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Antimicrobial Agents and Chemotherapy, August 2000, p. 2046-2051, Vol. 44, No. 8
0066-4804/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
A Population Pharmacokinetic Analysis of the
Penetration of the Prostate by Levofloxacin
G. L.
Drusano,1,*
S. L.
Preston,1
M.
Van
Guilder,2
D.
North,3
M.
Gombert,4
M.
Oefelein,5
L.
Boccumini,6
B.
Weisinger,7
M.
Corrado,6 and
J.
Kahn7
Division of Clinical Pharmacology,
Departments of Medicine and Pharmacology, Albany Medical College,
Albany,1 and Long Beach Medical Center,
Long Beach,4 New York; Laboratory of
Applied Pharmacokinetics, University of Southern California, Los
Angeles, California2; VA Medical Center,
Denver, Colorado3; 74th Med
Gp/SGOSU/CPDR, Wright Patterson Air Force Base, Dayton,
Ohio5; and Advanced Biologics, Inc.,
Lambertville,6 and Ortho-McNeil
Pharmaceuticals, Raritan,7 New Jersey
Received 12 October 1999/Returned for modification 4 March
2000/Accepted 25 April 2000
 |
ABSTRACT |
Prostatitis has remained a pathological entity that is difficult to
treat. Part of the difficulty revolves about the putative offending
pathogens. For acute prostatitis, members of the
Enterobacteriaceae, particularly Escherichia
coli, play a central role, while intracellular pathogens such as
Chlamydia are more frequently seen in chronic prostatitis. Consequently, a drug needs to be able to penetrate to this
specialized site in both the acute and chronic infection forms of the
disease and also have potent activity against the most common causative
pathogens, both intracellular and extracellular. Levofloxacin has such
an activity profile. We wished to document its ability to
penetrate to the site of infection. Patients undergoing prostatectomies
were administered 500 mg of levofloxacin orally every 24 h for 2 days prior to surgery, and then on the day of surgery, 500 mg was
administered as an hour-long, constant-rate intravenous (i.v.)
infusion. A set of blood samples was obtained as guided by stochastic
optimal design theory. Prostate biopsy times were determined by
randomizing subjects into one of four groups, based on the interval
after the i.v. dose. All plasma and prostate drug concentrations were
comodeled by a population modeling program, BigNPEM, implemented on the
Cray T3E Supercomputer housed at the Supercomputer Center at the
University of California at San Diego. Penetration was determined as
the ratio of the area under the concentration-time curve (AUC) of
levofloxacin in the prostate to the plasma levofloxacin AUC. When
calculated from the mean population parameters, this penetration ratio
was 2.96. We also performed a 1,000-subject Monte Carlo simulation from the mean parameter vector and covariance matrix. The mean penetration ratio here was 4.14 with a 95% confidence interval of 0.20 to 19.6. Over 70% of the population had a penetration ratio in excess of 1.0. Levofloxacin adequately penetrates a noninflamed prostate and should be
evaluated for the therapy of prostatitis.
| |
INTRODUCTION |
Prostatitis, particularly chronic
prostatitis, is often difficult to treat. Part of the difficulty
revolves around defining the infecting pathogen. Another aspect of the
problem lies in the protected nature of the prostate with regard to
antimicrobial penetration. The causative pathogen can be extracellular
(e.g., as in acute or chronic prostatitis due to Escherichia
coli) or intracellular (e.g., as in chronic prostatitis due to
Chlamydia). Consequently, the agent chosen for therapy
should have a spectrum that is appropriate for the suspected pathogen
and should penetrate well into the protected space of the prostate.
Levofloxacin is an agent that has good microbiological activity against
the pathogens that cause the vast majority of infections of the
prostate (9). Because it is a fluoroquinolone, one would, on
first principles, believe that it would have excellent penetration properties into extracellular fluid as well as into cells. However, it
is important to validate the penetration properties of an agent before
testing the drug in the clinical trial arena.
It was our intent, then, to examine the penetration of levofloxacin
into prostatic tissue. Because of the ethical issues involved in
obtaining penetration data during an acute infection, we chose to look
at penetration in the noninflamed situation, when patients were
undergoing prostatic surgery for other reasons.
