Silicone 3D Printing Case Study: Flexible Lattice Structures for Biomedical Applications

Flexible lattice structures created with silicone 3D printing and water-soluble support materials enable complex geometries that are impossible to achieve with traditional molding techniques. This advanced approach is especially valuable in biomedical engineering, soft robotics, and product design, where high precision and material performance are essential.

Using two-part medical-grade silicone and a water-soluble support material, these structures are printed with excellent dimensional accuracy. After curing, the support material is removed with ease, revealing detailed and precise lattice geometries.

These printed silicone lattices offer more than just design freedom.

They're engineered for shock absorption, controlled rebound, and adjustable mechanical properties, such as tunable hardness and flexibility. This makes them ideal for applications requiring lightweight, high-performance components, such as wearable medical devices, custom cushioning systems, and bio-integrated structures.

Key Benefits of Silicone Lattice 3D Printing:

• Complex shapes are unachievable by molding

• Superior mechanical properties: flexibility, rebound, and shock absorption

• Lightweight yet durable structure

• Biocompatibility for use in medical and wearable tech

• Precision geometry with less than 1% shrinkage

  
  

Looking to innovate in bioengineering or product development? Silicone 3D printing may be the solution!