The effect of viscoelastic properties on mucociliary transport rate was investigated using the frog palate ciliated model. Mucociliary transportability of several hydrophilic polymeric gels with widely different viscoelastic characteristics were tested on the frog palate mucociliary model. An apparent negative relationship is observed between the relative transport rate (TR) and storage (G1) or loss (G2) modulus. However, a minimum in relative transport rate is observed at an apparent loss tangent (tan delta) value of between 0.7 and 0.9. A theoretical model for mucociliary transport is presented. The model predicted a minimum in transport rate at tan delta equal to 1.74 after adjustment for primary variation due to storage modulus (G1), which is in agreement with the observed frog palate transport rate. The model isolates the loss tangent (tan delta) and the magnitude of the complex modulus (magnitude of G*) as the important viscoelastic parameters for mucociliary transport. Optimum rheological characteristics with respect to slow transport rate can be achieved by using hydrophilic polymer gels with a large complex modulus and simultaneously with a loss tangent equal to 1.74.