Most penetration studies performed with patients can only obtain a
single sample of the drug's concentration at the desired site because
of the invasive or destructive nature of sampling. This leads to
difficulties in analyzing the data. Most often, paired plasma and
peripheral site samples are obtained, and the ratio between the two is
calculated. This is problematic because in most instances, system
hysteresis exists, so that the ratio between plasma and peripheral site
concentrations continuously changes, and the value for penetration
obtained depends on the sampling time. Obviously, such a result is
suboptimal. In this evaluation, we wished to handle the data in a more
reasonable way so as to be able to obtain the best estimate of drug
penetration into the prostate. This involved making sure that tissue
samples were obtained throughout the 24-h dosing interval for
levofloxacin and also ensuring that a robust plasma sampling schedule
was in place for each patient. With such a data set, we applied
population pharmacokinetic modeling as the analytic tool to allow
calculation of the area under the concentration-time curve (AUC) of the
drug both in plasma and in the prostate. The ratio of these AUC
determinations was our estimate of prostate penetration.
| |
MATERIALS AND METHODS |
Patients.
Patients in three medical centers were studied.
Patients who were undergoing prostatic surgery for benign prostatic
hypertrophy and were 18 years of age or older were selected (age range,
47 to 94 years). Heights and weights ranged from 63 to 73 inches and
from 107 to 253 pounds, respectively. Patients were of either Caucasian
or Hispanic origin. Written informed consent was obtained from all
patients according to institutional guidelines. Exclusions included (i)
the presence of an indwelling Foley catheter for 
4 days prior to
surgery, (ii) an oral temperature in excess of 38°C or other evidence
of infection within 24 h of surgery, (iii) administration of a
fluoroquinolone other than the study drug from 72 h prior to
surgery through the end of the period of sample acquisition, (iv)
allergy to the fluoroquinolone class of antimicrobials, (v) a serum
creatinine level of >2.0 or estimated (Cockcroft-Gault) creatinine
clearance of <50 ml/min, (vi) an acute systemic illness, (vii)
presence of a seizure disorder or any condition requiring the
administration of major tranquilizers, (viii) use of any
investigational drug or device within 30 days of study entry, and (ix)
classification as a poor surgical risk.
Drug and drug administration.
Levofloxacin, 500 mg, was
administered orally once daily starting 2 days prior to surgery. On the
day of surgery, levofloxacin was administered as a 500-mg dose
intravenously (i.v.) over 1 h. Actual infusion times were recorded.
Prostate sampling.
Patients were randomly assigned to
receive their levofloxacin i.v. infusion in one of four time intervals:
(i) 0 to 0.5 h prior to surgery (estimated), (ii) 3.75 to
4.25 h prior to surgery, (iii) 7.5 to 8.5 h prior to surgery,
or (iv) 22 to 24 h prior to surgery. Protaste samples (3 to
10 g) were well timed during surgery and obtained with a paired
plasma sample. The prostate sample was carefully blotted dry of all
blood contamination and weighed prior to being frozen for subsequent
levofloxacin concentration determination.
Plasma sampling.
The plasma sampling schedule was designed
employing stochastic optimal design theory for use in population
modeling. We had available a prior population pharmacokinetic model for
levofloxacin derived from a large (n = 272) population
of patients (7). This database had been analyzed with the
NPEM program of Schumitzky and Jelliffe (8). Part of the
output of this program is the MATLAB.M file, which provides the
parameters for the discrete support points in the population
distribution as well as the estimate of the probability of that
particular support point in the population distribution. Consequently,
this provides m parameter vectors and their associated probabilities
(where m usually approximates the population, n). We did not
consider parameter vectors with P values of <0.0001. All
other parameter vectors were entered into the Optimal Sampling module
of the ADAPT II package of programs of D'Argenio and Schumitzky
(6). D optimality was the design criterion employed. The
optimal sampling schedule for each parameter vector was recorded, along
with its probability. These were then plotted on a frequency histogram
employing 15-min intervals and corrected for probability. This provided
a plot of the system information over time. This was used to select
sampling times. The final sampling schedule was predose, near the end
of infusion (it was requested to allow 1 to 2 min to elapse to avoid
mixing transients), and 1.5, 2, 3.75, 5, and 6 h postinfusion. In
addition, as noted above, a plasma sample was obtained from patients at the time of prostate biopsy.
Prostate and plasma levofloxacin concentration
determinations.
Samples of plasma and prostatic tissue had
levofloxacin concentrations determined by a well-validated
high-performance liquid chromatography procedure (4).
Separate standard curves were developed for plasma and prostate drug
levels. Within- and between-day coefficients of variation were
developed at low, middle and high concentrations of levofloxacin and
were less than 5%. Plasma drug concentrations were expressed in
micrograms per milliliter. Prostate drug concentrations were expressed
in micrograms per gram of tissue.
Population pharmacokinetic modeling.
