In electronics cooling, the junction temperature must be kept as low as possible to ensure the safe operation and stability of the electronic components. The problem becomes more severe since the electronic components always has discrete and concentrated heat source feature that accentuates the associated phenomenon. Therefore, microchannel employing liquid cooling is a good solution to eliminate the gigantic heat resistance caused by high flux concentrated heat sources. This study investigates the effect of configuration for microchannel heat sink on the overall performance both experimentally and numerically. The influence of the configurations of the manifolds is also examined. It is found that the forced convection is the main heat transfer mechanism but thermal conduction effect also plays essential role. The temperature distribution of the heat source becomes more non-uniform when the supplied heat is increased. To examine the influence of discrete heat source, the supplied heat source is divided into three separate heating sources. The results show a significant effect of the concentrated heat source. It is found that the deviation of temperature is also related to the supplied heat and the location of supplied heat source.