Scaffolds with nanofibers are being applied in tissue engineering due to its high porosities and surface area-to-volume ratios as well as a wide variety of topographical features to encourage cellular adhesion, migration, and proliferation. Furthermore, the physical properties can be easily altered by changing the size, arrangement and material of fiber. Thus, tissue engineering scaffold research using the electrospinning technique has been increased. The nanotopographies features created by electrospinning can be separated into two main categories: unordered topographies and ordered topographies. Scaffolds fabricated by electrospinning, the fibers are typically randomly oriented in the form of nonwoven mats. The structure with well-ordered fibers not only can improve mechanical properties but also has better biocompatibility. There have been a few approaches to improve the orderliness of electrospun fibers, but it is difficult to fabricate tubular structure with aligned architecture. The polymers we used are polylactic acid (PLA) and poly(ethylene oxide) (PEO). By combining mandrel and two parallel conductors, and using the rotating mandrel as ground target to collect fibers, we achieved to fabricate small diameter tubular structures with aligned nanofibers at lower tangential speed. The tubular structure with aligned topography which mimics the native artery and with better mechanical properties can be applied in blood vessel engineering.