 So I actually run a biohacking group in Singapore. So I'm going to be talking a little bit about democratizing biology and how we can make it more accessible to the public. So I'm going to use a software analogy and hardware. You know, when we were talking about hardware, we can open this experiment and we can look at it and start to know, or we can find things online. But for biology, it's a little bit more difficult. So mainly because your equipment, your chemical, the agents all realize themselves, and it's not accessible. So if I start to want to buy some, for example, code remakes or something, I can buy it online. I can buy it solutionally. And also, all you would call methodologies are proprietary. It's not so easy to find. Let's say you want to find a research paper that you understand and you want to actually find a paper. And you can actually buy it. You don't need this methodology. You have to do a brief description of how the experiment was done. So you can't really do anything with it. So I'm going to talk about, OK, so why do we want to make it more accessible? Well, one is outreach. So we can inspire future generations to become scientists, et cetera. We want people that have instruments in their minds. So one thing I really think about is folding, which is the game that we just put in folding. So actually, time has been working for the other strategy model to come to think it's working. And I think it worked. So we developed it into a game, and then we lived what people tried out. And within two weeks, it got answered. So the more people, it's sort of faster. Also, we can do a lot more fun experiments at the University Act, because proper activity might not get funding to do certain experiments. And obviously, it's fun. So one thing that I really find would be something like this thing called CRISPR. So CRISPR is a genetic action, very cool. And basically, we have a question to move forward from having a constant time in the lab to go on to laptop. So basically, anyone can be done genetic actionary at home. So here are some of the tools that I found. So basically, let's say I have a genetic effect, and I want to show how do I do all of that. If I want to, let's say, design a genetic shock. So using something called CRISPR. Basically, CRISPR is something like a programable, genetic editing tool. So let's say I want to come back again in a certain place where I want to cure my disease. What I would do is I would go to XCVI and have a free database. But if you can do a free database, find the results for any genetic disease, anything that you want. And if you can basically take that, you can find the results in this scientific bioenergy. They basically list, basically, you can take on any game you have. And that basically tells you how you can synthesize the killer genetic tool that will help the CRISPR and how it will help your genetic. You can use two types of tools that you want to basically view and see how everything will go together in your whole DNA sequence. And you can just set it for synthesis. So basically, you can become a, you can basically edit genes in your house. You don't need to add to the lab or anything. You can start doing genetic actionary at home. So actually for this talk, I will be going, you might get that. So if you might have to explore this out by yourself or you did this talk with me after the talk, since this is just a case of. So for basic genetic actionary, everyone that you meet is generally very simple. So basically, it is all very simple processes, keeping code and mixing, things that you can actually, we can alternate things that we can build, build quickly and enjoy at home. So some of the things that we have to do, what we call get-to-engineering. So it involves a lot of duct tape, are we not, stuff like that. So it might work, I don't know pretty, but it does the job. So basically, we can have something in creator that we use to build cells, that we use to culture. But that's why I'm saying that we see how. So we see how this thing to duplicate your DNA. So basically, it sounds very kind of sweet, but it's basically like a little temperature. In fact, very substantial, and I know. So something that you can really easily build with all the different modules, are we going to do things like that. But, so people still get my name is critical, because one thing is, your region are still expensive, you don't really mind what's in it, you have to maintain that for other people are right. And I'm sure by safety, there's other issues and stuff. So, for example, by itself, so if you have that, that's something you don't really want to have in your house, for all these reasons. So this is actually one of the projects that we're working on right now. So this is the job box. It's basically a completely steel environment that you can control, and basically it has a robotic arm inside. And we're planning to actually, basically, we can build that stuff up. So back when you are eight or nine years old, you can control this robotic arm and build that stuff inside. So we send out the email, and we will go and get the VHS for you. And basically, you just pay for the VHS, the rest is pretty much free. And basically, you can allow you to do the experiments that you really want anywhere in the world. And then this will probably be up in about a month or so. So, you'll come back to me in about a minute. Check it out. They have a website coming up soon, so you can check it out. There's your register. And you can check it out if you have this identity. In fact, thanks. Any questions? Why did you get started with this? Like you, was it? Yeah, it was fun. It just, I was good at thinking that genetic engineering is something that, you know, the cases in sci-fi novels and high, expensive labs, you know, when you see the genetic action on TV, you come to see an underground lab with some math scientists, they are cat, cat-dog, high-tech or something. So, doesn't seem really accessible, something that you can do at home. And I first started off in software and hardware. I'm not really crazy that I have to just go online, you know, just like go to or something, and I can find answers for pretty much anything. I can just go to a certain square and buy eight components at once, and I'll just see if I can tell that if it's a quality or something. And what is the first project that you would suggest for some of the students out there? I really have no idea, because I think it really just depends on you where the background is from. So, if your son comes with a software background or hardware background, you can try really, you can try to get a good one. Right now they have three kids of mine, just for genetic engineering kids that you can order. I said to try once, but it's quite good to get them to say that. Okay, so we have a number of projects at the moment. One of them was a prosthetic arm, which actually showed at last year's Osacea conference. So we're actually working with disabled people with amputations and all trying to get it to work. And it's really low cost, so pretty much anyone can afford it. Some of the more flashy projects that we have, that's going on is we're trying to grow a human heart and we're trying to get it to work. So we're trying to get it to work. That's going on is we're trying to grow a human heart. So, at the moment we've actually, we've started growing fish ourselves and we've actually got it to be, but we're still working on, we're still gonna work as human. Eventually, once we get the club work, it's working and everything because of biosecary concerns. Can we come and visit? Yeah, sure. At the moment, if anyone is really trying to sponsor me, we need a space. I've had a lot of investors here in South Asia, so please look for me. Put things in context there, and you're like, what, 15? No, I'm 17 at the moment, so close enough. I'm ambitious to the point of dilution, so why not? Okay, so there's no more questions. Yeah, thanks.