The electronic skin revolution: a new sense of touch | Giulia Spallanzani | TEDxForteDeiMarmi | Summary and Q&A

TL;DR

Scientists are developing electronic devices that can mimic the sense of touch, with the goal of creating artificial skin for prosthetics, remote health monitoring, and virtual reality applications.

Key Insights

• 🧠 Skin has the remarkable ability to sense and transmit information about the external environment to the brain.
• 💦 Researchers are working on developing electronic skins that can mimic the sense of touch and be used in various applications.
• 🤘 Wearable patches and sensors can monitor vital signs and reduce the burden on healthcare systems.
• 👣 Smart materials integrated with printed electronics can create sensors that respond to stimuli and have applications in robotics and prosthetics.

Transcript

Transcriber: Roqia Tobar Reviewer: Emma Gon As a scientist, what I do and I like are experiments. So let's start with an experiment today. Every one of you, please take a finger from your favorite hand and place it on the palm of your other hand in the way you like. Now experience. You probably feel a little warm, maybe sweaty. Maybe your nail is... Read More

Questions & Answers

Q: How does the skin gather information from the environment?

Skin contains thousands of tiny receptors that collect stimuli from the outside world and transmit electronic signals to the brain through the nervous system.

Q: What is the density of receptors in different parts of the body?

Receptors are more densely packed in areas like fingertips, with up to several hundreds of receptors per square centimeter.

Q: How are wearable patches and sensors used in healthcare?

Wearable patches can monitor vital signs, early detect diseases, and reduce hospitalization time. They can also allow remote monitoring of patients by doctors.

Q: What are smart materials and how are they used in electronic skin?

Smart materials respond to changes in the surrounding environment and can perform actions. They are integrated with printed electronics to create sensors that can measure deformation or respond to stimuli like temperature or light exposure.

Summary

In this video, the speaker talks about the fascinating capabilities of our skin and how researchers are working on developing a device that can mimic the sense of touch. They discuss the use of wearable devices and patches that can gather information from the environment and our bodies, and the integration of sensors in these devices. The speaker also introduces the concept of electronic skins or e-skins and their potential applications in fields such as healthcare, virtual reality, and haptics. Overall, electronic skins have the potential to revolutionize our interaction with technology and enhance our understanding and communication with the world around us.

Questions & Answers

Q: How does our skin gather information from the surrounding environment?

Our skin is equipped with thousands of tiny structures called receptors that are spread all over our body. These receptors can sense various stimuli such as temperature, textures, and pressure. They gather this information and translate it into electronic signals that are then sent to the brain via the nervous system.

Q: What is the density of receptors in different parts of our body?

The density of receptors varies widely throughout the body. For example, in fingertips, we can have hundreds of receptors per square centimeter. To put it into perspective, the surface area of a one Euro coin on our fingertip will have more than a thousand of these receptors. This high density allows for a more precise sense of touch in certain areas.

Q: How often do receptors gather and send information to the brain?

Regardless of whether the brain utilizes the information or not, the receptors gather and send information to the brain at a remarkable rate. They collect data 200 to a thousand times per second. For instance, a thermoreceptor in your hand would sense the temperature around it more than 30,000 times during the duration of the talk.

Q: What are some challenges in developing a device that can mimic our skin's sense of touch?

Creating a device that can replicate the complexity of natural skin is a highly complex task. Researchers are tackling this challenge step by step, starting with wearable devices and patches. These devices integrate electronic sensors, which serve as the electronic counterpart of the receptors. By using printed electronics, these sensors can be printed on flexible surfaces. However, further advancements are needed to create a fully functional artificial skin.

Q: What are the potential applications of electronic skins?

Electronic skins have a wide range of applications. In the biomedical field, they can be used in wearable devices to monitor vital signs and detect diseases. They can reduce hospitalization time by allowing remote monitoring of patients. They can also be used in virtual reality and haptics to create more intuitive and non-invasive human-machine interaction interfaces.

Q: How do printed electronics contribute to the development of electronic skins?

Printed electronics allow for the integration of sensors onto flexible and conformable surfaces. These sensors can gather information from the outside world and translate it into electronic signals. By combining printed electronics with smart materials, electronic skins can be created, providing a wide variety of functionalities.

Q: What are smart materials and how are they used in electronic skins?

Smart materials are materials that respond to changes in the surrounding environment and perform certain actions. For example, they can heal themselves or change shape depending on stimuli like temperature or light exposure. In electronic skins, smart materials can be used to create sensors that sense deformation or movement. These sensors can be mounted on prosthetics or robotic devices to provide feedback to the user.

Q: How can electronic skins enhance human-machine interaction?

Electronic skins can create more intuitive and non-invasive interfaces for human-machine interaction. By integrating smart materials and printed electronics, these skins can gather stimuli from the outside world, measure signals from the user, and also activate the natural skin receptors. This feedback loop between the device and the nervous system can significantly improve the interaction and the overall experience.

Q: What is the potential impact of electronic skins?

Electronic skins have the potential to revolutionize our interaction with technology and enhance our understanding and communication with the world around us. They can enable us to relive, transmit, and reimagine experiences. This technology can have applications in various fields, including healthcare, virtual reality, and communication.

Q: What are the envisioned future possibilities of electronic skins?

The speaker invites the audience to imagine a device that integrates smart materials and printed electronics, allowing us to feel stimuli from the environment, measure signals from our body, and trigger our natural skin receptors. This could enable us to experience sensations and communicate even while being miles away from the actual source of the stimuli. Electronic skins may pave the way for new possibilities in understanding and connecting with the people and the world around us.

Takeaways

The development of electronic skins holds great promise in transforming our interaction with technology. By mimicking the capabilities of our own skin, these devices can gather and interpret information from the surrounding environment and our own bodies. This opens up numerous possibilities in healthcare, virtual reality, and human-machine interactions. With further advancements in printed electronics and integration of smart materials, electronic skins may enable us to experience, understand, and communicate in ways we never thought possible before.

Summary & Key Takeaways

• Skin senses the surrounding environment and sends information to the brain, such as temperature, textures, and pressures.

• Researchers are working on developing devices that can mimic the sense of touch using wearable patches and sensors.

• These electronic skins have various applications in healthcare, prosthetics, virtual reality, and human-machine interaction.