Biobattery-embedded tattoos to use sweat to power your tech

Scientists have developed a temporary tattoo with a built-in, sweat-powered biobattery that could one day be used to charge your phone while you are out for a run.

The biobattery works using lactate, a key chemical found in sweat that can be used to monitor exercise performance.

This means that the more the wearer sweats, the more energy is going to be produced, creating the interesting scenario where less physically fit people are able to produce more power.

The technology is one of the first examples of skin-based power sources, and could pave the way for a host of technologies powered by devices attached to the skin.

biobattery-tattoo

The biobattery works by using an enzyme to extract the electrons in the sweat’s lactate and move them to the battery. At present, the amount of energy produced is very small, but the researchers are confident that they will be able to develop this to enable small electronic devices to be charged.

“The current produced is not that high, but we are working on enhancing it so that eventually we could power some small electronic devices,” said Dr Wenzhao Jia, a postdoctoral researcher at the University of California San Diego.

“Right now, we can get a maximum of 70 microWatts per cm², but our electrodes are only 2 by 3 millimeters in size and generate about 4 microWatts — a bit small to generate enough power to run a watch, for example, which requires at least 10 microWatts.

“So besides working to get higher power, we also need to leverage electronics to store the generated current and make it sufficient for these requirements.”

The device has also been developed as a lactate monitor, which will be a valuable tool for both doctors and athletes. Previously lactate has been monitored using a series of blood tests, so this monitor is likely to prove simpler and less invasive.

The biobattery’s reliance on sweat means that the amount of power produced can vary significantly depending on the person wearing it.

The researchers tested the initial biobattery on 15 exercise bike-riding volunteers, and found that not only did those who were least fit produce the most energy, but the most regularly active participants produced the least energy.

This could affect the potential success of the technology, as such variation in performance could make it difficult to market.

However, this is one of the first examples of skin-based batteries, and the technology is likely to be developed much further.

“These represent the first examples of epidermal electrochemical biosensing and biofuel cells that could potentially be used for a wide range of future applications,” said Dr Joseph Wang, professor of nanoengineering at University of California San Diego.

From here we could see the development of an array of wearable technologies and gadgets siphoning power through our skin, perhaps even one day powering whole computers, medical augmentations and more.


Inline image courtesy of Dr Joseph Wang.


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Stronger in old age: Stem cell research paves way for muscle-building medication

It could in the future be possible to take medication that will allow you to build muscle, even when you are in old age.

This is due to the findings of research at the Karolinska Institutet in Sweden, which found that large, and wholly unexpected, amounts of mutations in muscle stem cells blocks their ability to regenerate cells.

“What is most surprising is the high number of mutations. We have seen how a healthy 70-year-old has accumulated more than 1,000 mutations in each stem cell in the muscle, and that these mutations are not random but there are certain regions that are better protected,” said Maria Eriksson, professor at the Department of Biosciences and Nutrition at Karolinska Institutet.

With this knowledge, researchers could develop therapies that would encourage such regeneration, and so allow older people to rebuild lost muscle.

“We can demonstrate that this protection diminishes the older you become, indicating an impairment in the cell’s capacity to repair their DNA. And this is something we should be able to influence with new drugs,” explained Eriksson.

The landmark research, which is published today in the journal Nature Communications, involved the use of single stem cells, which were cultivated to provide enough DNA for whole genome sequencing – a medical first for this part of the body.

“We achieved this in the skeletal muscle tissue, which is absolutely unique. We have also found that there is very little overlap of mutations, despite the cells being located close to each other, representing an extremely complex mutational burden,” said study first author Irene Franco, a postdoc in Eriksson’s research group.

While a significant step, the research is now being expanded to look at whether exercise affects the number of mutations – a potentially vital factor in understand why and how these mutations occur.

“We aim to discover whether it is possible to individually influence the burden of mutations. Our results may be beneficial for the development of exercise programmes, particularly those designed for an ageing population,” said Eriksson.

The research is one of a host of projects being conducted across the world that have potential impacts on ageing, an area that was long ignored by much of the scientific community, but is now garnering increased support.

If many – or even a fair minority – of these findings eventually become the basis of therapeutics, it could be transformative for old age in the future, allowing people to remain healthier for far later in life and potentially even leading to longer life expectancies.