Nanofluid is a liquid suspended uniformly and stably with nano particles. The convection heat transfer of TiO2-water nanofluid in straight and zigzag micro channels were studied for different particle volume fractions, different Reynolds number and different applied heating power. The channels were fabricated with PDMS on a silicon wafer with also both the heating and temperature sensing electrodes deposited on the substrate. It was found that a different amount of input power (from several % up to 80% ) can be delivered to the fluid (water or nanofluid) flow inside the channel, and a method was proposed for quantifying such a power fraction, with the rest lost into the surrounding. For the forced that convection inside the channel, we found that the heat transfer coefficient increased as the Reynolds number increases (a feature for all the fluid), and as the volume fraction increases. However, the increase associated with the application of nanofluids is minor. Also the heat transfer of the zigzag micro channel is higher than that of the straight micro channel.