 So we're here with the Feel It. So who are you? So we are a startup company, a body startup from the Technion in Israel. Can we check this out? So you are doing skin-inspired, flexible sensors, electronic skin. So basically the most sensitive part of our human body is the fingertips. We can sense a milligram in terms of flow resolution, and we can sense two points that are one millimeter apart from one another. And we take these features and integrate this in the flexible sensors. So we have the patent technology that enables us to measure, touch on its location in a human-like resolution. And we use this... This is your sensor there? Yeah, this is the active layer. It's based on a wall nanoparticle ink that we print. We can print it on a different substrate. And we use, instead of 100 pixels that you normally might use, we use only 10. Only 10? 10 for this kind of resolution. That's our patent technology. And that enables us to have low power consumption and low transfer data. And this is good for wearable and mobile applications. So when you touch here, the sensor, can you show again? Yeah, so you see that you're changing the resistance, the electrical resistance. And that's based on just what you touch or the whole, where's the measuring? So this is only the sensor. This whole part are wires. Are they also active, the other ones? Not connected, but I can show you. So an additional application is for surgical tools. Okay. For minimum invasive surgery, a surgeon currently use a camera and some surgical tools, but they don't have the hands to feel like normal tissue versus cancer tissue, for example. And that's an issue. We've talked to several doctors and we wish to embed this sensor inside the surgical tools. So when you clap, you can see the change in the response and that could be monitored. You can monitor perforation, for example. You can have the textures of tissue and you can see this on a computer screen. This could be embedded as actuators on the doctor's hand, for example. So that's another physical application. An additional interesting application here is for movement monitoring. Movement? Movement, where we have the sensors embedded inside of a sleeve. And the sensors are placed over here. So when they bend, when you bend your hand, you can see very nicely the response. That's awesome. Yeah, and that's for example where you want to monitor the improvement of movement and also for virtual reality gaming and for sports, for athletes. So what else are you talking about here? You have a paper here. Where have you been showing this technology and what's going on with our solution? Is it coming to market? So currently we are focusing on initial health monitoring patch application where we want to provide the whole solution, the end product and based on this initial product line we'll be happy to get feedback and improve the technology and then have a kit that could be supplied to different companies costumed to their needs. Alright, cool. So how do you make this? What is, it's flexible, how do you make it? So we use a commercial polyamide substrate. We print on it the conductive with a commercial silver inks and we produce the gold nanoparticle ink which is the active layer which we print. So you saw that stuff. Cool, alright. What do you think about ID Tech X? It's great. It's a good opportunity to meet as many potential collaborations. It's going to be huge in the future. Printed electronics, flexible sensors and that's what you're doing there. That's great. Thank you.