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fruit fly eye

Scientists Replicate Self-Cleaning Coating of Insects' Eyes

The protective coating might find applications in diverse areas of economics including medicine, nanoelectronics, and the automotive and textile industries

Far Eastern Federal University

Scientists from Russia and Switzerland have probed into nanostructures covering the corneas of the eyes of small fruit flies. Investigating them the team learned how to produce the safe biodegradable nanocoating with antimicrobial, anti-reflective, and self-cleaning properties in a cost-effective and eco-friendly way. The protective coating might find applications in diverse areas of economics including medicine, nanoelectronics, and the automotive and textile industries. The article describing these discoveries appears in Nature.

Scientists from Far Eastern Federal University (FEFU, Russia) teamed up with colleagues from University of Geneva, the University of Lausanne, and Swiss Federal Institute of Technology in Zurich for an interdisciplinary research project during which they were able to artificially reproduce the nanocoating of the corneas of fruit flies (Drosophila flies) naturally designed to protect the eyes of the insects from the smallest dust particles and shut off the reflection of light.

The craft of nanocoating meets demands in various fields of economics. It can wrap up any flat or three-dimensional structure, and, depending on the task, give it anti-reflective, antibacterial, and hydrophobic properties, including self-cleaning. The latter, for example, is a very important feature for expensive reusable overnight ortho-k lenses that correct the eyesight. Similar anti-reflective coatings already exist, but are created by more complex and costly methods. They are being used on computer screens and glasses and paintings in museums can be covered with them in order to exclude reflection and refraction of light.

"We are able to produce the nanocoating in any required quantity given that its design is more cost-effective compared to the modern methods of manufacturing similar structures. The work with natural components requires no special equipment nor significant energy consumption and constraints of chemical etching, lithography, and laser printing," explains Vladimir Katanaev, the head of the research and head of the Laboratory of Pharmacology of Natural Compounds in the School of Biomedicine of FEFU. "The development has broad applications. For example, it could be the structural dying of textiles that would change the color depending on the angle of view. It is possible to create a disguise coat based on metamaterials, an antibacterial layer for medical implants, and a self-cleaning coating for contact lenses and windshields. We also believe that if we reinforce the nanocoating, it might be utilized as a basis of flexible miniature transistor prototypes designed for modern electronics."

Scientists managed to rebuild the corneal coating of small fruit flies via direct and reverse bioengineering methods. First, they took the protective layer apart into its constituent components, which turned out to be retinin (protein) and corneal wax (lipids) and then reassemblde it under room temperature conditions, covering glass and plastic surfaces.

Related Article: New Method Gives Microscope a Boost in Resolution

Step-wise increases in magnification are shown, from a macroscale image of a Drosophila head to an atomic force microscopy (AFM) image of a single nipple-type nanostructure coating an ommatidial lens.
Mikhail Kryuchkov, Department of Cell Physiology and Metabolism, Faculty of Medicine, University of Geneva, Geneva, Switzerland. Department of Pharmacology and Toxicology, University of Lausanne, Lausanne, Switzerland

According to Katanaev, any other types of materials can be nanocoated too. Combinations with different types of wax and genetic manipulations of the retinin protein allow the design of highly diverse and complex functional nanocoatings.

The scientist explains that the mechanism underlying the formation of the protective nanostructures on the corneas of Drosophila flies is a self-organizing process, described by Alan Turing back in 1952 as a reaction-diffusion mechanism. That is consistent with the mathematical modeling performed during the research. This mechanism is also responsible for the patterns forming, for example, on the fur of a zebra or a leopard. The nanostructures that protect the corneas of Drosophila eyes are the first established example of Turing patterns at the nanoscale.

In the course of the research project, scientists made a detailed characterization of the properties of retinin, as this protein has been studied little so far. It turned out that this initially unstructured protein forms a globular structure when interacting with corneal waxes. Thus, scientists took a look deep into the biophysical nature of the self-organization abiding to the Turing model, highlighting an important molecular process likely at the core of the self-organization—the initiation of the protein structuring.

At next stages, the research team aims at developing a model of three-dimensional nanostructuring (with nano-funnels, nanocolumns, nanorolls within the layer of the coating), also based on the Turing mechanism. This work would lie at the very frontier of modern scientific knowledge and can have promising fundamental and technological consequences.

Katanaev started studying the structure of the eye of Drosophila fly about 10 years ago. According to the scientist, the first data were obtained almost impromptu by means of atomic force microscopy. During collaboration with the laboratory of professor Igor Serdyuk from the Institute of Protein Research (Russian Academy of Sciences), it was discovered that the surface of the corneas of the flies was not smooth but was covered with beautiful patterns of pseudo-ordered nanoscale outgrowths. As it turned out, nanocoatings of this kind were described back in the late 1960s on the surface of the eyes of moths, larger insects to whom these structures also provide an anti-reflex function, reducing the reflection of incident light to zero and allowing the optimization of light perception in the darkness.