麻豆影视

The soft, pink blob stares at the camera with glassy eyes 鈥� before pulling its face into a dimpled smile.

While it might look like the stuff of nightmares, this tiny robot covered in living skin could mark a step forward in the quest to make robots more human-like. It鈥檚 the work of researchers in Japan, who say they have discovered a new way to bind living skin tissue to a mechanical robotic surface.

The team was led by Professor Shoji Takeuchi, of the Institute of Industrial Science at the University of Tokyo. Previously, he developed a 鈥渓iving鈥� robot skin 鈥� using collagen, a fibrous protein in human skin, and human dermal fibroblasts, the main cell type in connective tissue 鈥� that could be applied to a robotic finger and bend without breaking.

• The information you need to know, sent directly to you: Download the 麻豆影视 App

For its new technique, the team was inspired by the natural structure of human skin ligaments to create 鈥渁nchors鈥� using a collagen gel applied to small, V-shaped holes on the robot鈥檚 surface. The new method provides 鈥渁 more seamless and durable attachment,鈥� says Takeuchi.

For its new technique, the team was inspired by the natural structure of human skin ligaments to create 鈥渁nchors鈥� using a collagen gel applied to small, V-shaped holes on the robot鈥檚 surface. The new method provides 鈥渁 more seamless and durable attachment,鈥� says Takeuchi.

Takeuchi isn鈥檛 alone in his efforts to make robots more human-like.

Ameca, often called the world鈥檚 鈥渕ost advanced humanoid robot,鈥� employs artificial intelligence to talk with people and react appropriately to their responses. One of the things that makes her appear more realistic than other robots is her eyes, says Will Jackson, the founder and CEO of Engineered Arts Ltd (the company behind Ameca).

鈥淓yes are the windows to the soul. We read each other鈥檚 emotions by eye contact,鈥� Jackson told CNN earlier this year, adding that with a 鈥渇inite amount of motion鈥� available in the robot鈥檚 head, eyes provide 鈥渢he most expressive capability.鈥�

Unlike the 3.5 million industrial robots already working behind the scenes in sectors such as automotive manufacturing and electronics, humanoids like Ameca, or Hanson Robotics鈥� Sophia and Grace, are destined for people-facing roles such as hospitality, health care, or education. Currently, they don鈥檛 have a huge range of motion for their facial expressions, creating an 鈥渦ncanny valley鈥� effect 鈥� a phenomenon that can make people uncomfortable with things that are trying to be human-like, but miss the mark.

鈥淩ealistic facial expressions enhance the robot鈥檚 ability to communicate and interact with humans more naturally and effectively,鈥� says Takeuchi. 鈥淭his is particularly important in applications such as healthcare, where empathy and emotional connection can significantly impact patient care.鈥�

Building robots that can feel

The research, details of which were published in the journal Cell Reports Physical Science this month, is an exciting development for the robotics field, says Yifan Wang, an assistant professor at the school of mechanical and aerospace engineering at Nanyang Technological University, Singapore. Wang鈥檚 work focuses on 鈥渟oft robots鈥� that mimic biological creatures.

Skin, the largest organ of the human body, is vital for sensory perception, feeling temperature, humidity, and the textures of objects, says Wang. 鈥淭his kind of feature in biological systems is currently, with artificial robots, still very difficult to achieve,鈥� he adds.

But the research at the University of Tokyo enables a 鈥渉ybrid solution鈥� between the soft and traditional robotics fields that is 鈥渧ery interesting,鈥� says Wang. Robots are often covered in a material made to resemble flesh, such as silicone, which is attached via an adhesive or fastening 鈥� but this can lead to the skin falling off or breaking, says Wang.

The new method, on the other hand, offers a way of 鈥渁dhering the skin onto a rigid surface very nicely, so that it does not detach easily and forms a very good interface between the rigid and soft,鈥� he says.

For Wang, the most exciting implications of this research are around developments in the 鈥渟ensing capability of robots.鈥�

鈥淥ur human skin has these very delicate, high-density sensors on the surface, which currently you can still not quite achieve using some synthetic materials,鈥� says Wang. 鈥�(But) if we use biological skin on those traditional robots, we can achieve a similar type of sensing of different features.鈥�

Takeuchi and his team hope to add more sensory functions in the next research phase, 鈥渢o make the skin more responsive to environmental stimuli,鈥� he says.

However, ensuring the consistency and quality of the living skin might not be so easy, says Takeuchi.

That鈥檚 why another part of his research is exploring how to create a vascular system for the robotic skin 鈥� the network of vessels and veins that carry blood and lymphatic fluids all over the body 鈥� that can provide the necessary nutrient supply to maintain the skin鈥檚 health over time. This would give the skin more moisture, 鈥渆nhancing its durability and longevity,鈥� says Takeuchi.

Something like this would 鈥渘eed a lot of work in terms of engineering鈥� says Wang 鈥� but if they pull it off, it would give humanoids the ability to look and feel like people in the future.