NANONETWORKS & UR BODY - - ATTN: Jbossman

Video Transcript:

Welcome to education ASMR style. The rules of nanotechnology and Internet of nanofamilies in healthcare transformation. A lot of people are unaware of the healthcare transformation that has already occurred. They are without knowledge of something called your digital twin. Your digital twin is inside of a database and accessible to people who have access to wireless body area networks. In this particular college textbook about your personal digital twin, it states right here in particular wireless body area networks and multi source data fusion will be highlighted. Personal digital twins will rely on the joint development of many technologies for multiple disciplines, such as brain computer communications, molecular communications, synesthesia interconnection, AI, and intelligent interaction. We will present a variety of healthcare applications as part of a very early stage list of accomplishments. There are personal digital twin platform development as well as the outlook of personal digital twin related developments across the globe. Now, one of the first things that I attempted to ensure that the synergies understood is that your personal digital twin is already in business. And this article from BusinessWare about digital twin computing is from June 2019. And the reason I cited it is because it gives you a good picture. Here's humans, medical treatment, digital twins, things for the Internet of Things because this is a conventional digital twin usage. Our humans were separate from the Internet of Things, so we had the Internet of Bodies and the Internet of Things. Now we have the bio digital convergence in which we have the Internet of Everything. And even though things are still delineated due to replication, fusion, and exchange, your bodies are now connecting and connected with devices, other body area networks, and body sensor networks at the behest of either AI or a database change. So how did we get here? How did you end up on the cloud with a digital twin? Well, in the past, it was called the sentient world simulation. Sympetic environment for analysis and simulations. So if I go to the Wikipedia, I get Purdue University. Sympetic environment for analysis and simulations, or SEAS, is currently being used by Homeland Security and U.S. Defense to simulate crises on the mainland. What does that mean? They are using models and simulators, simulations, in order to make changes to your digital twin. In order to ensure they have a rapid response to things like pandemics and force fires, anything they need to. Well, that sounds great. That's wonderful, right? Well, the problem is that they didn't tell anybody that your butt is connected to the cloud. And when I asked people how they did not know, so I said, it's not called the sentient world simulation and it warrants the global information grid. And again, folks were confused. They were like, what does that mean? I said, well, the global information grid is the back end of the defense department, the Department of Defense's computer systems across the world. And then I often took them here. The global information grid 2.0 marked 2009 concept to show that this has to do with something called sensors. There are sensors open system architecture and we put sensors in literally everything so that the entire world can be broken down between things in humans and every single natural and unnatural item is leveraged as a tokenized object with net centric access, meaning that anything and everything is connected to the internet via all these digital sensors, all the branches and all the different business strategies like all the vendors and such of the Department of Defense get to connect into the global information grid based on your security. And then I often take people to where's my little pet come thing here. Here we go. When it comes to those of you that do understand that we have security clearances in the United States, you might have heard of these two before, Siprinet and Niprinet. And those are networks that you don't get access to unless the Department of Defense has you with the proper security clearance. A lot of people do not know that the whole internet is connected. They believe there was a dark web or they believe that they were somehow separate. You are not. The DISN with the Department of Defense literally runs everything. Period. Now the Department of Defense is not the one that gets to hold all the information on every single network. Cybersecurity is here article in nature so that not everybody is in the same place at the same time in the same way. However, for our purposes, of all this global information grid and all these people looking for a battle space awareness sensors to shoot air. Because when it comes to their ability to net-centric warfare, the command need assured information to transport in the core enterprise service to support operations in all phases of conflict. Electronic warfare squadron deploying worldwide. For the person who mentioned on the channel you saw in E6B or one of our Navy Boeing planes recently. It's because they have a big radar on them. So I think I'm on the second. Looking to see if we can grab a different paper. Nice to run it this. Anyways, so your global information grid used to be called your synthetic world simulation and that's where your Digitwin came from. But nobody knew it was there. Then I asserted that your Digitwin actually has been in cybersecurity since 2009 but I managed to find a paper that's safe to talk about open source from 2011. The wireless body area network encryption uses biometric data directly out of your body in real time. And most people know that radio frequency jamming is legal but as things continue with this situation we're all in, I imagine we'll be trying just about anything in order to dislodge these biosensors and how they communicate. Whether it's a drone or another body, it's your internal molecular communication routing of your body that will set off the payload, change out the security, stop or block the signal because data encryption between the biosensor head and biosensors are accomplished using dynamically generated symmetric keys. This is back in 2011 which derived from Master Key early registered in each biosensor in order to defend attacks that compromise the privacy and integrity of the user. As mentioned earlier, biosensors in human body are very resource constrained. This is in 2011. Biosensors in human body are very resource constrained so it is more efficient to use symmetric keys between the biosensor head and the biosensors than asymmetric keys in terms of resource cost. It is based on, excuse me, 4.1 security mechanisms. Our security mechanisms are summarized and figured too. First we propose our authentication scheme that is resilient against spoofing and physical compromise of a variety of devices and W bands. It is based on patient, biometric