Exploring the Influence of Biologically Relevant Ions on the Corrosion Behavior of Biodegradable Zinc in Physiological Fluids.

This work presents a study on the influence of biologically relevant ions on the corrosion of zinc (Zn) in physiological fluids. Electrochemical techniques were used to investigate the degradation of pure Zn exposed to different physiological electrolytes containing chlorides, carbonates, sulfates, and phosphates. The corrosion behavior of Zn in the solutions over a 7-day period was also assessed. SEM, EDS, and FTIR were used to analyze corrosion products. With respect to corrosion, the most aggressive ions are chlorides, which induce localized corrosion, while carbonates and phosphates reduce the corrosive attack of the chloride on Zn while inducing uniform corrosion. Sulfates reduce the corrosion rate by disrupting Zn's passive layer. The overall corrosion rate of Zn changed in each electrolyte depending on the nature of the solution and the corrosion product formed. These findings will be useful in predicting the in-service behavior of future biodegradable Zn medical implants.

Design, mechanical and degradation requirements of biodegradable metal mesh for pelvic floor reconstruction.

Pelvic organ prolapse is the herniation of surrounding tissue and organs into the vagina and/or rectum and is a result of the weakening of pelvic floor muscles, connective tissue, and fascia. It is widely accepted that 50% of women will develop prolapse, with the prevalence increasing with age, and up to 10-20% of those seek evaluation for their condition. Suture repairs of pelvic floor defects are associated with a high failure rate, and permanent meshes were introduced to reduce the recurrence rate. The meshes were successful in reducing the rate of recurrence but were also associated with a higher rate of complications (pain or erosion into surrounding organs) and as such have been banned in many countries. New materials that are able to provide tissue support without complications are urgently required. A promising new material may be a biodegradable metal, which provides support during healing and subsequently completely degrades. We summarise pelvic mesh usage, and evaluate the use of a biodegradable metal, which has advantages of biocompatibility, antibacterial properties, and mechanical properties. The remaining challenges are discussed as follows: (1) degradation rate, (2) stiffness, (3) corrosion fatigue, (4) zinc aging, and (5) MRI artifacts.