Case-Studies%20of%20Dose-Dependent%20Transitions%20in%20Toxicology - PowerPoint PPT Presentation

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Case-Studies%20of%20Dose-Dependent%20Transitions%20in%20Toxicology

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Overall Objectives Demonstrate the existence of new modalities of toxic tissue injury with increasing dose using a series of representative case examples. – PowerPoint PPT presentation

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Title: Case-Studies%20of%20Dose-Dependent%20Transitions%20in%20Toxicology


1
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2
Overall Objectives
  • Demonstrate the existence of new modalities of
    toxic tissue injury with increasing dose using a
    series of representative case examples.
  • Examine the impact of dose-dependent transitions
    on the risk assessment process.
  • Provide a forum for multi-sector discussion of
    data needs, experimental design, and principles
    for incorporating dose-dependent transitions into
    risk assessment decisions.

3
Challenge
  • The shape of the dose-response curve may be
    significantly affected by the existence of
    multiple mechanisms of toxicity. For example,
    critical, limiting steps in any given mechanistic
    pathway may become overwhelmed with increasing
    exposures, signaling the emergence of new
    modalities of toxic tissue injury at higher
    doses.

4
Challenge (cont.)
  • Chemical-specific case studies show that, as the
    dose of an agent increases, dose-dependent
    transitions such as receptor interactions,
    altered homeostasis, and saturation of
    pharmacokinetic and repair mechanisms can and do
    occur.

5
Challenge (cont.)
  • Determining which mechanisms are operative
    throughout the dose-response curve and examining
    the impact of these dose-dependent transitions in
    mechanisms of toxicity will have significant
    implications for interpretation of data sets for
    risk assessment.

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8
Basic Tenet
  • The course from the point of exposure to
    expression of a biological response consists of a
    series of interrelated yet independent processes,
    each with its own set of finite kinetic
    characteristics.
  • Saturation of any one of these active processes
    alters the course of the toxic response, which
    may be reflected in a deviation from a log-linear
    relationship as one explores the full
    dose-response curve.
  • Deviations from linear dose-response
    relationships confound the extrapolation of
    experimental laboratory data to accurately
    predict human health outcomes

9
Finite capacity
  • Absorption
  • Passive (dose-linear)
  • Active
  • Facilitated
  • Distribution
  • Serum binding
  • Tissue transporters
  • Uptake glycos
  • Export ABC transporters
  • Tissue storage
  • Specific binding proteins fabp, GST, MT
  • Non-specific storage depots lipid
  • Excretion
  • Filter
  • Secrete organic anions
  • Metabolic transformation
  • Activation P450, MFO
  • Detoxification conjugations, esterase
  • Cofactor depletion conjugate base

10
Finite capacity
  • Dynamic -
  • Receptor
  • Finite number
  • association/dissociation
  • turnover/reactivation
  • OPs, PPAR, ANS
  • Target -
  • Defense
  • oxidative stress
  • Repair
  • DNA
  • Replacement
  • cell necrosis-stimulated proliferation

11
Examples/Case Studies
  • Metabolic activation/detoxification
  • Acetaminophen
  • Ethylene Glycol

12
Acetaminophen Metabolic Disposition
13
Acetaminophen protein adducts/ GSH depletion -
Time Course
(Mitchell et al.)
14
Acetaminophen protein adducts/ GSH depletion -
Dose-dependence
(Mitchell et al.)
15
APAP Binding fGSH
(Hinson et al.)
16
Acetaminophen Metabolic Disposition
17
P450-dependent Metabolic Disposition of
Acetaminophen
(Mitchell et al.)
18
Acetaminophen
19
Ethylene Glycol
(EG)
(GA)
Rate-limit
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21
EG GA Oxal
(Marshall, 1982)
22
Ethylene Glycol
(EG)
(GA)
23
Examples/Case StudiesAltered Repair/Replacement
  • Propylene oxide

24
O
Propylene Oxide
CH3
25
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26
Conclusions/concerns
  • Documentation of dose-dependent transitions
  • Dictated by saturation of specific kinetic steps
  • Necessity to identify and characterize
    mechanisms

27
Conclusions/concerns
  • Key to applying to safety assessment is where
    transitions occur with respect to exptl dose and
    human dose
  • Explore mechanisms at doses in range of the
    transitions

28
Conclusions/concerns
  • Dose extrapolations assume that in the absence of
    evidence to the contrary, similar transitions
    occur across species, gender, age (targets,
    metabolic profile, disposition, receptors,
    defense, repair, cell cycle kinetics)

29
Conclusions/concerns
  • Now that we recognize the existence of
    dose-dependent transitions in drug-induced
    toxicities, how do we go about applying the
    concept to reducing the uncertainty of safety
    assessment estimates?

30
Proposed Definitions
  • Transition - a change in the relationship of
    the response rate as a function of dose, which
    may be indicated as a change in the slope of the
    dose-response curve and reflects a change in key
    underlying kinetic and/or dynamic factors that
    influence the mechanism responsible for the
    observed toxicity.
  • A transition usually occurs over a range of doses

31
Importance/Relevance
  • Transitions in the dose-response curve occur
    experimentally for a number of differentially-acti
    ng chemicals and should be factored into the risk
    assessment process to reduce uncertainty
  • Risk assessments should be based on the best
    science consideration of dose-dependent
    transitions in the mechanism of toxicity is an
    example of integrating the best science.

32
Origins
  • Transitions may reflect either kinetic or dynamic
    determinants
  • Importance of both PBPK and biologically-based
    modeling
  • Identification of key determinant factor
    influencing that transition
  • Identification of adaptive/compensatory responses
    in the respective species
  • Essential elements (O2, Fe, Cu, Mn, Vit A)

33
Importance/Relevance
  • Identification of the transition phase in the
    dose-response relationship is critical to the
    effective extrapolation between species, gender,
    age, etc.
  • Extrapolation beyond the tested dose-range
  • Estimating margins with respect to exposure

34
Dose-Selection
  • Dose selection should emphasize the transition
    region of the dose-response curve.
  • Current testing strategies likely will not
    capture transitions in the dose-response
    relationship.
  • Key concern is where within the dose-response
    relationship the transition occurs with regard to
    other points, such as NOAEL

35
Mechanism-based Biomarkers
  • Characterization of the mechanism of toxicity in
    animals reveals useful biomarkers of response,
    which are essential to anticipating points of
    departure in the dose-response relationship for
    humans.
  • Focus on endpoints that are linked to observed
    adverse effect and reliable in humans (bridging
    biomarkers).
  • Opportunity to consider human data.

36
Mechanism-based Biomarkers
  • Assume that more molecular end-points yield a d/r
    curve to the left (more sensitive) of the actual
    whole animal toxic end-point
  • A better understanding of molecular mechanisms
    will allow the integration of new approaches such
    as genomics, etc. in the R/A and R/C processes

37
Interspecies Concordance
  • If a dose-dependent transition is established for
    experimental species, the default assumption is
    that a similar transition occurs in humans.
  • Unless there is evidence to the contrary, it is
    assumed that the same mechanisms of toxicity are
    operative in humans as in experimental species.

38
Implementation
  • Applying the concept of dose-dependent
    transitions in R/A requires a much better
    understanding of exposure cant be exclusively
    hazard-driven.
  • Must provide incentives to generate the data

39
Achieving Acceptance
  • Acceptance is a far greater hurdle than
    conducting the scientific studies
  • there is a critical need for communication to
    convince the risk managers of the value for
    change.

40
Conclusion
  • Risk assessments should be based on the best
    science consideration of dose-dependent
    transitions in the mechanism of toxicity is an
    example of integrating the best science.
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