and physiological data which are acquired from his or her body. We assume that each implanted devices are identified manually by the certification authority of the medical center in which biosensors are injected and each base station such as PDA and wearable devices watch clothes are self authenticated by small fingerprint, comparable biometric ID device in order to verify identity via a biometric signature. Our authentication scheme can make an attacker difficult to go for the valid patient's biometric signature and generate patient's own physiological data. This is talking about an ID based ECC. Your Digi ID has feature values that are identified and then those feature values are found inside of something called geomancer and spellcaster with geospatial. So I'm going to take you to geomancer first. And what they do is every time someone accesses your body, the feature values that they accessed and whatever it is they were looking for are kept in something called a spell book. Here's raw coordinates reference data sets and your derived feature values. These feature values are part of your digital identifier. And this is where I am forced to bring everyone back every single time because unfortunately you have been connected to the cloud for a very long time. And in 2018 here in this particular paper with pervasive computing, it explains that the wireless body area network connects independent nodes that are placed in the clothes, on the body or under the skin of a person. Again, cybersecurity for the W band from 2011 and that's everybody. The biosensors of 802.15.4, the working group, I'm going to take you there in a minute. They are industrial. We have an industrial internet of things alongside of the internet of things. And that's why they are not hackable. The W bands don't show up to just anyone. They are specialized bio-electromagnetic algorithms and specialized routing protocols for the W band to ensure that people can't just sniff it, hack it, crack it and change people's physiological data. This system protects things like pacemakers as well. So it's pretty important. And as I've continued to cite for the people from the blockchain community who claimed that they were free as cypherpunks, you are a node on the network. Anything that is connected to the internet is not secure. This is why putting people's bodies as a node on the network without even telling them that they were connected to the cloud and then offering to sell their data blockchain style in order to mine crypto or whatever they're doing with their body and their data is intellectually dishonest and kind of mean in my opinion. Because there are plenty of people out there that when I tell them this that you're already connected to the cloud, they get rather upset because they don't want to be connected to the cloud. They don't want someone else being able to log into their body. And that's before even getting into the fact that no one admits these systems are here unless you're using medical health apps. So if I click in medical health apps, I get a ton of stuff. What are health apps and why do you need them? Healthcare and medical ideas we still need. Basic growth of healthcare at market makes it one to watch in 2019. And it can take your heartbeat and help you sleep better. And there's wearables just like everybody's heard of the Fitbit. And then there's other things you can do on the phone. And then there's ways to connect to your healthcare provider. Well, how do all these things work? Biocignals or biosignals are space time or space time records of a biological event such as a beating heart or a contracting muscle. So biosignals are something that we use in medicine, monitoring and telemetry, pattern recognition and machine learning for biosignal data, neural networks for biosignal data, multi-modal speech and audio processing and biometrics. So when you're using these different health apps in order for the frequencies in the biological signals that those frequencies are allocating to the phone and to the wireless networks, these systems, all of them, have to be mandated by the FCC and the FDA and they are. Federal Communications Commission gives medical body area networks clean bill of health. Wireless monitoring devices will improve hospital care and make way for continuous home monitoring June 2012. Electronic Health Monitoring took a big step forward last week when the U.S. Federal Communications Commission approved spectrum for medical body area networks. The Federal Communications Commission allowed the frequencies between 23, 16 and 24 megahertz which were part of the spectrum that was returned to the commission when TV shifted from analog to digital. So where did we start? We started with talking about how your digitwin is already here with your wireless body area network. Biometrics, cognition and control, cyber physical systems, which is where we're going to end up. Digital Twin Digitization Intelligent Connectivity Perception and Sensing. Oh, excuse me. Personal Digital Twin Pervasive Connectivity. See this word pervasive here? Check it out. Active Computing. What you need to know. Now when I make the assertion that your body area network, type in body area network and you click on the Wikipedia, you read the paragraph and it will tell you the development of wireless body area network technology started around 1995. And then I take you to this wily paper where we already have security protocols, cybersecurity for you being connected to the cloud, whether you like it or not, with no way to access your own WBAN discern what is coming and going for biological signals from your body. Microdoppler Extraction. Those are those feature values I mentioned prior. Whenever we pull your feature values for human activity, recognition radar to see if you're sitting, standing, your gate, breathing, we're using different bioelectromagnetic algorithms that are specifically matched to your DNA. We're using radar systems with that microdoppler in order to ensure that your body is electrically performing the way we want it to. So when it comes to cybersecurity, what you need to understand is that your body is connected to the cloud, there is cybersecurity involved at very high levels, for example, space force to ensure that no one can just automatically hack into your human body communication, which is down here on the other side of the commonly used ultra-wide band, as you can see this spectrum is much smaller than the big one over here. However, the problem that we face has to do with the molecular communication route, because it's one thing to have gotten this far with no way to getting accountability from anybody who uses these systems. And that is why I kept coming back with the Medical Body Area Network Challenge. In 2018, the main reason that they switched to all this AI and Medical Body Area Network and wireless biosignalling has to do with your digital twin, the cybersecurity