IN VITRO/IN VIVO CORRELATIONS-eval training
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Transcript IN VITRO/IN VIVO CORRELATIONS-eval training
CLINICAL PHARMACOLOGY IN
DRUG DEVELOPMENT
CONCENTRATION
70
60
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10
0
0
5
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25
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TIME IN HOURS
Ramana S. Uppoor, R.Ph., Ph.D.
Division of Clinical Pharmacology-1
ASENT meeting, March 6, 2008
Office of Clinical Pharmacology, CDER, FDA
Disclaimer
Views expressed are mine and
do not necessarily reflect
official FDA Policy.
New Molecular Entity Approvals by Fiscal Year
50
45
28 44
Number Approved
40
44
34
13
11
20
25
8
17
18
17
14
13
8
8
2002
2003
10
12
10
9
22
19
13
5
32
30
15
13
27
31
28
30
10
37
21
35
25
39
40
5
0
1993
1994
1995
1996
1997
1998
1999
2000
2001
Fiscal Year of Approval
Priority NME Approvals
* as of 30-Sep-2003
Standard NME Approvals
Number of NMEs Filed
High attrition rate even in late
development
Kola I, Landis J.Can the pharmaceutical industry reduce attrition rates?
Nat.Rev.Drug.Disc. Aug 2004.
Need/Opportunities for Innovative Methods in
Drug Development
Assess
useful
Biomarkers
Decrease
avoidable
trial failures
e.g. imaging
Evaluate
rational
trial
designs,
endpoints
Individualization
of
dosing
Providing solutions for these issues calls
for optimal early trials and efficient use of prior knowledge
OUTLINE
Definitions
Clinical
Pharmacology domain
Clinical Pharmacology studies
Biopharmaceutics studies
Value
Case examples
Conclusions
Clinical Pharmacology is…
Translational
science in which basic
information about the relationship between
dose, exposure and response (efficacy or
safety) is applied in the context of patient care
Major contribution of Clinical Pharmacology:
Knowledge of E-R relationship (key to
successful therapeutics) and how it is altered
by intrinsic (age, gender, renal function etc.)
and extrinsic (diet, drugs, life-style) factors of
an individual patient
Definitions
Clinical Pharmacology:
Pharmacokinetics (PK): What the body does to the
drug (Absorption, Distribution, Metabolism,
Excretion). For drug review purpose, PK also covers
extrinsic and intrinsic factors like drug interactions,
effect of age, gender, race, organ dysfunction, etc. PK
gives you Exposure.
Pharmacodynamics (PM): What the drug does to the
body. PD covers desirable and undesirable effects, from
biomarkers to surrogates to clinical endpoints. PD gives
you Response.
FIRST PRINCIPLES
Why Drugs Work In Vivo
Pharmacokinetics
Pharmacodynamics
Absorption
Distribution
Metabolism
Excretion
Concentration
Dose
MEC
Total
Free
Time
Effect
PK-PD MEASURES
Serum Drug Concentration
frequency
Peak conc. (Cmax)
Effect (e.g., Survival, % change in seizure
Relationships Between Exposure & Response
AUC
Time
Emax
EC50
PK-PD Measure
(e.g., AUC)
Clinical Trials Spectrum
Phase
I, II,III and IV clinical trials
Early and Late phase clinical trials
Learn and Confirm trials
Clinical Pharmacology (= Learn; phase 1
and 2) including dose response trials and
Efficacy (= Confirm; phase 3) trials
Safety Trials: All phases
Bioequivalence Trials
Clinical Pharmacology Domain
PK (ADME)
PM
PD
PG
Clinical Pharmacology &
Biopharmaceutics Studies
Pharmacokinetics/Biopharmaceutics:
Mass
Balance studies with radiolabelled drug
Single and multiple dose pharmacokinetics
Absolute bioavailability
Dose proportionality
Food effects studies
Bioequivalence studies to establish the link
between the market and clinical formulations
Metabolism and drug interactions
Clinical Pharmacology &
Biopharmaceutics Studies .. contd.
Clinical Pharmacology:
Pharmacokinetics in the target population
Special population studies
Age, Gender, Race, etc.
Disease states such as renal and liver impairment
Establishment of pharmacokinetic
pharmacodynamic correlations
Bioavailability and Bioequivalence Definitions
Bioavailability means the rate and extent to which the
active ingredient or active moiety is absorbed from a
drug product and becomes available at the site of
action.
Bioequivalence means the absence of a significant
difference in the rate and extent to which the active
ingredient or active moiety in pharmaceutical
equivalents or pharmaceutical alternatives becomes
available at the site of drug action when administered
at the same molar dose under similar conditions in an
appropriately designed study.
BIOAVAILABILITY
MEASUREMENT
MONITORING PARAMETERS
Peak Concentration: Cmax
Time to Peak Concentration:
Tmax
Area Under the Drug
Concentration-Time Curve:
AUC
70
120
60
100
50
80
CONCN.
CONCN.
