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Monte Carlo Simulation
G.L. Drusano, M.D.Co-Director
Ordway Research Institute &Research Physician
New York State Department of HealthProfessor of Medicine & Pharmacology
Albany Medical College
Monte Carlo Simulation
• Monte Carlo simulation was invented by Metropolis and von Neumann
• This technique and its first cousin Markov Chain Monte Carlo have been used since for construction of distributions (Markov Chain Monte Carlo was actually described as a solution to the “simulated annealing problem” in the Manhattan Project –Metropolis et al)
Monte Carlo Simulation
• The first use of Monte Carlo simulation for drug dose choice and breakpoint determination was presented on October 15, 1998 at an FDA Anti-Infective Drug Products Advisory Committee
• At this time, the drug was presented as “DrugX” but was evernimicin
• The ultimate outcome was predicted by the method (but the drug died)
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Required Factors for Rational Dose/Drug Comparison
1. Pharmacodynamic Goals of Therapy
2. Population Pharmacokinetic Modeling
3. Target Organism(s) MIC Distribution
4. Protein Binding Data in Animal and Man
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Role of Monte Carlo Simulation for Dose Choice for Clinical Trials of Anti-Infectives
Drusano GL, SL Preston, C Hardalo, et al. Antimicrob Agents Chemother. 2001;45:13-22.
Monte Carlo Simulation
• What is Monte Carlo simulation, as applied to Infectious Diseases issues?
• What are the technical issues?
• For what is Monte Carlo simulation useful?
Monte Carlo Simulation
What is Monte Carlo simulation?MC simulation allows us to make use
of prior knowledge of how a target population handles a specific drug to predict how well that drug will perform clinically at the dose chosen for clinical trials and to rationally set breakpoint values for susceptibility
Monte Carlo Simulation
How is this done?Through use of the mean
parameter vector and covariance matrix, derived from a population PK study, a sampling distribution is set up. This allows the peak concentrations, AUC and Time > threshold to be calculated for all the subjects
Monte Carlo Simulation
How do we use this to predict the clinical utility of a specific drug dose?
1) Identify the goal of therapy (cell kill, resistance suppression, etc)2) Identify the sources of variability that affect achieving the goal of therapya) PK variability (accounted for by MCS)b) Variability in MIC’s (or EC95, etc)c) Protein binding (only free drug is
active)
Monte Carlo Simulation
What do we do?As an example, for a drug that is
AUC/MIC driven in terms of goal of therapy (e.g. AUC/MIC of 100 for a good microbiological outcome), we can now take the 2000 (or 10000 or whatever) simulated subjects and divide the AUC by the lowest MIC in the distribution, then determine how many achieve the target of 100. This is then repeated with higher MIC values until the target attainment is zero or some low number
Monte Carlo Simulation
How does this help evaluate the utility of a specific drug dose?
We have target attainment rates at each MIC value in the organism population distribution. A specific fraction of the organisms have a specific MIC. A weighted average for the target attainment rate (taking an expectation) can be calculated. This value will be the overall “expected” target attainment rate for the outcome of interest for that specific dose.
Monte Carlo Simulation
Technical Issues
Monte Carlo Simulation
• What are the factors that may affect the simulation?
