Structure Optimization on FEM Biomechanical Model of Bioabsorable Pure Magnesium Skin Staple

Yong Hua Lao; Yue Shan Huang; Wei Rong Li; Ying Jun Wang

doi:10.4028/www.scientific.net/AMR.1049-1050.511

Paper Titles

The Stack Soil Management for Construction Site
p.487

On the Use of Waste Materials in Emergency Shelter - A Case Study on Ya’an Post-Earthquake Resettlement
p.491

Quality Control of CSG with P-Wave Speed Measurement
p.497

Public Landscape Regeneration Design Strategy in the Old City Reconstruction Based on the Restoration Ecology
p.505

Structure Optimization on FEM Biomechanical Model of Bioabsorable Pure Magnesium Skin Staple
p.511

Progress of Intravascular Optical Coherence Tomography Image Technology and Vascular Three-Dimensional Reconstruction
p.515

A Heuristic Link Selection for Radio Frequency Tomography Based on BCS: Principle and Method
p.520

A Heuristic Link Selection for Radio Frequency Tomography Based on BCS: Application
p.526

Improved Ant Colony Algorithm and Application in Sequence Images of Prostate DWI Registration
p.530

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 1049-1050Structure Optimization on FEM Biomechanical Model...

Structure Optimization on FEM Biomechanical Model of Bioabsorable Pure Magnesium Skin Staple

Abstract:

Skin Stapler is an alternative instrument, which makes surgy easily and quickly and owns fine-looking effect without scars after the wound healed, to traditional surgical suture for the wound skin sewing. Magnesium recently is considered to develop medical implants because of its beneficial biocompatibility and bioabsorability. Due its less mechanical strength than traditional 316L stainless steel used in common staple, this paper try to optimize the structure of pure magnesium skin staple by FEM models and simulation as so to assure its biomechanical safty. Using ADINA software, two staples with different pre-bended shoulders and the traditional staple without shoulder are modeling to analyze its stress and plastical strain during structural deformation under load. The results, not only of pure magnesium models but also of 316L stainless steel models, showed that the shoulders optimization on staple structure has important role in its mechanical performance. The research increases the possibility of bioabsorable magnesium material application on medical skin staple.