for your WBAN and saving the hospital money on getting sued because they can take your biomarker biosignals in real time. And so they started testing that out in the senior homes in 2014, and they had been cooking along ever since, and it seems like nobody really said anything. Because each time I brought it up, people continued to struggle, they didn't understand how did the sensors get in me. I explained it's an industrial system, and I explained that the biosensors are made out of you. They are literally made out of you, your own tissue. So you Google biosensors? The biosensor is a device that measures biological or chemical reactions by generating signals proportional to the concentration of an analyte in the reaction. And I prefer to click on images. So that you can see the analyte, the receptor could be an enzyme nucleic acid or an antibody, the transducer optical electrochemical piezoelectric or thermal, which then takes a biological signal and converts it into an electrical signal. They're biosensors, and how are they impacting the virtual reality and healthcare industries? Biosensors have been around a very long time, and they are in use for many different things, not just biological sensing. As you can see over here on the right, 2012 tooth enamel biosensor, 2012 contact lens biosensors, 2015 integrated biosensors, and of course temporary tattoos, or more commonly known now, bioelectric tattoos and your fabulous condots. So the applications of biosensors have to do with environmental monitoring, soil monitoring, pathogen discovery, drug discovery, toxin detection, water monitoring, used biosensors for quite literally everything. And these biosensors create different computer networks that we watch, not just your medical body area network with four layers of cybersecurity inside of you only. Layer two is you bootstrapping to a device. Layer three is your black box decision making to forward data to whoever it is that is meant to receive that data. So your Digi Twin has already been approved by the FDA Modernization Act in Congress in 2022. This bill authorizes the use of certain alternatives to alternatives to animal testing, including cell-based assay days and computer models. That's your digital twin. Additionally, using those cell-based assays, which are essentially your Digi Twin and all these other passive radar systems they use to watch all your cell structure, this bill also removes a requirement to use animal studies as part of the process to obtain a license for biological product that is biosimilar or interchangeable with another biological product. And that is what upsets me the most because people don't even know that we have living robots that are moving around to help take all these different types of biomarker signals, make changes with tissue scaffolding, they didn't tell people what they were really doing when they went with graphing and healthcare. The injection itself creates a cybernano interface. And for those of you that are curious, it's graphing, excuse me. Google fingers graphing healthcare. I've typically go to Frontiers Chemical Journal right here because it's the first one. It's got a beautiful image. Graffing based sensors for human health monitoring, since the desire for real-time human health monitoring as well as seamless human machine interaction, is increasing rapidly in 2019. Plenty of research efforts have been made to investigate wearable sensors and implantable devices in recent years. As a novel 2D material, graphing has aroused a boom in the field of sensor research around the world. So then you scroll down and here's an example of all the non-invasive applications they can pull without each hip in your head. And the invasive applications can be done with an ingestible pill, a sensor that's on a quantum dot or a little tab two on your arm. It can be done with a needleless injection now. So we are way down the line with all these different systems because nobody mentioned that you were attached to the clock. Now when I type in biofuels, okay, and it will tell you aeroves, shock-roses, not real, and nobody knows exactly what it is. Now in reality, your shock-ros are the nodal areas where more of your veins and arteries cross. And I just picked this image because it's kind of easier to see it that way. See where all these lines come in and out. It's just where your gonads and your stomach and more of where your lungs, your heart, all the different things with your thymus and the glands in the endocrine system. That is what your shock-ros actually are. There's more kinetic energy in your veins and arteries in these areas, which are called N-O-D-A-L, no-dol areas in the body. Some people use them with Chinese medicine, acupuncture, acupressure, chiropractic, and then some people use them for deep tissue massage and some people use them in order to alter frequencies inside the human body. And that's what got us in trouble because instead of telling people, hey, this is an actual biological field. People are told this field does not exist. And so then I get stuck in the middle because I have to explain to them this field does exist. And as you can see here, the IEEE International Standards for Electronic Centroelectrical Engineers has an 802.15.6 standard called the Wireless Body Area Network. Now here's what I advise people to do. When we're dealing with the bio field, you will be told that no it's the aura, nobody knows how to measure it, we don't know what it is, and then what I advise folks to do is I say, okay, because everybody knows that they're electrical and everybody admits that they have some format of electricity in their body. So I say go to 802.15 working group, click on images, what do you see? The electrical fields around the body, that's right. And then here's all the sensors that go with 802.15.4, the wireless sensor networks are 0.5, and when you click on this image, analysis of the IEEE 802.15.4A because your Bluetooth or millimeter wave, your body area network, the mesh network, the personal area network, it's all here because you're not allowed to talk about your own human electrical and electromagnetic anatomy. And then people would get upset and say, well, I need to see evidence, no problem. If you scroll down and you type in bio field, the bio field science, history, healing, and terminology is on the National Institute of Health. You want to be looking at bio-electro-magnetics, electromagnetic fields. And as you scroll and read here, it'll talk about all the different ways, the labeled things, how they changed out concepts, and on and on. And specifically, they speak to the electromagnetism, et cetera. However, if you want to see the different ways that we measure all the different electric fields in the body, that is a different search, human activity, radar recognition. And this is where we come back to that whole concept of having a ton of sensors all around you in the air and inside