►Model mis-specification
►Choice of distribution
►Covariance matrix (full vs diagonal)►Simulating the world from 6
subjects
Monte Carlo Simulation
Model Mis-specification
Monte Carlo Simulation
• Model mis-specificationSometimes, data are only available
from older studies where full parameter sets and their distributions were not reported
• Some investigators have used truncated models for simulation (1 cmpt vs 2 cmpt)
• This may have more effect for some drugs relative to others (β lactams vs quinolones)
Monte Carlo Simulation
Choice of Distribution
Monte Carlo Simulation
• There are many underlying distributions possible for parameter values
• Frequently, there are insufficient numbers of patients to make a true judgement
• One way to at least make the choice rational is to examine how one distribution vs another recapitulates the mean parameter values and measure of dispersion
• A quinolone example follows (N vs Log-N)
Monte Carlo Simulation
Param Pop Mean
Sim Mean
Pop SD
Sim SD
Distr
Vol 23.32 22.80 33.51 30.15 LN
Kcp 2.662 2.985 9.591 11.84 LN
Kpc 0.9327 0.7515 12.03 4.388 LN
SCL 6.242 6.252 4.360 4.303 LN
Monte Carlo Simulation
Param Pop Mean
Sim Mean
Pop SD
Sim SD
Distr
Vol 23.32 36.82 33.51 24.23 N
Kcp 2.662 8.926 9.591 6.311 N
Kpc 0.9327 9.914 12.03 7.370 N
SCL 6.242 6.936 4.360 3.817 N
Monte Carlo Simulation
• Here, it is clear that the Log-normal distribution better recaptures the mean parameter values and, in general, the starting dispersion (except Kpc)
• And for AUC distribution generation, it is clear that Log-normal is preferred because it performs better for the parameter of interest (SCL) for both mean value and dispersion
• We have seen examples where there is no substantive difference (N vs Log-N)
Monte Carlo Simulation
Full vs Major DiagonalCovariance Matrix
Monte Carlo Simulation
• Sometimes, only the population standard deviations are available and only a major diagonal covariance matrix can be formed
• Loss of the off-diagonal terms will generally cause the distribution to become broader (see example)
• One can obtain an idea of the degree of impact if the correlation among parameters is known (of course if this is known, one could calculate the full covariance matrix!)
Monte Carlo Simulation
Mean = 139.6
Median = 120.2
SD = 82.4
95% CI = 41.2-348.8
Mean = 140.4
Median = 121.4
SD = 83.5
95% CI = 40.7-351.4
0 200 400 600 800 1000Levofloxacin 750 mg AUC-Full Covariance Matrix
0
100
200
300
400
500
600
700
800
900
1000
Co
un
t
0.00
0.02
0.04
0.06
0.08
0.10
Pro
po
rtion
pe
r Ba
r
Monte Carlo Simulation
Simulating the WorldFrom 6 Subjects
Monte Carlo Simulationn = 6 n = 25
n = 50
Monte Carlo Simulation
• Obviously, the robustness of the conclusions are affected by the information from which the population PK analysis was performed
• If the “n” is small, there may be considerable risk attendant to simulating the world
• One of the underlying assumptions is that the PK is reflective of that in the population of interest – care needs to be taken and appropriate consideration given to the applicability of the available data to the target population
Monte Carlo Simulation• But, in the end, something is probably better than
nothing, so simulate away, but interpret the outcomes conservatively
• It is also important to examine the SD’s, as drawing inferences on drug dose from volunteer studies, where CV%’s are sometimes circa 10% may be risky
• How many simulations should be done? - Answer: as always, it depends
• To stabilize variance in the far tails of the distribution (> 3 SD), it is likely that one would require > 10000 simulations
Monte Carlo Simulation
• Utility of Monte Carlo simulation, a non-exhaustive list:
► Determination of drug dose to attain a specific endpoint
► Determination of a breakpoint
► Examine variability in drug penetration
Monte Carlo Simulation
Some New Stuff:
1) Effect simulations for combinations
2) Use of estimated GFR in simulations
3) Identification of a resistance-counterselective dose
Monte Carlo Simulation
Hope W et al. J Infect Dis 2005;192:673-680.
Monte Carlo Simulation
Hope W et al. J Infect Dis 2005;192:673-680.
Greco Model for Combination Chemotherapy
Monte Carlo Simulation
Hope W et al. J Infect Dis 2005;192:673-680.
Greco Model for Combination Chemotherapy
Monte Carlo Simulation
Hope W et al. J Infect Dis 2005;192:673-680.