All plasma and prostate
samples were subjected to simultaneous population analysis. There were
156 plasma samples available from 22 subjects (7.1 samples per
patient). There were 20 prostate samples available for analysis. One
patient's sample was lost. Another patient had a prostate drug
concentration that was quite low. A plasma drug concentration obtained
simultaneously from this patient was also quite low. A regularly
scheduled plasma drug sample had been taken 42 min later that had a
>7-fold-higher concentration. Because of this, we chose not to employ
this plasma-prostate sample pair in the analysis.
Because we wished to employ an algorithm of demonstrated mathematical
consistency and because multiple outputs were required, we employed the
BigNPEM program of Jelliffe and Schumitzky. This program resides on the
Cray T3E Supercomputer at the University of California, San Diego,
Supercomputer Center, and access is available over the internet.
We employed a three-compartment open model with zero- or first-order
input and first-order elimination. One compartment also
had an explicit
second volume, which served as the prostate equivalent
compartment.
This volume is a virtual volume and represents the
rapidly exchangeable
volume attendant to the prostate. The differential
equations for the
model and the output equations are displayed
below:
|
(1)
|
![dx(2)/dt = R(1) + K<SUB>a</SUB>*x(1) − [(SCL/V<SUB>1</SUB>) + K<SUB>12</SUB> + K<SUB>13</SUB>]*x(2) +](/content/vol44/issue8/fulltext/2046/img002.gif)
|
(2)
|
|
(3)
|
|
(4)
|
For model outputs, plasma concentration =
x(2)/V
1; prostate concentration =
x(4)/V
2. The differential equations provide the
rate of change of the amount of levofloxacin in the absorptive
compartment (equation 1), plasma (equation 2), the peripheral
compartment (equation 3), and the prostate (equation 4).
R
is
the piecewise input function for levofloxacin i.v. administration,
Ka is the absorption rate constant for oral
levofloxacin administration,
SCL is the clearance,
V1 and
V2 are the volume
terms for the plasma
and prostate, respectively, and all other
K terms are first-order
intercompartmental transfer rate
constants.
We assumed that assay variance was the major component of total
observation variance. We modeled the assay error with zero-through
second-order polynomials. The final models for plasma and prostate
were
as follows:
plasma standard deviation = 0.00318 + 0.03259 × concentration + 0.00277 × concentration
2
prostate standard deviation = 0.14018 + 0.00043*concentration + 0.00142*concentration
2
The convergence criterion was 99.9999% of the true
maximum-likelihood
estimate.
Maximum a posteriori probability Bayesian parameter estimates for each
patient were obtained employing the population of one
utility of
BigNPEM for both plasma and prostate outputs. These
were employed to
predict plasma and prostate drug concentrations
at specified times for
each
patient.
Monte Carlo simulation.
The mean parameter vector and
covariance matrix from the output of BigNPEM were embedded in
SUBROUTINE PRIOR of the ADAPT II package of D'Argenio and Schumitzky
(6). A log-normal distribution as well as a normal
distribution was assumed. The distributions were differentiated on the
basis of their ability to recreate the original mean parameter values.
A 1,000-subject Monte Carlo simulation was performed with seven
outputs: (i) plasma drug concentration, (ii) prostate drug
concentration, (iii) plasma drug AUC, (iv) prostate drug AUC, (v)
prostate drug AUC/plasma drug AUC ratio, (vi) amount of drug in plasma,
and (vii) amount of drug in the prostate. The prostate drug AUC/plasma
drug AUC ratio was depicted in a frequency histogram. The 95%
confidence interval (as well as other statistics) was developed
directly from the Monte Carlo simulation.
| |
RESULTS |
Demographics.
These patients are older than would be seen in a
normal volunteer trial (see above). As levofloxacin is approximately
90% renally cleared, it is therefore understandable that one would expect plasma drug clearances that were lower than those seen in normal
volunteer trials.
Pharmacokinetic parameter values.
The mean parameter values,
median parameter values, and standard deviations are shown in Table
1, and the covariance matrix from the
output is displayed in Table 2. As can be
seen, the serum drug clearance is 7.27 ± 2.83 liters/h, and the
volume of distribution of drug in the central compartment is 41.38 ± 25.97 liters. The prostate volume of drug distribution was 0.78 kg.
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TABLE 1.
Pharmacokinetic parameter values from the population
analysis of penetration of the prostate by levofloxacin
|
|
The actual prostate drug concentrations for 20 patients are displayed
in Fig.
1. These values are timed with
respect to the
end of the i.v. infusion of levofloxacin.
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|
FIG. 1.