your body. And those sensors report back to the different micro-doppler and regular Doppler and convolutional neural networks and all this machine learning and AI and air molecules. And it translates the data of you moving your body because we measure the magnetic and electrical motion of your entire internal organ systems and the capacitive and galvanic energy of your body as it moves in order to propagate the right signal at the right time for the sensor response that we work to get. In order to convert biological signals to digital, we have to have the ability to beam form in steer. We have different ways that we handle wearables. We have ways that we handle this. We have ways to do this with your air conditioning. Very metric pressure is kind of a big deal. And so it has been difficult to help folks understand that human body as signal transmission medium for body-coupled communication, galvanic mode models. Signal propagation models play a fundamental role in radio frequency communication research. However, emerging communication methods such as body-coupled communication require the creation of new models. In this paper, we introduce mathematical models that approximate the human body as an electrical circuit as well as linear regression and random forest-based predicted models. This would be your bioelectric magnetic algorithms that infer the expected signal loss from its frequency measurement point locations and body parameters. The results demonstrate a close correspondence between the amplitude frequency response predicted by the electrical circuit models and the experimental data gathered from volunteers. So, the development of microelectronics has facilitated the placement of sensors on the human body to create body-area networks. These networks serve as valuable data sources for healthcare and fitness applications. Signals from on-body sensors are collected and processed to derive clinically relevant information. And here on just a moment, electrical circuit model 1. And this goes through these are wearables so that you can see the difference of how they perform against interbody and interbody signal flow in electric quasi-static human body communication. Not wearables simply using your body with weak capacitive coupling or strong signal forward path, simplified circuit model for interbody, simplified circuit model for leakage, interbody not interrupt, inter between two bodies. And then, interbody electro quasi-static coupling for capacitive versus resistive load. And then, I'm going to stay out of phase array at this time. So when I take people to human body communication and frequency, this is where the aura went. They have all the different frequencies, the electrical fields, the electromagnetic fields, and they haven't broken down into the proper math where your body is the circuit on its own for cybersecurity purposes. And this is why I've been trying to get people to do the M-VAN challenge because radio frequency was not cybersecurity secure enough. So we're using your body and all the different calvanic, p-as-ill-electric biochemical, and the current like from your heartbeat, the natural flow of your veins and arteries to propel the nano to make the changes of routing of energy inside of you. So to continue to tell people that we don't know what the aura even is, when it's on the National Institute of Health as the human biofield. And to continue to tell people that we don't know how to manipulate their bodies, radio frequency, radiation in a body area network, capacitive coupled, e-human body communication, magnetic human body communication. Not only do we know what we're doing, but we have multiple jobs and folks in every direction you can imagine in order to keep you cybersecurity for things like your pacemaker or if you have an insulin pump. So in cybersecurity just to make sure you understand, as a note on the network, you are accessible to the physical data-linked network transport session presentation and application layers of data as they come and go. So given that your body is the physical layer of all this connectivity, data-linked layer and just a little bit of the network can host peer-to-peer, very close with just you and another person, but in the tokenized digital ledger system it's always recorded somewhere with something called the remote PHY physical layer. Your distributed ledger is a record of consensus with cryptographic audit trail maintained and validated by nodes and that would be your biometric data as I read out from 2011. It's a little updated now. I'm going to get there momentarily. Blockchain is a way to implement a distributed ledger but not all distributed ledgers, necessarily employee blockchains. And again, your digital twin with air molecules that are nearby and can be changed by their states in order to affect something called wake up radio. Software defined metamaterials, it could be the smart dust, it could be actual wireless sensor networks that are supposed to interface with your body and we have energy harvesting nano nodes that land on the outside of you to ultrasound based wake up radio. So we only want to wake up certain nodes. The nano nodes however many of them are flowing through you are passively flowing in the bloodstream and energy harvesting entities to be localized for application support, eG targeted drug delivery. When I say precision AI, healthcare and wireless drug are very sincere, that is the direction they are headed. That's why the FDA approved the digital twins so that they could just use the wireless to get the electrical signal in. And the nano nodes, these little nano bots, they redistribute themselves based on the wake up radio and the localization of themselves to where they're supposed to go or not go. This is why being a node on the worldwide web without anyone saying anything about it is so dangerous now. We have terrahertz radio for localization and communication and we have energy harvesting nano wires that grow along and inside of the veins and arteries helping out. The energy harvesting entities, they tear themselves down, put themselves back together at the cost of your red blood cells and vasculature, the energy from your body. So one of the things that comes with all this corona nano routing is, for example, from the journal of nanotechnology. How can nanotechnology help to, I'm not a second, an overview, I didn't want that one, I wanted this one. Journal of nanobiotic technology, biomedcentral, an overview on nanoparticle based strategies to fight viral infections, okay, another COVID one. And your corona is your coordinate routing system for nanonetworks, which is only going to show you little squares and things because that's kind of the flood sequencing of the packets. Here's another example of your energy conserving routing scheme for wireless body sensor nano networks because initially the signal would go all over. Another term you can look for is