Monte Carlo SimulationA
B
C
A
B
C
5-FC 30 mg/Kg/dayAmphotericin B 1 mg/Kg/day
5-FC 30 mg/Kg/dayAmphotericin B 0.6 mg/Kg/day
5-FC 30 mg/Kg/dayAmphotericin B 0.3 mg/kg/day
Monte Carlo Simulation
• It is straightforward to model combinations of agents
• Our laboratory has also done so for anti-retrovirals
• For Amphotericin B/5-FC, it is clear that the current dose of 5-FC is far too large (at least for C. albicans) and only adds toxicity
• Monte Carlo simulation shows that use of 30 mg/Kg 5-FC with Ampho B doses as low as 0.3 mg/Kg gives up little effect, but would have significantly diminished toxicity
Population Pharmacokinetic Parameter Values for Ceftobiprole
Kh Vc K23 K32 CLsl CLint
Units h-1 L h-1 h-1 L/h L/h
Mean 51.8 7.65 3.05 1.10 0.510 2.35
Median 59.9 7.05 1.20 0.960 0.484 2.46
S.D. 17.5 3.89 5.14 0.951 0.318 1.98
Observed vs. Predicted Plot after the Bayesian Step
Observed = 1.003 x Predicted + 0.627; r2 = 0.947; p << 0.001
Ceftibiprole 500mg IV Q12H,30% Dosing Interval, 1hr Inf
0.1 1.0 10.0MIC (mg/L)
0.00.10.20.30.40.50.60.70.80.91.0
Fra
ctio
na
l Ta
r ge
t At t
ain
me
nt
12010080604020
ClCr (ml/min)
Target Attainment Probabilities for a 500 mg dose of ceftobiprole administered as a 1 hour, constant rate intravenous infusion every 12 hours. Target was maintaining free drug concentrations in excess of the MIC for 30% of the dosing interval. Estimated creatinine clearances were held constant for each analysis at the indicated values between 20 ml/min and 120 ml/min.
Gumbo et al. J Infect Dis 2004;190:1642-1651.
11 )/(()1( XVSCLRdtdX c
SSSkSSSgS NMKENLKdtdN maxmax )1(
RRRkRRRgR MNKENLKdtdN maxmax )1(
)/)(1( POPMAXNNE SR
))//(()/( 5011HHH
c ECVcXVXL
HHHc ECVcXVXM 5011 )//(()/(
The model system delineated above was applied to all the data simultaneously
Gumbo et al. J Infect Dis 2004;190:1642-1651.
Monte Carlo Simulation
Gumbo et al. J Infect Dis 2004;190:1642-1651.
Total Population Resistant Population
Moxifloxacin Concentrations
Monte-Carlo Simulation and Moxifloxacin in Mtb Therapy
• Therapeutic target; moxifloxacin AUC/MIC of 53 in patients for resistance suppression
• Moxifloxacin doses of 400 mg a day, 600 mg a day, and 800 mg a day taken by 10,000 simulated patients
• Prior information: published population pharmacokinetic parameters
Moxifloxacin 400 mg a day. Target attainment=59.3%
The target here and in the next two slides is suppression of the resistant population
Moxifloxacin 600 mg a day. Target attainment=86.4%
Moxifloxacin 800 mg a day. Target attainment=93.1%
Moxifloxacin and M.tuberculosis Conclusion
• Moxifloxacin resistance in sub-therapeutic exposure occurs early during 2nd week of therapy.
• Drug doses associated with excellent microbial kill may amplify resistant population.
• Drug exposure associated with suppression of resistance is an AUC0-24/MIC of 53.
• Moxifloxacin daily dose of 800 mg may be better for MDRTB as opposed to current 400 mg a day dose recommended by CDC/IDSA/ATC because of resistance issues. Such a dose would need careful clinical evaluation because of QTc prolongation
Monte Carlo SimulationOverall Conclusions
• MCS is useful for rational breakpoint determination• MCS allows insight into the probability that a
specific dose will attain its target• This has been prospectively validated• The technique rests upon certain assumptions and
is as reliable as the assumptions • Care needs to be taken when applying the method,
particularly as regards applicability of the population studied and population size, among other issues
Monte Carlo SimulationSense and Non-Sense
• WE CAN DO BETTER AND WE SHOULD!– As an aside, I have trying since the early 1980’s
to interest the infectious diseases community (and granting agencies) in pharmacodynamic modeling, notably WITHOUT SUCCESS!
– WELL!
George