Examples of metamaterial blocks with different unit cells that are studied in the paper. These blocks were additively manufactured from a polymer-based material using a hobby-type 3D printer, Bambu Lab X1 Carbon, in the Metamechanics Lab, University of Groningen. Credit: Shantanu Nath, University of Groningen

Metamaterials are composites with a very precisely controlled structure. It is this structure that determines the properties of the metamaterial, not the substances it is made of. Typically, a metamaterial consists of repeating identical blocks called unit cells. New research by Ph.D. student Shyam Veluvali, Prof. Anastasiia Krushynska, and colleagues from the University of Groningen, UMCG, and Karlstad University in Sweden show that the overall mechanical response of metamaterials depends on how many unit cells are joined together, and how they are arranged.

In their paper in the journal Small Structures, Veluvali and colleagues show how the size of the building blocks affects the simplest behavior, such as elasticity. They also show that the number of blocks can affect the metamaterial properties. Furthermore, the more blocks are added, the easier it becomes to predict the structural behavior of a metamaterial. These insights help to predict the mechanics of metamaterials, such as bone implants, with higher precision.

A metamaterial alternative

Currently, bone implants are made of a titanium alloy, which is much stiffer than the bone itself and, therefore, takes most of the load from chewing or talking. The stiff titanium reduces the load on the remaining bone and, as the bone adapts to this load, weakens it. "We propose to replace traditional implants with a metamaterial alternative," says Veluvali. By adapting the material’s structure, it is possible to match the stiffness of the implant to that of the bone. In that case, the bone and the implant share the load and, consequently, the bone remains strong.

• This is a Graphical abstract of the paper. Credit: Small Structures / Shyam Veluvali & Anastasiia Krushynska, University of Groningen
• The metamaterial blocks were used to test the stiffness of blocks with identical external/overall dimensions and mass, but with different numbers of unit cells. The experiments show that the number of unit cells is a crucial parameter influencing the stiffness under compression (left) and torsion (right). The samples were tested under compression in the Metamechanics Lab at the University of Groningen Physics department, using Instron universal testing machines and under torsion at Instron’s Applications Laboratory in Boston, U.S. Credit: Small Structures / Sidharth Beniwal (left) and Walter Conway, University of Groningen

The paper also shows that it matters what type of force is acting on the metamaterial. Veluvali says, "We found that different kinds of forces, such as shear, stretching, or torsion, can have different effects on the same material." This was not yet known, as prior studies focused on just a single force.

All these results are useful for the design of different types of implants (e.g. orthopedic or spinal), and also of applications such as the grippers of robotic hands or energy absorbers such as car bumpers. "Our insights help to design safer, longer-lasting structures for various applications by choosing the right block size and arrangement."

More information: H. C. V. M. Shyam Veluvali et al, When Scale Matters: Size‐Dependent Mechanics of Architected Lattices for Implants and Beyond, Small Structures (2026). DOI: 10.1002/sstr.202500434

Citation: Metamaterial insights point to better implants, robot hands and bumpers (2026, February 3) retrieved 3 February 2026 from https://techxplore.com/news/2026-02-metamaterial-insights-implants-robot-bumpers.html

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