Coronary angioplasty is commonly used as a treatment for myocardial infarction. Initial challenges of bare metallic stents (BMS), e.g., early thrombosis and in stent restenosis (ISR) from proliferation and migration of vascular smooth muscle cell (SMC) are treated with anticlotting drugs and drug eluting stents (DES), respectively. But very late stent thrombosis (ST) is another challenge which causes restenosis of the stenotic arteries [1]. Improvement of reduced in stent restenosis (ISR) rate from 20–25% to around 8.6% using DES instead of BMS is hampered by stent fracture (SF) associated with DES [2]. Moreover, BMS shows very late ST (>5 years), whereas improved DES shows late ST (>1 year). In addition, clinically silent DES SF is associated with ISR and ST and pathologic investigation indicates 29% incidence of SF with about additional 5% incidence associated with adverse effect, e.g., inflammation, ulceration, avulsion, etc. [3]. Use of long overlapping stents with severe angulation, balloon overexpansion and vessel tortuosity reveal potential predictors of stent fracture in addition to stent design [4]. This indicates a fatigue process occurring under cyclic loading associated with the heart beats which inevitably will lead to Severe SF for any material and stent design. Long term problems of permanent stents require to improve material strength or biodegradability [5]. Due to lower ultimate tensile strength with polymeric stents, current research is directed to develop degradable metals and alloys for stents. Currently, iron and magnesium based alloys are investigated as degradable stent material [6]. Cold spray, introduced in this work, provides smaller grain size and good mechanical integrity as compared to powder metallurgy technique. Since cold spray coating deposition occurs at much lower temperature than powders melting point, it reduces thermally induced harmful effects commonly observed in conventional thermal spray coatings [7]. In this work, galvanic or bimetallic corrosion is introduced on the coating at the particle level, thus generating micro galvanic corrosion. In order to achieve this, a metal is selected with a nonreactive alloy which maintains a galvanic gap or potential difference in the galvanic table. Selected metals need to be available in powder form and cold spray able.