A mechanism-based dosimetry model was developed to describe 2,4,4-trimethyl-2-pentanol (TMP-2-OH) dosimetry and renal alpha 2u-globulin (alpha 2u) nephropathy in the male Fischer 344 rat. Experimental data were collected to estimate the chemical-specific parameters (metabolic constants, tissue solubility, and oral absorption rate) necessary to describe TMP-2-OH dosimetry in male rats. The concentrations of alpha 2u and TMP-2-OH were measured in male rats up to 64 hr after a single oral dose of TMP-2-OH (6, 60, or 600 mg/kg). The model predicted the time course behavior of TMP-2-OH and alpha 2u in the kidney, but overestimated their renal concentrations by two or threefold. Simulations of renal alpha 2u concentration were sensitive to changes in TMP-2-OH-alpha 2u-binding affinity and degradation rate of the TMP-2-OH-protein complex. In contrast, simulation of the concentration of TMP-2-OH in the kidney was most sensitive to the amount of protein present. Oral absorption of TMP-2-OH was dose dependent. The model predicted that alpha 2u and TMP-2-OH concentration in the kidney is sensitive to changes in the rate of TMP-2-OH absorbed after oral administration. This model permitted a more rigorous evaluation than has previously been possible of the combination of protein characteristics and chemical dosimetry required for the accumulation of alpha 2u in the kidney of male rats. The behavior of the model is consistent with the qualitative aspects of the alpha 2u hypothesis. However, further characterization of alpha 2u distribution and renal hydrolysis will be required in order to fully characterize the hypothesis at the quantitative level.