Electrorotation (ER) has become a very powerful diagnostic technique for the measurement of dielectric properties of cells. However, only a few papers have investigated the electric-induced rotation of particles in a stationary alternating (AC) electric field instead of a rotating electric field. In this study, a microchip composed of a top-grounded electrode, flow chamber and bottom chess-type electrode arrays was used to construct a stationary non-uniform AC electric field for the manipulation of cells by dielectrophoretic force. We focused on the effects of metal and dielectric nanoparticles uptaken by cells under ER, by using human promyelocytic leukemia cells (HL-60), 13 run Au and 19 mn SiO2 nanoparticles. As revealed by the experimental results, both the percentage of cells in rotation and the range of rotational (ROT) frequency for the uptake of Au nanoparticle cells were higher and wider than in the case of SiO2 nanoparticles. In addition, the rotation of lone cells and pearl-chain cells under non-uniform and uniform electric field were quantitatively investigated, respectively. The membrane capacitance and membrane conductance of HL-60 cells can be extracted from the ROT spectra as 10.18 +/- 1.92 mF/m(2) and 1500 +/- 321 S/m(2), respectively. In general, the ER of cells in a stationary AC electric field can be attributed to the highly non-uniform electric field and non-uniform dispersion of nanoparticles within cells; therefore, the electrical properties of uptaken nanoparticles and the aggregation phenomenon have significant influences on the resulting electrical torque.