Dosimetry of [15O]water: a physiologic approach

Med Phys. 1996 Jan;23(1):159-68. doi: 10.1118/1.597793.

Abstract

Earlier dosimetry estimates for [15O]water assumed its instantaneous equilibrium with total body water. This assumption leads to an underestimation of the absorbed doses to organs with high blood flows, since the biodistribution of this short-lived radiopharmaceutical is dependent upon blood flow to organs. We have developed a physiologically based whole body blood flow model (WBBFM) using a commercially available icon-driven mathematical simulation software package and applied it to the reevaluation of [15O]water dosimetry in humans. The WBBFM uses multiple parallel compartments to represent organs, heart chambers, the injection site for [15O]water, and blood sampling sites (arterial and venous). Input values to the WBBFM include organ blood flows, organ masses, organ water volumes, organ:blood partition coefficients, injected activity and S-values of [15O]. The WBBFM is based on the same assumptions that are used in calculating regional blood flow using [15O]water and simulates the human body closely in its physiologic response. The activity in each organ is derived from the simulation and is used to calculate absorbed doses. The WBBFM calculated absorbed doses in microGy/MBq (mrad/mCi) to various organs are as follows: heart--2.66 (9.84), kidneys--2.20 (8.15), thyroid--1.83 (6.78), brain--1.66 (6.13), ovaries--1.25 (4.61), breast--1.24 (4.59), and small intestine--1.03 (3.83). These values are approximately two- to threefold higher than the earlier estimates of Kearfott [J. Nucl. Med. 23, 1031-1037 (1982)] and similar to the recent findings of Herscovitch et al. [J. Nucl. Med. 34, 155P (1983)]. We believe this approach yields more realistic dosimetry estimates for [15O]water. Accordingly, we have revised the amount of [15O]water administered during regional blood flow studies at our institution. The relative ease and accuracy of this approach suggests its usefulness in dosimetry estimation for other freely diffusible radiopharmaceuticals.

MeSH terms

  • Biophysical Phenomena
  • Biophysics
  • Blood Circulation / physiology
  • Body Water / metabolism
  • Female
  • Humans
  • Male
  • Mathematics
  • Models, Biological
  • Oxygen Radioisotopes / administration & dosage*
  • Oxygen Radioisotopes / pharmacokinetics
  • Radiometry
  • Regional Blood Flow / physiology
  • Tomography, Emission-Computed / methods
  • Tomography, Emission-Computed / statistics & numerical data
  • Water / administration & dosage*
  • Water / metabolism

Substances

  • Oxygen Radioisotopes
  • Water