A smart coating with integrated physical antimicrobial and strain-mapping functionalities for orthopedic implants.
Yi ZhangJinsong CuiKuan-Yu ChenShanny Hsuan KuoJaishree SharmaRimsha BhattaZheng LiuAustin Ellis-MohrFufei AnJiahui LiQian ChenKari D FossHua WangYumeng LiAnnette M McCoyGee W LauQing CaoPublished in: Science advances (2023)
The prevalence of orthopedic implants is increasing with an aging population. These patients are vulnerable to risks from periprosthetic infections and instrument failures. Here, we present a dual-functional smart polymer foil coating compatible with commercial orthopedic implants to address both septic and aseptic failures. Its outer surface features optimum bioinspired mechano-bactericidal nanostructures, capable of killing a wide spectrum of attached pathogens through a physical process to reduce the risk of bacterial infection, without directly releasing any chemicals or harming mammalian cells. On its inner surface in contact with the implant, an array of strain gauges with multiplexing transistors, built on single-crystalline silicon nanomembranes, is incorporated to map the strain experienced by the implant with high sensitivity and spatial resolution, providing information about bone-implant biomechanics for early diagnosis to minimize the probability of catastrophic instrument failures. Their multimodal functionalities, performance, biocompatibility, and stability are authenticated in sheep posterolateral fusion model and rodent implant infection model.
Keyphrases
- soft tissue
- physical activity
- end stage renal disease
- patient reported outcomes
- high resolution
- ejection fraction
- chronic kidney disease
- staphylococcus aureus
- newly diagnosed
- risk factors
- high density
- acute kidney injury
- mass spectrometry
- body composition
- climate change
- bone mineral density
- pain management
- peritoneal dialysis
- gram negative
- room temperature
- single molecule
- human health