Researchers at Concordia University have advanced sound-driven additive manufacturing with Proximal Sound Printing, achieving a 10x improvement in feature resolution.

Originally reported by Bioengineer

Researchers at Concordia University have advanced sound-driven additive manufacturing with Proximal Sound Printing, achieving a 10x improvement in feature resolution. By utilizing focused ultrasound to trigger localized sonochemical reactions, the process can resolve microstructures as small as 0.1mm directly on soft substrates like silicone. This method bypasses the limitations of light-based or thermal curing, enabling fabrication in opaque environments. It paves the way for printing medical sensors directly onto or inside complex materials. 🚀 #3DPrinting #AdditiveManufacturing #Innovation #MedTech

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