Transistors produced with Aerosol Jet Printing are overcoming the limits of printed electronics, opening new paths for flexible and low-cost devices. Thanks to a resolution of 10-50 micrometers and the use of printable materials, this technology allows for the realization of circuits on 3D substrates with good electrical reliability, suitable for sensors, wearable electronics, and circuits lo

3D printing in schools can be inclusive and scalable if well planned. Simple models, materials like PLA, and collaboration with teachers allow for optimizing production and educational impact, avoiding waste and overloads. Starting with pilot projects and scaling gradually is the key to success.

Bio-inspired soft sensors represent an engineering revolution: the material structure itself becomes the true sensor, generating electrical signals without electronic components. Thanks to porous and anisotropic microarchitectures, these smart materials convert mechanical stimuli into electrical responses by leveraging natural physical phenomena, such as streaming potential. Studies inspired by the spines

Upgrades for desktop 3D printers can improve quality and versatility, but they must be chosen carefully. Always verify mechanical, electrical, and firmware compatibility before purchase. Prioritize high-impact modifications like heated beds, hardened nozzles, and direct extruders, suitable for the materials you use. Start with simple upgrades like the PEI bed or filament sensors, then move on

Many additive startups fail because they focus on technology without building a sustainable business. A solid economic model, paying customers, and strategic patience are needed.

Additive Manufacturing (AM) succeeds in production only when applied to specific cases with high functional requirements, not to replace traditional methods, but to solve needs that these cannot satisfy. Success depends on consolidated designs, controlled materials, fixed parameters, and disciplined post-processing. Sectors such as aerospace, medical, and tooling exploit the

3D printing improves with two patented innovations: controlled vibrations and smart sensors for precise powder distribution. These systems reduce defects, waste, and post-production rework, increasing quality and repeatability without changing materials or machinery.

The Bambu Lab X2D introduces a dual nozzle system with mechanical switching to improve precision and support removal. One nozzle prints the model, the other handles supports with dedicated material, reducing post-processing and waste. The absence of additional motors on the head increases reliability and precision, with over a million change cycles tested. Main Extruder

Integrated metrology in 3D scanners enables real-time quality control, reducing time and costs. Thanks to advanced sensors, geometric algorithms, and connectivity, these systems process dimensional data directly during scanning, integrating with metrology platforms and production processes. Despite some technological limitations, they represent a breakthrough for high-

Technical polyamides offer excellent performance, but their printing complexity often makes them impractical. SP4 CF15 from 3DBooster was created to solve this paradox: 8.5 GPa rigidity, thermal resistance up to 180°C, and open-air printability without advanced setups.

3DSearch is a meta-engine that indexes millions of 3D models from various platforms, offering fast search and a modern interface. While scalable and comprehensive, it does not yet replace the integrated features and community of native platforms. Ideal for quick research, less suitable for professional workflows.

Creality develops a home recycling system for 3D filament, composed of a shredder and extruder, which turns print failures into new filament. The process includes shredding, drying, and re-extrusion, with acceptable tolerances for non-professional use. It supports various materials and allows for creative customizations, yet still requires manual intervention. A first step