1 / 13

Implications of Linear Low-Dose Extrapolation for Noncancer Risk Assessment

Implications of Linear Low-Dose Extrapolation for Noncancer Risk Assessment. Oliver Kroner, Lynne Haber, Rick Hertzberg TERA. **This case study is a characterization of the method, and is not intended as endorsement or opposition of linear extrapolation.

kiaria
Download Presentation

Implications of Linear Low-Dose Extrapolation for Noncancer Risk Assessment

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Implications of Linear Low-Dose Extrapolation for Noncancer Risk Assessment Oliver Kroner, Lynne Haber, Rick Hertzberg TERA

  2. **This case study is a characterization of the method, and is not intended as endorsement or opposition of linear extrapolation. Method 1: extend a straight line from the chosen BMDL adjusted to the human equivalent dose or concentration (HED or HEC). Method 2: linearize HED(C) dose-response data using probit transformation in logarithmic space. Fit regression line to the data and extend to the low-dose

  3. Method 1: Linear extrapolation from BMD Response Animal BMD Human Equivalent Dose UFS UFD UFA 0.1 Dose

  4. Results • Strengths: • simplicity • Provides Risk Specific Dose at any level of exposure • Weaknesses: • Risk estimates produced were highly conservative compared to current RfC/RfD methods • No consideration of biological understanding

  5. Panel Comments • Possibly useful for screening level assessment or priority setting, but should not be construed as accurate estimate of risk • Requested exploration of non-cancer linear extrapolation in log-dose, probit space

  6. Probit Transformation • Linearizes biological data • requires quantal population data • To allow graphing in log space, response rates were converted to Excess Risk [added risk(d) = P(d) - P(0)] for each dose group • a dataset of at least three test doses above the control From Casarett & Doull 2009

  7. Method 2: Linear extrapolation in Log-Dose, Probit Space Probit Response Animal Data Human Equivalent Dose 5 UFS UFD UFA Log Dose

  8. Summary of Results

  9. Conclusions • Simple • Provides estimate of risk at any level of exposure But, • Limited Applicability: • Restrictive data requirements permitted the use of four of the 25 chemicals considered • Inconsistent Results: • Risk estimates at the RfD/RfCranged from 1 x 10-12 (1,3-dichloropropene) to 0.5 (nitrobenzene).

  10. Extra Slides

  11. Areas of Uncertainty to Consider in Noncancer Dose Response Assessment Sub-chronic Animal Chronic Human Chronic Animal Response Reproductive UFL UFS 0.1 UFD PBPK UFH UFA Dose

  12. Calculation of Human Equivalence Dose or Concentration • Method 1 Benchmark Dose 95% Lower-bound confidence limit (BMDL) Uncertainty Factors: UFS, UFA, and UFD • Method 2Benchmark Dose (BMD) Uncertainty Factors: UFS, UFA, and UFD • Method 3.Benchmark Dose (BMD) Uncertainty Factors: geometric means of the UFS, UFA, and UFD • Method 4. Benchmark Dose (BMD) Uncertainty Factors: geometric mean of the UFA

More Related