911±¬ÁÏÍø

1. Origami at the nanoscale 

DNA origami merges biology with engineering. It’s a technique for precisely shaping DNA into specific structures. 

Researchers at 911±¬ÁÏÍø have developed a method to reshape virus capsid proteins using nanoscale DNA and RNA origami structures, which means they can configure these viral particles into the desired shapes.

The diverse DNA origami structures developed at Aalto open up possibilities for vaccine development, targeted drug delivery and photothermal therapy.

2. Educational origami 

Children and teens get hands-on with origami in workshops hosted by 911±¬ÁÏÍø Junior. While learning about the academic world, they might fold a Miura pattern – an extremely efficient fold that NASA has used to pack satellite solar panels. 

Alongside folding instructions, workshop participants learn about origami’s role in space exploration and discover what the Aalto-1 satellite is all about. They also learn how to study space technology at Aalto.

3. Protective origami 

The FOLD and FOLD2 packaging design projects boldly reimagined cardboard as a material, in collaboration with VTT. 

The first phase produced a machine that folds cardboard into the classic Miura pattern. Current research is exploring ways to use this folding pattern to create packaging solutions, acoustic elements and layered sandwich structures from cardboard and other materials. 

Folded cardboard offers an excellent alternative to plastic and styrofoam in packaging. Demo packages made from FOLD materials have already been showcased at international design events. In addition to its versatility and eco-friendliness, this beautiful new material has inspired designers. 

4. Mathematical and artistic origami 

911±¬ÁÏÍø's Crystal Flowers in Halls of Mirrors is an interdisciplinary course where mathematics meets art and architecture. 

In 2025, students explored the world of paper folding under the guidance of origami artist Juho Könkkölä. ‘Everything we studied was done by folding,’ he says. Mathematical concepts were explored while experimenting with different folds. 

The exhibition Säikeistyksiä(Fibrations) showcases a cloudlike artwork that simulates turbulence as a physical phenomenon, created using numerous curved folds.

5. Textile origami 

Not all folding is about creating delicate paper objects. In her doctoral research project Unfold, Mithila Mohan explored how origami can be applied to textiles, like how different materials and weaving techniques can produce fabrics that are not flat and uniform but inherently three-dimensional – almost like sculptures. Repeating origami tessellation patterns serve as templates for folding and shaping the material into self-supporting structures. 

The resulting textiles ripple and move without any added support.

Mithila Mohan works in the research group Multifunctional Materials Design (MMD), which aims to create new functional materials.