pk.hlp

是一个经济学管理应用软件 很难找的 但是经济学学生又必须用到

{smcl}
{* 03dec2004}{...}
{cmd:help pk}
{hline}

{title:Title}

{p2colset 5 15 17 2}{...}
{p2col :{hi:[R] pk} {hline 2}}Pharmacokinetic (biopharmaceutical) data{p_end}
{p2colreset}{...}


{title:Description}

{pstd}
The term pk refers to pharmacokinetic data and the Stata commands, all of
which begin with the letters pk, designed to do some of the analyses commonly
performed in the pharmaceutical industry.  The system is intended for the
analysis of pharmacokinetic data, although some of the commands are of general
use.

{pstd}
The pk commands are

{p2colset 9 26 28 2}{...}
{p2col :{helpb pkexamine}}Calculate pharmacokinetic measures{p_end}
{p2col :{helpb pksumm}}Summarize pharmacokinetic data{p_end}
{p2col :{helpb pkshape}}Reshape (pharmacokinetic) Latin-square data{p_end}
{p2col :{helpb pkcross}}Analyze crossover experiments{p_end}
{p2col :{helpb pkequiv}}Perform bioequivalence tests{p_end}
{p2col :{helpb pkcollapse}}Generate pharmacokinetic measurement dataset{p_end}
{p2colreset}{...}


{title:Remarks}

{pstd}
Several types of clinical trials are commonly performed in the pharmaceutical
industry.  Examples include combination trials, multicenter trials,
equivalence trials, and active control trials.  For each type of trial, there
is an optimal study design for estimating the effects of interest.  Currently,
the pk system can be used to analyze equivalence trials, which are
usually conducted using a crossover design; however, it is possible to use a
parallel design and still draw conclusions about equivalence.

{pstd}
Equivalence trials assess bioequivalence between two drugs.  While it is
impossible to prove two drugs behave exactly the same, the United States Food
and Drug Administration believes that if the absorption properties of two
drugs are similar, the two drugs will produce similar effects and have
similar safety profiles.  Generally, the goal of an equivalence trial is to
assess the equivalence of a generic drug with an existing drug.  This is
commonly accomplished by comparing a confidence interval about the difference
between a pharmacokinetic measurement of two drugs with a confidence limit
constructed from U.S. federal regulations.  If the confidence interval is
entirely within the confidence limit, the drugs are declared bioequivalent.
An alternative approach to the assessment of bioequivalence is to use the
method of interval hypotheses testing.  {cmd:pkequiv} is used to conduct these
tests of bioequivalence.

{pstd}
Several pharmacokinetic measures that can be used to ascertain how
available a drug is for cellular absorption.  The most common measure is the
area under the time-versus-concentration curve (AUC).  Another common measure
of drug availability is the maximum concentration (Cmax) achieved by the drug
during the follow-up period.  Stata reports these and other less common
measures of drug availability, including the time at which the maximum drug
concentration was observed and the duration of the period during which the
subject was being measured.  Stata also reports the elimination rate, that is,
the rate at which the drug is metabolized; and the drug's half-life, that is,
the time it takes for the drug concentration to fall to one-half of its
maximum concentration.

{pstd}
{cmd:pkexamine} computes and reports all the pharmacokinetic measures that
Stata produces, including four calculations of the area under the
time-versus-concentration curve.  The standard area under the curve from 0 to
the maximum observed time (AUC) is computed using cubic splines or the
trapezoidal rule.  Additionally, {cmd:pkexamine} will also compute the area
under the curve from 0 to infinity by extending the standard
time-versus-concentration curve from the maximum observed time using three
different methods.  The first method simply extends the standard curve using a
least squares linear fit through the last few data points.  The second method
extends the standard curve by fitting a decreasing exponential curve through
the last few data points.  Lastly, the third method extends the curve by
fitting a least-squares linear regression line on the log concentration.  The
mathematical details of these extensions are described in {hi:[R] pkexamine}.

{pstd}
Data from an equivalence trial may also be analyzed using methods appropriate
to the particular study design.  When you have a crossover design,
{cmd:pkcross} can be used to fit an appropriate ANOVA model.  As an aside, a
crossover design is simply a restricted Latin square; therefore, {cmd:pkcross}
can also be used to analyze any Latin square design.

{pstd}
There are some practical concerns when dealing with data from equivalence
trials.  Primarily, the data need to be organized in a manner that Stata can
use.  The pk commands include {cmd:pkcollapse} and {cmd:pkshape}, which are
designed to help transform data from a common format to one that is suitable
for analysis with Stata.


{title:Also see}

{psee}
Manual:  {bf:[R] pk}

{psee}
Online:  {helpb anova}, {helpb pkcollapse}, {helpb pkequiv},
{helpb pkexamine}, {helpb pkshape}, {helpb pksumm}, {helpb reshape}, 
{helpb statsby}
{p_end}