Pop culture has often depicted robots as cold, metallic, and menacing, built for domination, not compassion. But at 色花堂, the future of robotics is softer, smarter, and designed to help.
鈥淲hen people think of robots, they usually imagine something like The Terminator or RoboCop: big, rigid, and made of metal,鈥 said , the G.P. 鈥淏ud鈥 Peterson and Valerie H. Peterson Professor in the . 鈥淏ut what we鈥檙e developing is the opposite. These artificial muscles are soft, flexible, and responsive 鈥 more like human tissue than machine.鈥
Yeo鈥檚 latest study, published in , explores AI-powered muscles made from lifelike materials paired with intelligent control systems. The technology learns from the body and adapts in real time, creating motion that feels natural, responsive, and safe enough to support recovery.
Muscles That Think, Materials That Feel
Traditional robotics relies on steel, wires, and motors, but rarely captures the nuances of human motion. Yeo鈥檚 research takes a different approach. He uses hierarchically structured fibers, which are flexible materials built in layers, much like muscle and tendon. They can sense, adapt, and even 鈥渞emember鈥 how they鈥檝e moved before.
Yeo trains machine learning algorithms to adjust those pliable materials in real time with the right amount of force or flexibility for each task.
鈥淭hese muscles don鈥檛 only respond to commands,鈥 Yeo said. 鈥淭hey learn from experience. They can adapt and self-correct, which makes motion smoother and more natural.鈥
The result of that research is deeply human. For someone recovering from a stroke or limb loss, each deliberate movement rebuilds not just strength 鈥 it rebuilds confidence, independence, and a sense of self.
A Glove That Gives Freedom Back
One of the first real-world applications is a prosthetic glove powered by artificial muscles (), a device that behaves more like a helping hand than a mechanical tool. Traditional prosthetics rely on rigid motors and preset motions, but Yeo鈥檚 design mirrors the natural give-and-take of real muscle.
Inside the glove, thin layers of stretchable fibers and sensors contract, twist, and flex in sync with the wearer鈥檚 intent. The glove can fine-tune grip strength, reduce tremors, and respond instantly to the user鈥檚 movements, bringing dexterity back to everyday life.
That kind of precision matters most in the smallest tasks: fastening a button, lifting a glass, holding a child鈥檚 hand.
鈥淭hese aren鈥檛 just movements,鈥 Yeo said. 鈥淭hey鈥檙e freedoms.鈥
For Yeo, the idea of restoring freedom through movement has driven his research from the very beginning.
A Mission Rooted in Loss
His path to biomedical engineering began with loss 鈥 the sudden death of his father while Yeo was still in college. That moment reshaped his sense of purpose, redirecting his focus from machines that move to technologies that heal.
鈥淚nitially, I was thinking about designing cars,鈥 he said. 鈥淏ut after my father鈥檚 death, I kind of woke up. Maybe I could do something that helps save someone鈥檚 life.鈥
That purpose continues to guide , building technologies that help people recover what they鈥檝e lost.
Achieving that vision, however, means tackling some of engineering鈥檚 toughest challenges.
Soft Machines, Hard Problems
Creating lifelike muscles isn鈥檛 easy. They need to be soft but strong, responsive but safe. And they must avoid triggering the body鈥檚 immune system. That means building materials that can survive inside the body 鈥 and learn to belong there.
鈥淲e always think about not only function, but adaptability,鈥 Yeo said. 鈥淚f it鈥檚 going to be part of someone鈥檚 body, it has to work with them, not against them.鈥
His team calibrates these synthetic fibers like precision instruments 鈥 tested, adjusted, and re-tuned until they operate in sync with the body鈥檚 natural movements. Over time, they develop a kind of 鈥渕uscle memory,鈥 adapting fluidly to changing conditions. That dynamic adaptability, Yeo explained, is what separates a machine from a prosthetic that truly feels alive.
From Collaboration to Innovation
Solving problems this complex requires more than one discipline. It takes an entire ecosystem of collaboration. Yeo鈥檚 lab brings together experts in mechanical engineering, materials science, medicine, and computer science to design smarter, safer devices.
鈥淵ou can鈥檛 solve this kind of problem in isolation,鈥 he said. 鈥淲e need all of it 鈥 polymers, artificial intelligence, biomechanics 鈥 working together.鈥
That collaborative model is supported by the National Science Foundation (NSF), the , and 色花堂鈥檚 In 2023, Yeo received a to train the next generation of engineers building smart medical technology.
His team now works closely with healthcare providers and industry partners to bring these devices out of the lab and into patients鈥 lives.
The Future You Can Feel
The future of robotics, according to Yeo, won鈥檛 be defined by power or complexity but by feel.
鈥淚f it feels foreign, people won鈥檛 use it,鈥 he said. 鈥淏ut if it feels like part of you, that鈥檚 when it can truly change lives.鈥
It鈥檚 the opposite of The Terminator, where machines replace us. Yeo is designing these machines to help us reclaim ourselves.