nanomedicine. Does protein corona route target or off-road? The perspective on bio-nano interface technology for COVID-19? Body to body network communication. So here's your node controller, for example, with other body-oriented networks. For example, we have a system parameter for WBAN routing protocols, system model and wireless body-oriented networks. So for those of you who are good people who have no idea any of this existed, we are absolutely out of time for folks to not understand that we have human activity recognition radar in which we are able to assist your body with only a drone. The implementation of the Internet of Things and UAV unmanned aerial vehicle, a drone, based wireless body-oriented network for healthcare applications 2021. This research work focuses on the rapid data transmission between the patient and doctor using a drone. Five sensors, heart rate monitoring, temperature, human motion, oxygen meter and blood pressure. And therefore, it would be really, really helpful if we could find a way to get folks to understand that you're not going to be pulling yourself off of the cloud. There's no law fair to remove any of this. The cyber physical backbone was finished in 2017. Cyber physical backbone. And the reason I keep bringing this up is because it's important to understand that unless you're a value chain partner or a stakeholder of the value chain, you don't have the power to change their mind. So then people kept asking me, okay, Sabrina, I understand we're all connected to the cloud, turning the body into a wire December 2020 to safeguard sensitive data, turn flesh and tissue into a secure wireless channel. Your body is the medium. Your body is what is generating the electricity, capacitive human body communication and galvanic. Intra body communication, radio frequency waves, ultrasound waves, see how they're differently shaped, electrical current, electric field with an external ground and a magnetic field. And then the search for this Google fingers is intro galvanic coupling images. And as you can see, everything that you can imagine of how we measure electricity and magnetic current through the body, piece of electric compression with your muscles, with galvanic energy and then mechanical stress on the bone, biotense, and all of it. We have all of it. And that's again, why it is absolutely critical that humans understand that you are no longer worried about reading your mind. Their way past that, they're reading biomarker biological signals anytime they want to, reporting them to human activity radar. Because see, it looks like this in the air molecules that then transfer with ubiquitous and pervasive computing, which is AI and deep learning, and then we're watching you walk. It looks like this, the software on the person's phone or iPad or whatever they're looking at has a different graphic user interface than just seeing all these blue lines and numbers. And that's the modeling IIT sex software that we talk about on the channel. So for those of you who have been asked to be here on the channel because your loved one wanted you to know about this, I hope that this tone of voice and this way of reading it out and explaining it was helpful to you. There's almost always a list of links in my description so that you can take all these different things and see for yourself. The bio block, a blockchain and now goes mechanism for integrity and the internet of bio nano things based drug delivery systems. So wireless drug and last sounds terrible Sabrina. I know, but look what we get. Wireless implantable devices loaded with drugs are promising for localized and on demand pharmaceutical delivery. Well, how about wireless on demand drug delivery? Nature electronics July 2021. Wireless on demand drug delivery systems exploit exogenous stimuli, acoustic waves, electric fields, magnetic fields and electromagnetic radiation to trigger drug carriers. The approach allows drugs to be delivered with controlled release profiles and minimal off-target effects. Recent advances in electronics and materials engineering have led to the development of sophisticated systems designed for specific applications. Here we review the development of wireless on demand drug delivery systems. We examine the working mechanisms, applications, advantages and limitations of systems that are triggered by electric fields, magnetic fields or electromagnetic radiation. We also provide design guidelines for the development of such systems including key metrics for evaluating the practicality of different smart drug delivery systems. Number two, electric fields can be generated by electrostatic charges as in parallel plate capacitors or time varying magnetic fields as in dual heating and induction heating. They have been employed in medicine with different therapeutic effects such as actuating drug depots for in vivo drug delivery and enhancing the drug molecule transport via electroporation and ion to foresis. Ion to foresis and even directly treating cancer tumors called tumor treating fields. So, you know what, second? So that's this one. Drugs go wireless, nature biotechnology. Just going through the second one. And that's 2016. Electronic drugs and delivery systems are reaching the market, giving drug developers and healthcare providers a way to improve patient compliance and more. Okay. So, I like to go to images so that you can actually see some of this in action if it will allow it. And I also let me grab my other search. The other search that you want to try is, left row suit to close. Electro suit to close. On demand. Electro suit calls. A wireless platform. And mechanical energy, electrical energy, epinural interface. A self sustainable platform. Got a wireless, neural clip, a bladder nerve thingy, something on the vagal nerve. Here's another one. We're able an implantable electro suit calls for therapeutic electrostimulation. So this is why the FDA was like, hey, let's do it. Let's go because we can check the Digi Twin. We're doing a lot with telemedicine and remote healthcare. We are absolutely ready to be sourcing our data with the drones, with the W band. We have our human activity recognition radar, which then gets translated in real time into whatever. And however we want to see what's going on in your body. And how are they doing it? They are routing computer networking game theory through the human body. This is cybersecurity with the wireless body area network. ZivSlog, intelligent transmission power switching approach. This particular paper is in the Synergy Tecmetric PDF. Routing theory based routing protocols and wireless sensor networks. Survey on Q learning based position aware routing protocols and flying at hot networks. And you're the little body down here around the more circle math. So that's how they are doing this. They are routing computer data through human bodies as a matter of what they do for work. The merester thus are still trying to