Bioabsorbable zinc alloys for use in urological surgery.

PURPOSE: Non-absorbable clips are widely used in urologic surgery and they may come in contact with an open urinary tract intraoperatively. As a result, stray clips in the urinary tract and associated intractable infections have been reported. We developed a bioabsorbable metal and evaluated whether it would dissolve if it strayed into the urinary tract. METHODS: We prepared four types of alloys mainly comprising zinc (Zn) with small amounts of magnesium (Mg) and strontium (Sr), and the biological effects, degradability, strength, and ductility were investigated. Each alloy was implanted in the bladder of five rats for 4, 8, and 12 weeks. The alloys were removed and evaluated for degradability, stone adhesion, and tissue changes. The Zn-Mg-Sr alloy had degradability and no stone adhesion in the rat experiments, and it was implanted in the bladders of five pigs for 24 weeks. The Mg and Zn levels in the blood were measured, and staple changes were confirmed by cystoscopy. RESULTS: Zn-Mg-Sr alloys showed the best degradability of 6.51% at 12 weeks. In pig experiments, the degradation rate was 3.72% at 24 weeks. None of the pigs had changes in the Zn or Mg concentrations in the blood. Overall, the bladder incision was healed and the gross pathology showed wound healing. CONCLUSIONS: The Zn-Mg-Sr alloys were safely used in animal experiments. Furthermore, the alloys are easy to process and can be formed into various shapes, such as staples, making them useful in robotic surgery.

A heterojunction photocatalyst composed of zinc rhodium oxide, single crystal-derived bismuth vanadium oxide, and silver for overall pure-water splitting under visible light up to 740 nm.

We recently reported the synthesis of a solid-state heterojunction photocatalyst consisting of zinc rhodium oxide (ZnRh2O4) and bismuth vanadium oxide (Bi4V2O11), which functioned as hydrogen (H2) and oxygen (O2) evolution photocatalysts, respectively, connected with silver (Ag). Polycrystalline Bi4V2O11 (p-Bi4V2O11) powders were utilized to form ZnRh2O4/Ag/p-Bi4V2O11, which was able to photocatalyze overall pure-water splitting under red-light irradiation with a wavelength of 700 nm (R. Kobayashi et al., J. Mater. Chem. A, 2016, 4, 3061). In the present study, we replaced p-Bi4V2O11 with a powder obtained by pulverizing single crystals of Bi4V2O11 (s-Bi4V2O11) to form ZnRh2O4/Ag/s-Bi4V2O11, and demonstrated that this heterojunction photocatalyst had enhanced water-splitting activity. In addition, ZnRh2O4/Ag/s-Bi4V2O11 was able to utilize nearly the entire range of visible light up to a wavelength of 740 nm. These properties were attributable to the higher O2 evolution activity of s-Bi4V2O11.

Photocatalytic hydrogen evolution over ß-iron silicide under infrared-light irradiation.

We investigated the ability of ß-iron silicide (ß-FeSi2) to serve as a hydrogen (H2)-evolution photocatalyst due to the potential of its conduction band bottom, which may allow thermodynamically favorable H2 evolution in spite of its small band-gap of 0.80 eV. ß-FeSi2 had an apparent quantum efficiency for H2 evolution of ∼24% up to 950 nm (near infrared light), in the presence of the dithionic acid ion (S2O6(2-)) as a sacrificial agent. It was also sensitive to infrared light (>1300 nm) for H2 evolution.