They look like spirals with tiny heads, and screw through the liquid like miniature corkscrews. When moving, they resemble rather ungainly bacteria with long whip-like tails. They can only be observed under a microscope because, at a total length of 25 to 60 µm, they are almost as small as natural flagellated bacteria. Most are between 5 and 15 µm long, a few are more than 20 µm.
The tiny spiral-shaped, nature-mimicking lookalikes of E. coli and similar bacteria. are called “Artificial Bacterial Flagella” (ABFs), the “flagella” referring to their whip-like tails. They were invented, manufactured and enabled to swim in a controllable way by researchers in the group led by Bradley Nelson, Professor at the Institute of Robotics and Intelligent Systems at ETH Zurich. In contrast to their natural role model, some of which cause diseases, the ABFs are intended to help cure diseases in the future.
The practical realization of these artificial bacteria, the smallest yet created, with a rigid flagellum and external actuation, was made possible mainly by the self-scrolling technique from which the spiral-shaped ABFs are constructed. ABFs are fabricated by vapor-depositing several ultra-thin layers of the elements indium, gallium, arsenic and chromium onto a substrate in a particular sequence. They are then patterned from it by means of lithography and etching. This forms super-thin, very long narrow ribbons that curl themselves into a spiral shape as soon as they are detached from the substrate, because of the unequal molecular lattice structures of the various layers. Depending on the deposited layer thickness and composition, a spiral is formed with different sizes which can be precisely defined by the researchers. Nelson says, “We can specify not only how small the spiral is, but even the scrolling direction of the ribbon that forms the spiral .”
Even before releasing the ribbon that will afterwards form the artificial flagellum, a kind of head for the mini-robot is attached to one of its ends. It consists of a chromium-nickel-gold tri-layer film, also vapor-deposited. Nickel is soft-magnetic, in contrast to the other materials used, which are non-magnetic. Nelson explains that, “This tiny magnetic head enables the ABF to move in a specific way in a magnetic field.” The spiral-shaped ABF swim through the liquid and its movements can be observed and recorded under a microscope.
The ABFs have been designed for biomedical applications. For example, they could carry medicines to predetermined targets in the body, remove plaque deposits in the arteries or help biologists to modify cellular structures that are too small for direct manipulation by researchers. In initial experiments, the ETH Zurich researchers have already made the ABFs carry around polystyrene micro-spheres.