communicate with people we love that this is human anatomy. If they have provided a technology like a wearable and adjustable, then you could have just not taken it, taken wearable off. They literally took your human immune system. So what I've been doing lately is trying to help people understand with a better picture. So this is when I tell you that 80% of your immune system by the mean median in mode is your biofield. The largest organ in the body is the skin and check out all these other connections of your immune system. Your entire lymphatic, all your veins and arteries. So now because nobody bothered to mention any of this, again, it's a really rough place to be because everybody thinks they can pull it out of them that they can somehow find a way to cleanse the biotechnology out of their system. And unfortunately, that is just not realistic. It's not the way the system is built. It's not the way the cyber security runs and more or rather most importantly. Here's my page. No one knows. Secure strain for medical data. Oh, don't forget about your electronic disease surveillance system with the CDC. National Notifiable Disease Surveillance System. Why didn't you come up properly? Electronic Integrated Disease Surveillance System. Oh, that's why I missed a word. Integrated. There we go. Integrated. Nothing here. Disease Surveillance and Response. The Integrated Disease Surveillance and Response framework makes surveillance and laboratory data like those that say is more available. And this has been around since 1988. And then I normally make sure you know about the COVW ban, which is the intelligent and energy efficient wireless body area network to control COV ban. I have been making sure that this particular widely article is inside of most of my videos so that you can see all the different mathematics for the capacitive coupled human body communication between receivers and transmitters and transceivers. Now we've got Secure strain processing. Oh, your feature IDs, medical health apps. Okay. Sorry folks, I'm looking for that original paper that I wanted to go over. Excuse me a moment. Okay. The rules of nanotechnology and internet of nanofanings in healthcare transformation. Healthcare has a basic human right to not remain immune to innovative technologies. Technological progress has significantly contributed to high quality on time acceptable and affordable healthcare. Since their appearance, nanotechnology and the internet of nanofanings that continuously affected healthcare and have a tremendous influence on its transformation contributing to the better outcome. The inclusion of nanotechnology and medicine through nanomaterials and nanodervices known as nanomedicine. Nanomedicine. Has brought numerous benefits and disease-preventured diagnosis and treatment. Going further by connecting nanodervices to the internet, the internet of nanofanings paradigm has been created. The inclusion of internet of nanofanings concepts in healthcare has resulted in more personalized, timely, and convenient, health, monitoring, and treatment. Hence, nanotechnology and the internet of nanofanings hold the potential to completely revolutionize healthcare in the 21st century creating a system that will enable early disease detection. This is September 2017. Okay. So there's the internet, your healthcare provider, your micro-intensive, yeah, it's your gateway, boots to happen to you. And here is your Inker node area, wake up radio or not to our nano link or nano router to ensure that only the places in or on the body that we want to go are what gave welcome up. Nanoparticle ingestion, nanoparticle inhalation. Okay. Potential harmful effects of nanoparticles to human health. Come on. There we go. The roles of nanotechnology and internet of nanotanks in healthcare transformation. Same thing, healthcare is a basic human right introduction. As a technology that is enabled science and engineering on the exponential scale and nanotechnology is resulted in the development of nanoparticles, nanomaterials, nanoscale electronic and sensing devices and is considered to be the technology of the 21st century. Technological advances have enabled nanodivisus composed of nanopomponents to perform single tasks, excuse me, simple tasks such as sensing or actuation and to be connected to the internet through seamless communication and information transmission. Nanotechnology and the internet of nanotanks already have significant roles in numerous applications across diverse sectors such as agriculture and food environment protection, electronics, energy, and bio-medicine. Now, RumbleDent has this page loaded right now with AI reading it to you, so I just want to go through a couple different things. As it is anticipated that in the next few years there will be no aspect of life untouched by nanotechnology and the internet of nanotanks, again this is in 2017, that they receive growing worldwide attention. New and enhanced properties and functionalities are the results of production of novel nanomaterials and nanodivisus. This means that the new ways to synthesize nanomaterials and create nanomaterials, the analysis of nanomaterials and nanomaterials potential toxicity in the development of novel nanodivisus, nanosensors, and nanocommunication. And then it talks about, in addition it is forecasted that the global nanotechnology market will grow, nanomedicine markets will grow. All right, so this is why nanomedicine as medicine of the future, nanomedicine would be defined as the use of nanodivisus and nanostructures for monitoring, repairing or controlling, controlling human biological systems. Now briefly, just again to have another search term to look to, nanomedicine is the medical application of nanotechnology. Click on images, here we are. And here's where 1964, 1976, 1980, first targeted liposomes, 1994 long circulating PLGA pegnanoparticles, 1995, first liposome approved by the FDA, 2007 polymeric, myself Pat Littaxle marketed in Korea, and 2008, first targeted silicon, I think RNA polymeric nanoparticle, and your clinical trials, 2011, first targeted controlled release polymeric nanoparticles, and your clinical trials. So we got polymer, unite ligand, anti-cancer drug, okay, here's another one. Medical imaging, radio sensitization, immunotherapy, drug delivery, nanocascade, chemocatalysis, photo-catalysis, localized hyperthermia, and then why nanomedicine, sun screening, diagnoses, and treatment, delivery and function, synthesis, molecule cells, tissues, and the organisms, you can see a club there. And what we got here, ocular nanomedicine, only for the eye, okay, so you get the idea, biomimetic nanomedicine. So this is why I have been so ardent and so upset on the channel, because I know very well that there's people watching this right now, not only did they have no idea that it wasn't a virus, but they took the cyber nanosystem and got rid of their actual body-given immune system, so