Movement through tree tops in tropical forests can be particularly dangerous for large animals like orangutans where a fall of up to 30m could be fatal. Scientists found that dangerous tree vibrations can be countered by the orangutan's ability to move with an irregular rhythm.
Professor Robin Crompton, from the University of Liverpool's School of Biomedical Sciences, explained that these challenges were similar to the difficulties engineers encountered with London's 'wobbly' Millennium Bridge: "The problems with the Millennium Bridge were caused by large numbers of people walking in sync with the slight sideways motion of the bridge. This regular pattern of movement made the swaying motion of the bridge even worse. We see a similar problem in the movement of animals through the canopy of tropical forests, where there are highly flexible branches.
"Most animals, such as the chimpanzee, respond to these challenges by flexing their limbs to bring their body closer to the branch. Orangutans, however, are the largest arboreal mammal and so they are likely to face more severe difficulties due to weight. If they move in a regular fashion, like their smaller relatives, we get a 'wobbly bridge' situation, whereby the movement of the branches increases."
Dr Susannah Thorpe, from the University of Birmingham's School of Biosciences, added: "Orangutans have developed a unique way of coping with these problems; they move in an irregular way which includes upright walking, four-limbed suspension from branches and tree-swaying, whereby they move branches backwards and forwards, with increasing magnitude, until they are able to cross large gaps between trees."
The team studied orangutans in Sumatra, where the animal is predicted to be the first great ape to become extinct. This new research could further understanding into the way orangutans use their habitat, which could support new conservation programs.
Dr Thorpe continued: "If the destruction of forest land does not slow down, the Sumatran orangutan could be extinct within the next decade. Now that we know more about how they move through the trees and the unique way that they adapt to challenges in their environment we can better understand their needs."
The research is published in Proceedings of the National Academy of Sciences.
Source: University of Liverpool