1. Principles of�Clinical Pharmacology Steven P. Stratton, Ph.D. ��
2. Learning Objectives To define Pharmacokinetics & Pharmacodynamics
To identify PK/PD approaches, terminology, and parameters
To consider endpoints for PK/PD modeling
To identify barriers and opportunities with molecularly targeted drugs
To see new advances in clinical pharmacology
To understand some practical considerations in design of PK studies in clinical protocols
3. Potential Therapeutic Outcomes Efficacy without toxicity
Palliation
Efficacy with toxicity
Treatment, potentially curative
Toxicity without efficacy
Poison
Neither toxicity nor efficacy
Alternative medicine
4. Pharmacokinetics
5. Pharmacodynamics
6. Practical considerations in designing clinical drug intervention trials Why this drug?
What dose?
What schedule?
What combination?
What about other interactions?
7. Administering Drugs: Things to consider Age
Renal status
Liver function
Polymorphisms
Cytochrome P450 (genetics, drug interactions)
Acetylator status (genetics)
“Target” present?
8. Administering Drugs:�Things to consider What should I measure?
How do I measure it?
Correct sampling schedule
Validated method available?
9. Audience Question #1: �Once in the clinic, what is the primary reason for failure of experimental drugs to gain FDA approval? Toxicity
Efficacy
Pharmacokinetic Properties
Cost
Marketing
11. PK Terminology
12. Audience Question #2: ��What is the most important pharmacokinetic variable? Volume of Distribution (Vd)
Bioavailability (F)
Clearance (CL)
Half-life (t1/2)
Area Under the Curve (AUC)
13. Apparent Volume of Distribution (Vd) The Vd is basically a convenient method for describing how well a drug is removed from the plasma and distributed to the tissues. However, it doesn't provide any specific information about where the drug is or whether it is concentrated in a particular organ. A large volume of distribution implies wide distribution, or extensive tissue binding, or both. Conversely, ionized drugs that are trapped in plasma, will have small volumes of distribution. The Vd is basically a convenient method for describing how well a drug is removed from the plasma and distributed to the tissues. However, it doesn't provide any specific information about where the drug is or whether it is concentrated in a particular organ. A large volume of distribution implies wide distribution, or extensive tissue binding, or both. Conversely, ionized drugs that are trapped in plasma, will have small volumes of distribution.
14. Protein Binding Large fraction of drug bound to tissue
Unavailable for drug function
Easily measured in vitro (% bound)
Consequences
What if bound drug is displaced?
e.g. aspirin, warfarin displaces 1%
15. Clearance (CL)
16. Area Under the Curve (AUC)
17. Half-life (t˝) Time required to clear 50% of drug
Depends on Volume of Distribution (Vd) and Clearance (CL)
Multi-phasic (if you can capture the distribution phase)
Rule of Thumb: Drug is cleared in 5 half-lives
18. Other Important Parameters Peak plasma concentration
Bioavailability
Duration above a threshold concentration
Free drug vs. total drug
Cumulative dose
Bioactivation to active metabolite
19. PK Analysis Linear Pharmacokinetics
“First order” kinetics
Covers most drugs
Rate of change depends only on the current [drug]
Half-life remains constant no matter how high the concentration
AUC not affected by schedule
Example: doxorubicin For example, the AUC after a 60 mg/m2 bolus dose of doxorubicin equals the total AUC for three daily (or weekly) bolus doses of 20 mg/m2, which equals the AUC for the same dose administered as a 96-hour infusion. A second implication is that the AUC is proportional to the dose. Thus, if one measures the AUC for a 60 mg/m2 dose, one can estimate the AUC for a 90 mg/m2dose in the same patient as being 50% higher.For example, the AUC after a 60 mg/m2 bolus dose of doxorubicin equals the total AUC for three daily (or weekly) bolus doses of 20 mg/m2, which equals the AUC for the same dose administered as a 96-hour infusion. A second implication is that the AUC is proportional to the dose. Thus, if one measures the AUC for a 60 mg/m2 dose, one can estimate the AUC for a 90 mg/m2dose in the same patient as being 50% higher.
