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The goal of this paper is to develop a numerical model for physiological mech- anisms that help to compensate reduced blood flow caused by a peripheral arterial stenosis. Thereby we restrict ourselves to the following compensation mechanisms: Metabolic regulation and arteriogenesis, i.e., growth of pre-existing collateral arteries. Our model is based on dimensionally reduced differential equations to simulate large time periods with low computational cost. As a test scenario, we consider a stenosis located in the right posterior tibial artery of a human. We study its impact on blood supply for different narrowing degrees by the help of numerical simulations. Moreover, the efficiency of the above compensation mechanisms is examined. Our results reveal that even a com- plete occlusion of this artery exhibiting a cross-section area of 0.442 $cm^2$ can be compensated at rest, if metabolic regulation is combined with collateral arteries whose total cross-section area accounts for 8.14 \% of the occluded artery.