Who lives in the treetops? DNA-collecting drone provides insights

"If we want people to protect nature, we need to tell them what we are actually protecting -- with our solution, we hope to better understand the life in the canopy," says the study's lead author, Steffen Kirchgeorg.

Drones go where people can't or shouldn't go, including remote, protected or inaccessible locations. So, researchers have started to use aerial robots to take pictures, deploy sensors and collect samples in the forest canopy. To identify the species living in and around trees, samples are taken of genetic material left on leaves and branches. This environmental DNA (eDNA) comes from mucus, feces and dead skin cells. However, if a drone outfitted with swabs to gently collect eDNA accidentally collides with a tree, both the robot and plant can be damaged. So, Kirchgeorg, Stefano Mintchev and colleagues wanted to design a sampling system that keeps the drone out of the vegetation.

They developed a drone sampling system with a specialized fabric probe that brushes against branches and leaves to collect eDNA. When a remote pilot activates a pully underneath the drone, a tether lowers and raises the probe through the canopy. The system includes a piece of fleece cloth cut into a circle, similar in shape to a coffee filter, with strips of fiberglass attached to provide structure. In addition, a sensor keeps the probe's tether from tangling on branches: If it detects an impact, the researchers programmed the system to automatically shift position before completing the drop or retrieval.

In proof-of-concept demonstrations, the researchers flew their drone into a rainforest in Southeast Asia, sending it beyond their line of sight to retrieve genetic material from trees 10 different times. When the drone returned from the flights, the researchers removed the fabric and extracted eDNA from each probe before bringing the samples to a lab for analysis and species identification. Across the 10 separate samples, most of the organisms detected were arachnids and insects. Additional species of note, according to the researchers, include the long-tailed macaque (monkey), multiple ant and termite species, and a type of fly called the gall midge. The study presents another way to study biodiversity in remote habitats, which the researchers say is critical for conservation and restoration initiatives.

The authors acknowledge funding from the Swiss National Science Foundation through an Eccellenza Grant and a Bridge Discovery Grant, the European Research Council through the European Union's Horizon 2020 research and innovation program, Rütli-Stiftung, the ETH Foundation, the XPRIZE Foundation, and the Alana Foundation.