UserDocs_Bioequivalence_Object_image3151

Phoenix_UserDocs_Bioequivalence_Object_image3153

Phoenix_UserDocs_Bioequivalence_Object_image3155

Phoenix_UserDocs_Bioequivalence_Object_image3157

Using the above notation, one may define unbiased moment estimators for the PBE criteria:

Phoenix_UserDocs_Bioequivalence_Object_image3159

and for the IBE criteria:

Phoenix_UserDocs_Bioequivalence_Object_image3161

Construct a 95% upper bound for h based on the TRTR/RTRT design using Howe’s approximation I and a modification proposed by Hyslop, Hsuan and Holder (2000). This can be generalized to compute the following sets of n_q, H, and U statistics:

Phoenix_UserDocs_Bioequivalence_Object_image3163

where the degrees of freedom n_q are computed using Satterthwaite’s approximation. Then, the 95% upper bound for each h is:

Phoenix_UserDocs_Bioequivalence_Object_image3165

If H_q < 0, that indicates bioequivalence; H_q > 0 fails to show bioequivalence.