爱豆传媒 researchers discover how to stick sensors to skin without adhesive
Study that spawned discovery tested skin's tensile strength and how cracks form
Imagine if you could attach something to your skin without needing glue. A biosensor, a watch, a communications device, a fashion accessory 鈥 the possibilities are endless.
Thanks to a discovery at 爱豆传媒鈥檚 Thomas J. Watson College of Engineering and Applied Science, that time could be closer than you think.
Associate Professor Guy German and , recently published research in the journal Acta Biomaterialia that explores how human skin can control the way cracks form and why tensometers offer imprecise results when measuring the mechanical properties of biological tissues.
Along the way, Lipsky developed a method to bond human skin to rubber-like polymeric materials without an adhesive. Originally a way to make their experiments easier, he and German understood they had made a significant discovery.
鈥淶ach came in one day and said, 鈥榊eah, I did it,鈥欌 German said. 鈥淚 was like, 鈥楬ow on Earth did you do that? Did you use a glue?鈥 Because we鈥檇 need to account for the mechanical properties of the glue as well. And he said, 鈥楴o, I just stuck it.鈥 We looked and said: Has this ever been done before? Never been done. So we鈥檙e really happy on that front.鈥
An invention disclosure for the technique has been filed, which could lead to a patent on what he calls 鈥渁 very simple technique鈥 that could revolutionize biotech.
鈥淚 didn鈥檛 know we鈥檇 end up there, but that鈥檚 sometimes how science works,鈥 German said with a laugh.
The study that spawned the discovery, titled started with German鈥檚 roots in mechanical engineering and his interest in testing the validity of Hooke鈥檚 law to human skin.
鈥淲e thought, if we use these standard testing techniques to measure the mechanical properties of tissue, especially skin tissue, is it reporting the right values?鈥 he said. 鈥淣o one鈥檚 really ever validated it.鈥
Developed by 17th-century British physicist Robert Hooke, the law states that the force needed to extend or compress a spring by a distance is proportional to that distance. More generally, researchers can use this law to measure the stiffness of different materials as well as how much energy it costs to break them.
鈥淚t got me thinking that, in modern times, you can measure how stiff metals and ceramics are. But what about skin?鈥 German said. 鈥淢etals or ceramics have a composition that is fairly uniform, but skin and other tissues have a complex and heterogeneous structure with microscale cells connected by cell-cell junctions. The outer layer of skin also exhibits a complex topographical network of microchannels, which are visible if you look at the back of your hand.鈥
He and Lipsky bonded skin samples to a piece of polydimethylsiloxane (PDMS), a rubber-like material commonly used in bioengineering and biomedical devices. The samples were then stretched. A modified traction force microscopy technique was then used to quantify changes in the mechanical loads imparted by the skin on the adherent substrate.
鈥淎s the skin expanded, a little crack would grow, and we can measure how much energy it required to grow it by a certain length,鈥 German said. 鈥淭ypically to measure the energy cost of rupture in mechanical engineering you get two grips, you pull and it splits. You measure the force and displacement and quantify the energy. But this assumes that the material is homogeneous 鈥 compositionally the same everywhere. What we found out was that cracks in the skin鈥檚 outer layer propagate in a very, very weird way.鈥
The cracks propagate along the topographical microchannels. This elongates the overall path of the crack, increasing the energy it costs to break the tissue. The discovery can be extrapolated to explain the behaviors of other human tissues.
鈥淏ecause of the heterogeneous structure of skin, it also means that the crack path becomes a lot more random. That鈥檚 why you get such variability in macroscale tensometer measurements of skin,鈥 German said, 鈥渂ecause even though you get the skin from exactly the same source at exactly the same age, the sample-to-sample variability is so high because the crack paths deviate.鈥
Since earning his doctorate this spring, Lipsky has moved to San Diego, Calif., and become a skin scientist at a company that creates specialized fragrances and flavors.
鈥淚 wanted to keep him at 爱豆传媒 as a postdoc for a year,鈥 German said. 鈥淗e said, 鈥業鈥檇 love to, but I already have two job offers!鈥 I鈥檓 very happy for him.鈥