that this nanodrug delivery, regenerative nanomedicine cancer detection and smart pill system, will be utilized on them instead of their natural immune system. Thus the need for continuous injections, but now they're growing it in the food, you're breathing it in, they have it in the water, it's in the human other body area networks around you all the time. Excuse me, and for that, I do not call it shedding, I call it load balancing body area networks, because that's how it authentically functions with your natural body's communication when you're around another person. So nanomedicine is medicine of the future. Nanomedicine may be defined as the use of nanodvices and nanostructures for monitoring, repairing, or controlling human biological systems at the molecular level. Engineer nanodvices and nanostructures used in medicine and healthcare can be classified into four categories. First generation products, dispersed in contact nanostructures, e.g. colloids, as well as product incorporating nanostructures, nanostructured metal, and polymers, 2000. Second generation active nanostructures, physical chemical active adaptive structures, actuators, amplifiers, and bioactive devices, bio devices and targeted drugs 2000 to 2005. Third generation nanosystems, 2005 to 2010, robotics and evolutionary bio systems, and fourth generation molecular nanotechnology and nanosystems molecular devices by design, and molecular structures that could serve as a foundation for regeneration or replacement of lost body parts. So then it talks about nanoscale precision, bio-farm aesthetics. The utilization of nanoparticles as drug delivery systems has already shown great success. As nano-enhanced drug delivery products already are a commercial reality drug delivery is a dominant research field in nanomedicine. Polymerons and photos, there's just so many terms. Targeted delivery of peptides from DNA, as well as detection and photo-thermalusis of microorganisms and cancer cells, are other examples of golden nanoparticles usage in biomedicine. Cancer is one of the leading causes of death in the world, but at the same time it is the largest therapeutic area where nano-enabled products have made major contributions. Silver nanoparticles are used in the diagnoses and treatment of cancer. Similarly, the usage of golden nanoparticles functionalized with target-specific biomolecules can effectively destroy cancer cells or bacteria. In other words, golden nanoshells are being used if I cancer in such way, after entering tumor cells and applying radiation treatment, they absorb energy and heat up enough to kill the cancer cells with minimum harm to the surrounding healthy cells. The improvement to the orthopedic implants lifespan can also be achieved by using carbon nanotubes. Nevertheless, the utilization of implantable nanosensors enables more effective detection of a targeted chemical or physical attribute. Implantable and nanometical devices or nano machines deployed inside the human body, yes, you read that right, can perform actions according to demand-survey remotely controlled from the macro scale and over the internet by an external user, a healthcare professional. Nanotechnology also enables the development of surgical instruments and robots that perform that enable performing micro surgeries in a precise and accurate way. So, diagnostic tools. The utilization of nanotechnology for clinical diagnostic purposes is referred to as nanodagnostics. So, GoogleFingers, same thing instead of nanomedicine, nanodagnostics. What do we get? Oh, state-of-the-art nanodagnostics and nanotherapeutics. Against the COVID, again, nanodagnostics and nanotherapeutics, polymer nanoparticles, liposomes, solid lipid nanoparticles, gold nanoparticles, silicate nanoparticles, nanoteria, awesome. And so, here's a good one that has an adeninant. Inorganic nanoparticles, carbon nanotubes, magnetic nanoparticles, quantum dots, lenium nanoparticles, mesoporous silicon nanoparticles, gold nanoparticles, organic nanoparticles, nyonisomes, liposomes, polymeric nanocapsule, and nanoemosure. And the same thing, right? Nanotheranostics for cardiac diseases, surface modified nanoparticles, active targeting to ligands and inflamed endothelium, nanoparticles, eluting stent, imaging by nanotechnology. So, they're very busy. And as always, gene delivery, this is polymer's emerging application of magnetic nanoparticles, photothermal therapy, drug delivery, UV radiation, cell imaging, treatment of bacterial and viral infections. 2.3, diagnostic tools, nanodagnostics, there are numerous types of nanoparticles that enable detection of pre-cancerous cells, a fragment of viruses, specific proteins, antibodies, and other markers and indicators of disease. Quantum dots, very small semi-conductor particles, hold potential for creating disease detection systems that are more sensitive and accurate. The utilization of novel sensors and lab-on-achyp concepts based on nanotubes, nanowires, cantilevers, or atomic force micro-scopy for diagnostic. Purpose is improve the sensitivity and enable faster and more accurate diagnostics alongside reduced costs. For example, carbon nanotubes and gold nanoparticles used in sensors enable the detection of oral cancer indicators. Nanoparticles called nanoflares are used to discover cancerous cells in the bloodstream. And furthermore, in vivo imaging, can be performed using nanoparticle contrast agents mainly for MRI. And then I think, yeah, it wills nanoparticles and a bunch of other stuff. Internet of nanotanks and medicine and healthcare. The Internet of Things is a network of smart things devices connected to the internet and able to communicate with each other and with humans. That has brought tremendous benefits in modern society. Further reduction of the size of devices to the nanoscale from one to a few hundred nanometers and their connection to the internet have enabled the appearance of a paradigm dangling the internet of nanotanks. The Internet of Nanotanks is based on the usage of nanomachines, small components able to perform simple processing sensing and control tasks that are used for the development of nanoprocessors, nanomemaries, nanobots, and nanoplocks. So nanomachines are developed using the top-down approach, self-assembly of molecular components, bottom-up approach synthesis of nanomaterials from atoms or molecules, or biohybrid approach designed based on molecular signaling. Nanonotes used in nanomedicine or nanomachines composed of control and storage unit communication unit, power unit, and a variety of sensors and actuators. So, okay, the remote control of the nanodavises over the internet is performed via gateway devices. Regarding communication radio frequency messaging in the 110-megawattes is a possible way to send a message into a body while most cell communication uses chemical signals. That would be your molecular communication routing folks as well. However, the