Concentrations of levofloxacin in the prostate as
determined by high-performance liquid chromatography. Times are after
the end of the actual administration of the intravenous infusion are
shown.  , concentration of drug in prostate.
|
|
The results of the maximum a posteriori probability Bayesian estimation
for the 156 plasma data points showed that the plot
of observed versus
predicted values had a regression line with
an intercept of
0.008 and
a slope of 1.041. The
r2 of this
regression is 0.930 (
r = 0.964),
P 
0.0001. The mean
error (predicted versus observed values) was employed as a measure
of
bias and was
0.17 µg/ml. The mean squared error was used as
a
measure of precision and was 0.44 (µg/ml)
2.
The predicted versus observed values regression for the 20 prostate
data points has an intercept of 0.09 and a slope of 0.996.
The
r2 of this regression is 0.992 (
r = 0.996),
P 0.0001. The mean
error was 0.059 µg/ml. The mean
squared error was 0.161 (µg/ml)
2.
The concentration-time curves for drug in the plasma and prostate as
simulated from the mean parameter values only are displayed
in Fig.
2A. The penetration ratio for this is
2.96. The amount-time
curve for drug in the plasma and prostate is
displayed in Fig.
2B.
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|
FIG. 2.
(A) Simulation from the mean parameter vector of the
plasma and prostate concentration-time profiles of levofloxacin. (B)
Simulation from the mean parameter vector of the plasma and prostate
amount-time curves of levofloxacin. Dotted line, drug concentration in
prostate; solid line, drug concentration in plasma.
|
|
The Monte Carlo simulation using the log-normal distribution best
recreated the initial mean values for the system parameters.
This was
used to create the mean curve of the 1,000-subject simulation
and the
95% confidence interval about the mean for both the plasma
and
prostate samples. These are displayed in Fig.
3.
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FIG. 3.
(A) Mean concentration-time curve in plasma and the 95%
confidence interval derived from a Monte Carlo simulation. , drug
concentration in plasma. (B) Mean concentration-time curve in the
prostate and the 95% confidence interval derived from a Monte Carlo
simulation. , drug concentration in prostate.
|
|
The mean, median, standard deviation, and 95% confidence interval of
the observation values for the drug penetration ratio
as calculated
from the Monte Carlo simulation were 4.14, 2.08,
6.94, and 0.197 to
19.63,
respectively.
In order to understand the true variability of drug penetration as
might be seen in the clinical trial arena, we display this
Monte Carlo
simulation in Fig.
4. Figure
4A displays
the full
variability of drug penetration, with a penetration ratio
range
that exceeds 20. The largest penetration ratio was 95.30. This
and 23 other values exceeding 20 were not displayed on the histogram
for clarity. Figure
4B demonstrates how many subjects were at
the low
end for penetration. Of the simulated subjects, 72.5%
had a
penetration ratio that was 1.0 or greater.
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|
FIG. 4.
(A) Histogram of a 1,000-subject Monte Carlo simulation
of the AUCprostate/AUCplasma of levofloxacin.
(B) As in panel A, but with only the range of the ratio of 0 to 2 displayed.
|
|
| |
DISCUSSION |
In order for an antibiotic to cure an infection, the antibiotic
must be able to penetrate to the primary infection site. In most
instances, this is not a problem, as most sites demonstrate the rapid
exchange of drug from the central compartment to the peripheral site of
infection (e.g., in lung tissue in pneumonia and skin in skin structure
infection). However, there are several specialized sites where it is
important to check drug penetration before initiating clinical trials.
Certainly, cerebrospinal fluid, the vitreous of the eye, and the
prostate must rank as the most important sites to delineate penetration
before clinical trials (2).
Many penetration studies are flawed by their methods of analysis. Since
obtaining serial samples is difficult to impossible in protected sites
like those listed above, one must examine only a single sample from
each site of interest from each patient. Using a site/plasma drug
concentration ratio at a single time point as a measure of drug
penetration is problematic, as there is often system hysteresis that
causes the ratio to change nearly continuously with time. While
straightforward to perform as a study and also straightforward to
analyze, such investigations may give biased estimates of drug
penetration, depending on the sampling time.
Consequently, we decided to approach this problem from the viewpoint of
population pharmacokinetic modeling. We decided it was important to
have information from all parts of the concentration-time curve
obtained from the prostate samples. Therefore, we randomized patients
as to when their prostate sample would be collected with regard to the
dosing interval of 24 h.
The approach worked well, with the plots of predicted versus
observed values demonstrating excellent regression
relationships (r2 = 0.930 and 0.992 for plasma and prostate, respectively),
particularly for the prostate drug concentrations. Consequently, the
results may be viewed with some degree of confidence.
