The objective of this study was to develop a device to mimic a microfluidic system of human arterial blood vessels. This device integrates fluid shear stress (FSS) and cyclic stretch (CS) which are the two major mechanical stimulations in cardiovascular systems. The endothelial cells (ECs) were injected into the microchannel and placed into an incubator (37 °C, 5 % CO2), using a programmable air pressure, a syringe pump and a stage top incubator(STR) combined with the microscope. The system can realize real-time observation of dynamic morphological change of cells in different flow fields (continuous flow, reciprocating flow and pulsatile flow). 　　In our study, microfluidic device was made by polydimethylsiloxane (PDMS) using soft lithography process, PDMS is an ideal material for this device since it is optically transparent, elastic and biocompatible. We expose the PDMS and glass to an air plasma, surface-oxidized PDMS can seal to glass to enclose the channel, which is completed our microfluidic device. PDMS use as materials reduces the time, complexity, and cost of prototyping and manufacturing, and the field of Lab on a Chip can be rapidly developed. 　　This study used bovine aortic endothelial cells (BAECs) are subjected to haemodynamic forces in the form of fluid shear stress and cyclic stretch resulting from blood flow and blood pressure. The EC change in function in response to mechanical stimuli, which is also accompanied by an apparent morphological change, including ECs align their cytoskeleton proteins with the blood flow direction and paxillin redistribution to the cell periphery. Investigations on how ECs respond to combined shear stress and cyclic stretch will help us to better understand how altered mechanical environment affects ECs function, morphological and associated cardiovascular disease development. Understanding the relationship between mechanical stimuli and vascular pathology can lead to improved treatments.