Single dose & Multiple dose
Bioavailability
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TIME IN HOURS
TIME IN HOURS
Cmax and AUC
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Food effect study
70
CONCENTRATION
High fat meal:
2 eggs fried in butter
2 strips of bacon
2 slices of toast with butter
4 ounces of hash brown
potatoes
8 ounces of whole milk
1000 calories, 50 % derived
from fat
60
fed
fasting
50
40
30
20
10
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0
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TIME IN HOURS
Evaluate the food effect by
comparing the PK parameters
obtained in fed vs. fasted state
25
30
BIOEQUIVALENCE MEASUREMENT
PHARMACOKINETIC PARAMETERS
SINGLE DOSE
AUC0-Tlast
AUC 0-Tinf
Cmax
Tmax
MULTIPLE DOSE
AUCss
Cmax
Cmin
Tmax
STATISTICAL REQUIREMENTS
FOR Bioequivalence
Current Decision Rule:
Two one-sided test procedure:
(ALSO CALLED THE 90% CONFIDENCE INTERVAL APPROACH)
•
•
Recognizes that there will be a difference in mean values
between treatments
Provides reasonable assurance that mean
treatment differences are acceptable
General Requirement:
90% confidence intervals for AUC and Cmax have to be within
the range of: 80 – 125% (based on log transformed data)
Common CPR Encounters
Exposure-Response
Pater Current Controlled Trials in Cardiovascular Medicine 2004 5:7
GENERAL THOUGHTS/VALUES
OCP:
The Right Dose of the Right Drug at the Right Time
for the Right Patient
Optimal bioavailability
Dose selection
Dosing regimen selection
Dose adjustment for special populations
Dose adjustment in presence of intrinsic and extrinsic factors
GOAL: To develop good drugs/drug
products with adequate information to
improve therapeutics (with an ultimate
goal of optimal treatment for a patient)
Exposure Response Relationship
Selection of appropriate dose/regimen
Efficacy
Percentage
of
Response
Toxicity
Exposure
Selection of optimal release profile
Case example 1 – Dosing regimen
FDA’s proactive model-based analysis
identified that the proposed dosing is suboptimal. Simulations suggested alternatives.
Development cycle extended.
Regulatory Issue
Short
t1/2 drug for lowering BP
Sustained effect desired
Proposed dosing - QD
Very large trial conducted
Typically
pivotal trials are not large for hypertension
Exposure-Response
Effectiveness
analyses conducted
and Safety
Is this really a once-day-drug?
s-Lercanidipine Steady-Stat
6.0
6.
ER Analysis
3.0
Clear concentration-effect
relationship
No delay between PK and
PD
Nonlinear concentrationeffect relationship
FDA performed the analysis
during NDA review
0.0
3.6
2.4
Cp
1.2
0.0
3.
X mg daily
ID: 101
EC50
0.
4.
3.
1.
0.
0 Time,
6 12h18 24
Modeling demonstrated inadequacy of once a
day regimen
Value Delivered by the Exposure
Response Analysis
Supported
evidence for effectiveness
Aided in judging that QD dosing is suboptimal
Provided alternatives for future development
Prospective modeling of early PK/PD data
could have (and an EOP2A meeting)
Avoided
lengthening drug development time
Been more economical
Case example 2 - Use of exposure
response for pediatric approval
FDA’s proactive model-based analysis alleviated
the need to conduct additional clinical trial for the
approval of Trileptal monotherapy in pediatrics
Regulatory Issue
Adults
Adjunctive
Clinical trials
Children
Clinical trial
(4-16 years
of age)
Monotherapy
Clinical trials
“Model Based Bridging”
approach proposed by
FDA
FDA/Sponsor pursued approaches to best utilize
knowledge from the positive trials to assess if
monotherapy in pediatrics can be approved without new
controlled trials
Motivation
Monotherapy of anticonvulsants is important
Better safety, Ease of Rx mgmt
Avoid unnecessary costs
Monotherapy trials are challenging
Reasonable ER knowledge available
Integration of knowledge across trials and populations
is needed
Law supports model based thinking
Value of this type of analysis
Modeling
and simulation aided in utilizing all
previous data to justify approval without
additional controlled clinical trials
Allowed selection of dosing guidelines in
pediatrics
The presented approach has a greater global
impact
Precedent
was set
Conclusions
PK and Exposure-Response analysis can help select
suitable dose/dosing regimen and identify optimal drug
products.
PK from early trials will help optimize the dosing
conditions for pivotal trials.
Facilitate dosing in special populations and also provide
dose adjustment guidelines in the presence of intrinsic
(age, gender, renal function etc.) or extrinsic factors
(concomitant drugs, food etc.).
Conclusions …. contd.
Facilitate
findings of effectiveness as well
as help resolve safety concerns.
E-R frame created in the approved setting
can be a powerful source for approval
consideration for additional settings (e.g.
pediatrics).
Need/Opportunities for Innovative Methods in
Drug Development
Assess
useful
Biomarkers
Decrease
avoidable
trial failures
e.g. imaging
Evaluate
rational
trial
designs,
endpoints
Individualization
of
dosing
Providing solutions for these issues calls
for optimal early trials and efficient use of prior knowledge
ACKNOWLEDGEMENTS
Dr. Mehul Mehta
Dr. Patrick Marroum
Dr. Robert Kumi
That’s all folks!