It may not be a living, breathing robot, but UK researchers have created something pretty close.

Robotics experts has developed a soft robot capable of consuming organic material for energy, effectively creating a machine which digests living things.

The hope is that such self-sustaining robo-scavengers could be used to mop up contaminated water or algal blooms, which choke out life.

A robot developed by British robotics engineers can sustain itself by consuming living matter from its environment (pictured). The soft robot is capable of consuming organic material for energy, effectively digesting living things

THE SOFT ROBOT THAT EATS LIVING MATTER Robotics engineers in Bristol have developed a soft robot with a 'mouth' and 'gut' capable of consuming organic material for energy. Using a soft polymer membrane as a 'mouth', it filters biomatter from water. Its 'gut' is a microbial fuel cell packed with bacteria which break down the ingested organic matter. This chemical energy is then transformed into electrical energy to keep the robot going. Energy gained from the process is currently limited, but the soft design of the machine has enabled the team to drastically cut the amount it requires. Advertisement

Developed by a team of engineers based in Bristol, the machine is able to gain the energy it needs to keep it 'alive' from its watery surrounding.

According to New Scientist, the design imitates basic marine creatures called salps, simple, transparent tube-like creatures which filter the water for living scraps.

Using a soft polymer membrane as a 'mouth', the machine filters its aquatic surroundings – a water bath with added biomatter – to gain the energy it needs.

But unlike the stomach or digestive tract of living organisms, the mechanical imitator relies on a microbial fuel cell packed with bacteria which break down organic matter.

These microbes break liberate the chemical energy stored in the biomatter, which is transformed into electrical energy which the robot can use.

The clever design imitates the symbiotic relationships which have helped living things to dominate the planet over billions of years.

Once the matter is used up, it is excreted out the other end and the robot moves on.

New Scientist's Timothy Revell reports that the energy gained from the process is currently limited, but the soft design of the machine has enabled the team to drastically cut the amount of energy it requires.

The hope is that such self-sustaining robo-scavengers could be used to mop up contaminated water or algal blooms (pictured), which choke out life

What's more, the team was able to link multiple fuel cells in series to boost the energy output.

Getting the balance right means such soft robots can eke out a living with relatively little 'food', so could be pretty much self-sustaining.

Professor Ioannis Ieropoulos, who is leading the project at the Bristol Robotics Laboratory, told MailOnline the team hopes to trial the robots within the next two years.

He told MailOnline: 'By deploying these robots in remote environments and building-in telemetry, we can also be collecting valuable information from that environment, such as temperature, pH, relative humidity, pollutants concentration, depending on the sensor technology that may be incorporated.

He added: 'Longer term, these would be the agents that could hopefully be deployed in search & rescue missions, where energy management - such as battery recharging or replacement - is extremely challenging.'

The octobot is an entirely soft, autonomous robot. A pneumatic network, pink, is embedded within the octobot's body and hyperelastic actuator arms, light blue. It's squishy like Silly Putty, wireless, battery-less and made for pennies by a 3-D printer

Earlier this year, researchers in the US created a 3D-printed octopus robot called the Octobot.

It looks like a tiny octopus and is designed to mimic that slithery creature to get through cracks and tight places, making it ideal as a rescue robot.

A team at Harvard University created the robot — actually about 300 of them, since they are so cheap to make.

The idea is to make this something that is powered by a chemical reaction in fluids; fluid movement moves the arms and directs the robot's actions.