摘要:This work is concerned with the analysis of blood flow through inclined catheterized arteries having a balloon (angioplasty) with time-variant overlapping stenosis. The nature of blood in small arteries is analyzed mathematically by considering it as a Carreau nanofluid. The highly nonlinear momentum equations of nanofluid model are simplified by considering the mild stenosis case. The formulated problem is solved by a homotopy perturbation expansion in terms of a variant of the Weissenberg number to obtain explicit forms for the axial velocity, the stream function, the pressure gradient, the resistance impedance and the wall shear stress distribution. These solutions depend on the Brownian motion number, thermophoresis number, local temperature Grashof numberGr and local nanoparticle Grashof numberBr. The results were also studied for various values of the physical parameters, such as the Weissenberg numberWi, the power law indexn, the taper angleφ, the maximum height of stenosisδ*, the angle of inclinationα, the maximum height of balloonσ*, the axial displacement of the balloon*,dz the flow rateF and the Froud numberFr. The obtained results show that the transmission of axial velocity curves through a Newtonian fluid (Wi=0,n=1,Gr=0,Br=0,Nt=0, Nb≠0) is substantially lower than that through a Carreau nanofluid near the wall of balloon while the inverse occurs in the region between the balloon and stenosis. The streamlines have a clearly distinguished shifting toward the stenotic region and this shifting appears near the wall of the balloon, while it has almost disappeared near the stenotic wall and the trapping bolus in the case of horizontal arteries and Newtonian fluid (Wi=0,n=1,Gr=0,Br=0,Nt=0,Nb≠0) does not appear but for the case of Carreau nanofluid bolus appears.