Molecules in solution experience rotational diffusion. For large biomolecules such as proteins, the rotational correlation times, τ_c, are often on the nanosecond time scale. PAC isotopes exhibit lifetimes of the intermediate nuclear level on the time scale of nanoseconds, and the hyperfine interactions measured by PAC spectroscopy are therefore sensitive to dynamics on this time scale. With this work we have compiled experimentally determined rotational correlation times, τ_c^exp, reported in the literature in the slow reorientation limit, and compared to calculated rotational correlations times, τ_c^calc, using the simple Stoke-Einstein-Debye approximation. In a number of cases τ_c^exp agrees with the calculated value within the experimental error, including proteins which are expected to be rigid. In several cases, however, τ_c^exp is smaller than the theoretical value, presumably due to local dynamics at the PAC probe site. In support of this interpretation, τ_c^exp < τ_c^calc is observed for many enzymes, which are expected to display dynamics at the PAC probe site due to water coordination to the active site metal.