20. PK Analysis Non-Linear Pharmacokinetics (“zero order”)
Classic examples: ethanol, phenytoin
Saturable metabolism
Decreased CL at higher doses
Shortened infusion ? increased AUC
Examples: 5-FU, Taxol
Saturable absorption
Decreased proportional AUC at higher doses
Lengthened infusion ? increased plasma conc.
Examples: methotrexate, cisplatin This is clearly the case for 5-FU, probably due to saturation of its conversion to dihydrofluorouracil by the enzyme dihydropyrimidine dehydrogenase. 112 115 Schaaf et al. demonstrated that doubling of the 5-FU dose from approximately 7.5 mg/kg to 15 mg/kg (by IV bolus) resulted in a 135% increase in the mean AUC. 114 Since 5-FU is used on a variety of schedules, its nonlinear pharmacokinetic behavior may be one factor in its highly schedule-dependent effects.
The opposite situation arises when a drug's absorption from the gastrointestinal tract (or renal tubular reabsorption) is saturable. In this case, an increase in dose results in a less than proportional increase in the AUC. Gastrointestinal absorption of drugs that resemble natural compounds is frequently mediated by active transport processes in the gastrointestinal tract that display saturable kinetics. Folate analogues such as MTX or leucovorin and amino acid analogues such as melphalan are examples of drugs with saturable absorption. 119 121 Cisplatin appears to have nonlinear pharmacokinetics due to saturation of its renal tubular reabsorption. 122, 123 Forastiere et al. demonstrated that free plasma platinum is increased by 42% when the drug is given as a 24-hour continuous infusion, rather than as a 20-minute infusion. 122 Prolonged infusion was also associated with a greater than three-fold increase in the free platinum half-life
For saturable absorption, lengthening infusion of same amount of drug allows drug to “soak in”.This is clearly the case for 5-FU, probably due to saturation of its conversion to dihydrofluorouracil by the enzyme dihydropyrimidine dehydrogenase. 112 115 Schaaf et al. demonstrated that doubling of the 5-FU dose from approximately 7.5 mg/kg to 15 mg/kg (by IV bolus) resulted in a 135% increase in the mean AUC. 114 Since 5-FU is used on a variety of schedules, its nonlinear pharmacokinetic behavior may be one factor in its highly schedule-dependent effects.
The opposite situation arises when a drug's absorption from the gastrointestinal tract (or renal tubular reabsorption) is saturable. In this case, an increase in dose results in a less than proportional increase in the AUC. Gastrointestinal absorption of drugs that resemble natural compounds is frequently mediated by active transport processes in the gastrointestinal tract that display saturable kinetics. Folate analogues such as MTX or leucovorin and amino acid analogues such as melphalan are examples of drugs with saturable absorption. 119 121 Cisplatin appears to have nonlinear pharmacokinetics due to saturation of its renal tubular reabsorption. 122, 123 Forastiere et al. demonstrated that free plasma platinum is increased by 42% when the drug is given as a 24-hour continuous infusion, rather than as a 20-minute infusion. 122 Prolonged infusion was also associated with a greater than three-fold increase in the free platinum half-life
For saturable absorption, lengthening infusion of same amount of drug allows drug to “soak in”.
21. Audience Question #3: ��If you failed to abstain from one of these, but had to be at work and drug-free in one hour, which would be least likely to result in your dismissal? 5 mg oxycodone
150 mg erlotinib
Top-shelf (Patron) margarita
4-5 bong hits Oxycodone linear PK, 3 hr half life
Erlotinib linear PK at that dose, 36 hr half life
Margarita gone in 1 hr (1 oz)
Marijuana 24 hr half life (metabolites 45-60 day half life)Oxycodone linear PK, 3 hr half life
Erlotinib linear PK at that dose, 36 hr half life
Margarita gone in 1 hr (1 oz)
Marijuana 24 hr half life (metabolites 45-60 day half life)
22. What is ‘Translational Research’?
23. Translational Research “…the interphase between basic research and its application in a clinical setting for the diagnosis, treatment, or prevention of a disease.”
Dr. William Hait, Past Pres. AACR
Observation ? Practice
PK/PD is a cornerstone of translational research
24. PK/PD Modeling Preclinical animal data guides dose and schedule, but you still have to perform PK/PD in humans to confirm.
