Using the potent developmental toxicant 2-methoxyethanol (2-ME) as a prototypical compound, a physiologically based pharmacokinetic (PBPK) model was developed to describe the disposition of its primary metabolite and proximate toxicant 2-methoxyacetic acid (2-MAA) in the pregnant CD-1 mouse. Data were collected during early, mid, and late organogenesis, specifically Gestation Days (GD) 8, 11, and 13 (GD 0 = plug-positive date). Pharmacokinetics and tissue partition coefficients for 2-MAA were determined in maternal plasma and conceptus on GD 8 and in maternal plasma, embryo, and extraembryonic/amniotic fluid (EAF) on GD 11 and 13. For simulation of GD 8 data, the conceptus was described as a single compartment, combining the yolk sac placenta, embryo, EAF, and decidua. For GD 11 and 13, the placenta, embryo, and EAF were explicitly described. Several hypotheses were tested for their ability to predict 2-MAA dosimetry. These hypotheses were encoded as alternative models having (a) blood flow-limited delivery of 2-MAA to model compartments, (b) pH trapping of ionized 2-MAA within compartments, (c) active transport of 2-MAA into compartments, and (d) reversible binding of 2-MAA within compartments. While the flow-limited description adequately predicted GD 8 dosimetry, the best simulations of the pharmacokinetic data collected on GD 11 and 13 were obtained with the active transport models. Since the mechanism by which 2-MAA accumulates into the embryo and EAF has not yet been elucidated, these mathematical descriptions are empirical. Further development of this PBPK model for 2-MAA in pregnant mice, in particular its scale-up to humans, will facilitate more realistic human risk assessments for the developmental toxicity of 2-ME and related compounds.