The parameter values are likewise concordant with our expectations. The
estimate of a mean clearance of 7.27 liters/h is to be expected from
patients in the age range observed. The mean values for clearance and
volume of drug distribution in the central compartment as well as
marginal distributions fit well into the larger population of patients
that our group has studied previously (7). It should be
noted that the estimate of prostate volume was 0.779 kg. This should
not be taken to indicate that the true prostate volume was this large,
any more than one should assume from the volume of distribution of the
central compartment of 41.38 liters that the circulating blood volume
is this size. Rather, the central compartment represents the rapidly
exchangeable compartment for plasma, and the prostate volume represents
the rapidly exchangeable compartment size about the prostate.
When we calculate the penetration drug ratio, either from the mean
parameters (2.96 [Fig. 2A]) or from the mean of a 1,000 subject Monte
Carlo simulation (4.14), it is clear that much higher levofloxacin
concentrations are present in the prostate, on average, than are
present in the plasma. This seems to be an impossible finding. The
answer is provided in Fig. 2B. The amount of drug present in the plasma
always exceeds that present in the prostate. It is only because the
volume of prostate distribution is much smaller that the concentrations
become so great. The physiology that supports this finding is that
fluoroquinolones, like levofloxacin, are able to take on a net charge
at intracellular pH, rendering them subject to ion trapping
intracellularly (1).
As we sampled only whole tissue, it is likely that the majority of the
three- to fourfold increase in prostate drug concentrations seen here
represents intracellular drug. If one examines levofloxacin penetration
into other tissues representing interstitial fluid (5), it
is clear that AUC ratios approximate 1.0. If this is also true for the
interstitial fluid for the prostate, this means that extracellular
concentrations would approximate those seen in plasma (AUCs are equal).
The intracellular drug concentrations (which should constitute
approximately 80% of the volume of a whole tissue biopsy
[3]) should be approximately 3.8- to 4.8-fold that of
the plasma drug concentration by AUC ratio.
On average, then, levofloxacin concentrations in either the
extracellular space or the intracellular environment should be sufficient to provide a high probability of good clinical and microbiological outcomes when one considers the MICs for the target pathogens.
Figures 3 and 4 provide us with some insight into biological
variability. When we administer a fixed dose of drug to a large number
of patients, we often carry around a mental picture of the mean plasma
or tissue drug concentration-time profile. The reality is much
different. Figure 3 provides an idea of how variable the
concentration-time profiles can be when administered to a large group
of patients. Figure 4 allows us to see how the overall penetration of
the drug varies.
Two things should be stated clearly. One is that levofloxacin is a drug
that behaves very predictably. The coefficients of variation are quite
small when one considers that patients are being studied under clinical
conditions, making the results more predictable than with many other
agents. The second is that the vast majority of patients had an
excellent drug penetration into tissue, with over 70% of patients
having an AUC ratio that exceeded 1.0. So, even if one considers the
full range of variability, given the distribution of MICs for target
pathogens (9), excellent clinical results can be expected.
Finally, it should be emphasized that these penetration figures are
minimal estimates, as none of our patients had any inflammation. Target
patients with prostatitis should have sufficient inflammation to boost
penetration considerably, adding to the degree of confidence engendered
by these findings.
In summary, we have examined the penetration of the prostate by
levofloxacin in a mathematically robust way, so as to obtain the most
precise estimates of whole tissue penetration based on AUC ratios. We
have also expanded this investigation to examine the full range of
variability expected in a Monte Carlo simulation. The outcome of this
study is clear. Given levofloxacin's profile of microbiological
activity against target pathogens seen in prostatitis, its penetration
to this protected site makes it likely that clinicians will find
excellent clinical and microbiological outcomes in infected patients
subsequent to its use. Clinical trials of this agent in prostatitis are warranted.
| |
ACKNOWLEDGMENTS |
This study was supported, in part, by Ortho-McNeil
Pharmaceuticals and by NIH RO1-RR11526, a grant to R. W. Jelliffe.
We also extend our profound gratitude to R. W. Jelliffe and A. Schumitzky.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Division of
Clinical Pharmacology, Departments of Medicine and Pharmacology, Albany Medical College, 47 New Scotland Ave., Albany, NY 12208. Phone: (518)
262-6330. Fax: (518) 262-6333. E-mail: GLDRUSANO{at}AOL.COM.
| |
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Antimicrobial Agents and Chemotherapy, August 2000, p. 2046-2051, Vol. 44, No. 8
0066-4804/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