PK/PD bridges from animal to manPreclinical animal data guides dose and schedule, but you still have to perform PK/PD in humans to confirm.
PK/PD bridges from animal to man
25. PK Variability in Ovarian Cancer Patients�250 mg/m2, 24 hr infusion, 22-23 hr sample, n = 48 Shows how important PK variability is in evaluating toxicitiesShows how important PK variability is in evaluating toxicities
26. PK/PD modeling of Taxol-induced neutropenia Non-linear kinetics
Myelosuppression related to duration of threshold plasma concentration
[Taxol] = 0.05 mM
Prediction of disposition and toxicity Pharmacokinetic/pharmacodynamic relationship between duration spent at a plasma paclitaxel concentration > 0.05 pmol/L and percentage reduction in ANC in the first course of therapy. Symbols represent individuals treated at different doses and schedules (see Legend). Curve depicts the sigmoid Emax, model fit to the data. The broken portion of the curve represents that region for which data were not available.
Neutropenia wasn’t really dose-dependent because of the variability in metabolism saturation (nonlinear PK). Instead, it was dependent on duration of plasma concentration > 0.05 uM.Pharmacokinetic/pharmacodynamic relationship between duration spent at a plasma paclitaxel concentration > 0.05 pmol/L and percentage reduction in ANC in the first course of therapy. Symbols represent individuals treated at different doses and schedules (see Legend). Curve depicts the sigmoid Emax, model fit to the data. The broken portion of the curve represents that region for which data were not available.
Neutropenia wasn’t really dose-dependent because of the variability in metabolism saturation (nonlinear PK). Instead, it was dependent on duration of plasma concentration > 0.05 uM.
27. PK/PD Modeling�Effect of formulation on paclitaxel PK First-Order Elimination (Abraxane)
Rate of elimination is proportional to drug concentration
Constant fraction of drug eliminated per unit time Zero-Order Elimination (Taxol)
Rate of elimination constant regardless of drug concentration
Constant amount of drug eliminated per unit time
Abraxane has linear PK because no cremaphor
Taxol is zero order elimination meaning potential major increases in toxicity with small increases in doseAbraxane has linear PK because no cremaphor
Taxol is zero order elimination meaning potential major increases in toxicity with small increases in dose
28. paclitaxel (ABI_007)
nanoparticles
30 min infusion, q 21d
No cremaphor
No premeds
Linear kinetics
Clin Cancer Res 8:1038-1044 (2002) paclitaxel (Taxol)
6 hr infusion, q 21d
Cremaphor formulation
Premedication
Non-linear kinetics
J Clin Oncology 9:1261-1267 (1991) Take home message- difficult to predict tox with non-lin kineticsTake home message- difficult to predict tox with non-lin kinetics
29. PD Modeling Example: Pharmacogenetics � Myelotoxicity and UGT genetic polymorphisms Irinotecan
350 mg/m2
90 min infusion, q3w
n = 66
SN-38 metabolism dependent on UGT variant
Identification of patients predisposed to severe irinotecan toxicity
Most Pts have low risk of Grade 4 neutropenia on irinotecan, but Pts with 7/7 genotype have 50% incidence of Grade 4 neutropenia.Most Pts have low risk of Grade 4 neutropenia on irinotecan, but Pts with 7/7 genotype have 50% incidence of Grade 4 neutropenia.
30. Molecularly-targeted Drugs
31. Shift Towards Target-based vs. Compound-based Development Compound-based (backward)
Interesting compound discovered with activity in in vitro models
Target-based (forward)
Protein or gene targets identified on carcinogenesis pathway.
