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Volumn 5, Issue 20, 2013, Pages 9517-9522
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Nanophasic biodegradation enhances the durability and biocompatibility of magnesium alloys for the next-generation vascular stents
a,b,c
d
b
b
b,c
a
a,e
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Author keywords
[No Author keywords available]
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Indexed keywords
ALLOYING COMPOSITIONS;
BIODEGRA-DABLE MATERIALS;
BIODEGRADATION PATTERNS;
CARDIOVASCULAR STENTS;
ELECTROCHEMICAL CHARACTERIZATIONS;
HUMAN VASCULAR ENDOTHELIAL CELLS;
MECHANICAL DURABILITY;
SURGICAL INTERVENTIONS;
ALLOYS;
BIOCOMPATIBILITY;
BIODEGRADATION;
BIOLOGICAL MATERIALS;
BIOMEDICAL EQUIPMENT;
CHARACTERIZATION;
DEGRADATION;
DURABILITY;
FRACTURE MECHANICS;
MAGNESIUM ALLOYS;
MICROBIOLOGY;
TISSUE ENGINEERING;
TOXIC MATERIALS;
STENTS;
ALLOY;
BIOMATERIAL;
MAGNESIUM;
NANOMATERIAL;
ANIMAL;
ARTICLE;
CELL MOTION;
CELL SURVIVAL;
CHEMISTRY;
DISEASE MODEL;
DRUG EFFECT;
ELECTROCHEMICAL ANALYSIS;
HUMAN;
METABOLISM;
STENT;
UMBILICAL VEIN ENDOTHELIAL CELL;
DRUG EFFECTS;
TOXICITY;
ALLOYS;
ANIMALS;
BIOCOMPATIBLE MATERIALS;
CELL MOVEMENT;
CELL SURVIVAL;
DISEASE MODELS, ANIMAL;
ELECTROCHEMICAL TECHNIQUES;
HUMAN UMBILICAL VEIN ENDOTHELIAL CELLS;
HUMANS;
MAGNESIUM;
NANOSTRUCTURES;
STENTS;
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EID: 84884876512
PISSN: 20403364
EISSN: 20403372
Source Type: Journal
DOI: 10.1039/c3nr02912c Document Type: Article |
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Times cited : (103)
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References (23)
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