This thesis studies experimentally the traveling wave dielectrophoretic pump, which is a micropump suitable for delivering two-phase suspension medium, such as our blood. The pump is essentially a straight microchannel with square cross section with array of electrodes built on one of its walls. Ac voltage is applied to the electrodes with a certain phase shift on neighboring electrodes. Both conventional and traveling wave dielectrophorsis are generated and drive the suspended particles (or cells) in motion. When the traveling wave dielectrophoretic force dominates the particle motion, the particles move along the direction of increasing phase if the imaginary part of the Clausius factor is positive (or vice versa), drag their surrounding fluid, and thus the whole medium is transported. We first manufactured the pump via MEMS techniques and demonstrate the feasibility of the above idea for pumping using human blood. Then we studied the performance of the pump for different parameters, including applied electric voltage, electric frequency, phase shift for neighboring electrodes, number of electrodes, concentration of suspended particles (by varying blood/saline ratio), different particles (blood cells of wister and human), without and with assistant electrodes before the normal electrode array, and different driving sources (functional generator or small IC chip). It is found that we have larger cell velocity for larger voltage, more electrodes, 90o phase shift (in comparing with 120o), larger cells, and with assistant electrodes. Typical cell velocity of human blood reaches 28.4 μm/s for 6 volts, 10 MHz, 90 phase shift and 24 electrodes with assistant electrodes. The pump also works when it is integrated with a IC chip, which shows the possibilities of building a small portable device. The result may find application in biomedical area.