Drugs designed to interfere with these specific targets
32. EGFR as a Molecular Target Member of erbB family of receptor tyrosine kinases
EGFR (ErbB1), HER2/Neu (ErbB2), HER3 (ErbB3) and HER4 (ErbB4)
Overexpressed in various solid tumors
Overexpression has been correlated with poor prognosis
EGFR signaling is implicated in angiogenesis, proliferation, and inhibition of apoptosis
33. EGFR Mechanism
34. EGFR Targeted Therapy Neutralizing monoclonal antibody
cetuximab
competitive inhibitor
prevents dimerization
Tyrosine kinase inhibitors
erlotinib, gefitinib
reversible inhibitors
lapatinib
duel EGFR/erbB2 irreversible inhibitor Erlotinib clearance doubles in smokers
Gefitinib limited access only since 2005
Lapatinib approved in 2007 w/ capecitabine erb2 exp adv breast caErlotinib clearance doubles in smokers
Gefitinib limited access only since 2005
Lapatinib approved in 2007 w/ capecitabine erb2 exp adv breast ca
35. Issues with molecularly targeted EGFR inhibitors Mutation in EGFR
Activation of redundant pathways
Constitutive activation of downstream signaling factors
Ligand-independent activation of EGFR
36. Altered response to EGFR inhibitors EGFR mutations have been characterized in gliomas, NSCLC, breast, ovarian cancers
Activating mutations correlated with increased response to gefitinib in NSCLC
37. Resistance to EGFR inhibitors Resistance caused by activation of other tyrosine kinase receptors that bypass the EGFR pathway
38. Resistance to EGFR inhibitors
39. Resistance to EGFR inhibitors EGFR can be activated by integrins
cetuximab could not inhibit this pathway
40. Concerns with Targeted Therapy “The Butterfly effect”
Predicting toxicities of a single target is difficult when the target of interest is relatively upstream in a pathway
Example: bortezomib (Velcade) ? myelosuppression, fatigue, etc.
Dosing regimens are difficult to determine
High potency ? difficult detection of drug
Cytostatic mechanism ? low toxicity, MED vs. MTD
Targeted therapies are not as “specific” as we think (e.g., imatinib mesylate, sorafenib)
Pleiotropism
41. Concerns with Targeted Therapy (cont’d) Redundancy
Cells that “find a way” get rewarded and select for resistance
Delivery (chemistry)
The drug may not reach the target in vivo (PK)
Bogus mechanism
Almost all in vitro mechanisms are convenient to believe once the xenograft data is positive
A good (valid) biomarker is hard to find
42. How do we improve targeted therapies? Combinations
We need better tools to select the best patient/therapy combinations
43. Pharmacogenomics How variations in the genome affect the response to medications
44. Personalized therapy in ovarian cancer: A genomic approach� Dressman et al, JCO 25:517 (2007) Primary ovarian tumors collected at surgery from 119 patients
All patients rec’d platinum-based therapy
85 CR, 34 IR
DNA microarray analysis
Gene expression signatures used to predict oncogenic pathways activated in a tumor
Relationship between pathway activation and survival was analyzed in CRs and IRs
84 Complete Response, 34 Incomplete response
84 Complete Response, 34 Incomplete response
46. How is this helpful? Is it real? Potential (very cool) application of pathway prediction in this patient population
47. Practical Advice in PK Study Design
48. Patients should not be made to feel that the situation is out of their control.
Be aware of all regulations (HIPAA, others) regarding collection, storage, and use of collected blood and tissue.Patients should not be made to feel that the situation is out of their control.
Be aware of all regulations (HIPAA, others) regarding collection, storage, and use of collected blood and tissue.
49. Typical Phase 1/PK Study Goal
Capture adequate tissue samples to measure drug/metabolite levels over time
0, ˝, 1, 2, 4, 8, 24, 48 hr
Day 8, Day 15
Capture 4-5 half-lives if possible
May need to collect urine, other fluids?
50. Know your analyst
Ensure that the analytical technique is available
Ensure that the method is available, validated, and reliable
Define sample preparation
Know your sample size
The biometrist is your friend
visit them early and often
Be kind to nurses
Do you really want that 16 hr PK?
Don’t require a sample at the end of the infusion- too many things at once is trouble
51. Consider your patients
Don’t exsanguinate them
Extended PK sampling can be exhausting
Don’t sample from the infusion port
Define and monitor sample handling!!
Ensure study personnel are informed and understand SOPs
Shipping whole blood at room temp instead of frozen plasma ? Disaster
Cheap ink, cheap labels, and freezers don’t mix
53. Compound-based vs. Target-based Drug Development
