Comparing with the traditional heat pipe, the loop heat pipe(LHP) is a passive heat transfer device which has high heat removal and low thermal resistance even at long transporting distances. However, under high heat load condition, pores in the monoporous wick are occupied by vapor, and the heat transfer performance is thus restricted. Therefore, in this study, we intend to use biporous wick structure to improve this weakness. Since the surface tension of a self-rewetting fluid displays a non-linear variation as temperature changes, researchers regard it as a potential working fluid to improve the performance of capillary-pumping heat transfer device. Such method is easier and much simpler to accomplish compared with other more complicated systems; thus, if it is possible to improve the heat transfer performance through such an easy method, self-rewetting fluid will be more acceptable to the industry. Currently, there are already papers that apply this kind of working fluid to heat pipe systems, but applications to loop heat pipe have not been found. In this study, we use copper to manufacture the biporous wick to enhance the heat transfer performance. We then observe the influence of applying self-rewetting fluid in the loop heat pipe system. Experimental results show that using biporous wick efficiently increases the critical heat load and reduces the total thermal resistance. More specifically, the heat load increased from 150W to 350W and the total thermal resistance from 0.72to 0.32. Also, using self-rewetting fluid as the working fluid in a monoporous wick loop heat pipe system also increases the critical heat load and reduces total thermal resistance; that is, the heat load increased from 150W to 350W and the total thermal resistance decreased from 0.72 from 0.72to 0.32. On the other hand, under low heat load condition, applying self-rewetting fluid to the biporous wick loop heat pipe system only reduced the total thermal resistance very little. Furthermore, the critical heat flux is lower and total thermal resistance is also higher than using water as working fluid. We suggest that detailed assessment is definitely required in order to effectively use self-rewetting fluid to enhance the heat transfer performance of loop heat pipe. Key words: Loop heat pipe, biporous wick, vapor blanket, self-rewetting fluid, Marangoni effect