uniqueness of nanodavises and nanonotes implies that demand for new solutions for communicating with the outside world and between nanodavises. It is important to highlight that molecular communication is nano-electromagnetic and connects to nanodavises transmitting and receiving electromagnetic radio frequency waves in the terror heard span. Nanonot work utilization in medicine and health care is the most present in nanoscale surgeries, smart drug administration, and detection and management of the rapid spread of infectious disease, like the electronic integrated disease surveillance system with the CDC since 1988. Okay, just like your passive radar here has the microdoppler with your feature value extractions, just like your co-wvand is watching how much corona you do or do not have in using low-range lura-based internet of things to talk back and forth, along with your biosensors. Just like your corona coordinate routing system for nanonot works to ensure they can talk to each other properly, a number of hops, their anchors, obtaining a sense of geolocation. See how all of this brings us back to the fact that you're a node on the network that no one ever told you, you've been connected to the cloud since 1995. And it's too late now to turn off anything because they already did it and mandated it back in 2012. Just going back over broad brush here with everything we just talked about so that you understand why it is so difficult to help people realize there's no law fair for this. It was done in 2017, two years before the deployment of COVID. They absolutely watch you move with air molecules. We have an internet of bio-nano things with the IEEE as in 2015 because it's not the internet of everything, not just the internet of things. A unvanned aerial vehicle based wireless body-oriented network for health applications in 2021 can send and drone over your home or over you for your temperature, your motion, your oxygen, your blood pressure, and your heart rate. In 2020, the IEEE made it very clear that in order to safeguard sensitive data, we need to turn flesh and tissue into a secure wireless channel. Your digital twin, excuse me, your digital twin is absolutely already here in cybersecurity. I can show you it's been there since 2011, hybrid security protocol for wireless body-oriented network, wireless communications and mobile computing 2011. We are currently still reading our nano network civilization and medicine and healthcare. It's most present in nano-scale surgeries, smart, broad administration, and detection and management to the rapid spread of infectious diseases. That's why I bounced over there. So the internet of nano-things, paradigm enables doctors and healthcare providers to gain insights about the patient's current health condition as well as remotely monitoring control. Any sudden change in the body through the nano sensors or nano robots embedded within the patient's body. Some examples are the monitoring the blood glucose level, delivering a drug in case of need, or monitoring the biomarkers of cancer. The inclusion of nano devices in the internet of nano-things in medicine and healthcare enables access to hard-to-reach areas and vital information at a whole new level. Molecular information, molecular communication. Inside of 3.1, I think is what it is in our security, modification of data 3.3. A malicious intruder may inject a false note on the human body ignoring the user's approval. This note can insert, change, or delete the information transmitted between nodes and W-bands and utilize an ADOS attack or man-in-the-middle attack. If the private healthcare data of the patient is modified in wireless body-oriented networks, he's she can get a wrong disease or be unaware about the disease due to false information. This is why the cyber security is partially based on your real-time biometrics inside of you in order to craft the cryptographic key for that wireless sensor network to get through. This is also why it was very important to shrink down that huge egg size radiofrequency bubble to only human body communication. And as you can see, here's all those different mathematical equations that I was referencing for intergalvanic, capacitive coupling, things like that with your skin. The epidermis and conductive layers below the skin. So in this manner, it is possible to detect diseases make an accurate diagnosis earlier and react faster than ever before, which significantly increases the chances of successful treatment and overcoming diseases. Benefits, challenges, and risks, no specific regulatory framework for nanotechnology-based products. They always have a rogue map. Again, if you want to listen to all of this, the rumble dad will have it loaded at some point this evening. The synthesis of nanoparticles can be performed by plants, algae, bacteria, yeast, fungi, and human cells. At the same time, the internet of nanothings that holds the potential to revolutionize healthcare more than anything else before also brings risks and challenges that must be considered. The internet of nanothings enables to gain better insights into health conditions remotely monitor and control and timely and accurately respond to unexpected changes in the human body. Nevertheless, the primary concerns are security and privacy issues. Health-related data are quite sensitive and they have to be properly protected to reduce the risk of any malicious attacks, disruption, and medical applications that can harm or kill through drug delivery and radio communication. A strong network security infrastructure for all ranges of communication are menos from nanodevices rather in gateway further to the cloud is mandatory. Existing security mechanisms and techniques are not suitable to secure nanodevices. It's a very small and implies the necessity of new and appropriate security and privacy framework and mechanisms presented in various research works 31 through 34 and 51. Some of the proposed solutions are checking the integrity of information by using checks some algorithms using encryption algorithms to code information before transferring between nanodevices critical data hiding algorithms and multi-layer authentication to guarantee only authentic user can access nano networks. So here's an analysis of opportunities and threats strengths and weaknesses and then your conclusions. So for those of you that do not like the way I present data, what for whatever reason, I do appreciate that there are those of you that just want the information. Well there you go. And this is really all you need to know. You can pick up a synergy tecmetric PDF all the other things that I have been going through. I've been doing it primarily for the people who are researching legitimate mitigation because nearly a third of all US physicians are already using AI. Addressed diagnostic errors, the largest cause of malpractice claims. A recent physician survey by the doctors company, the nation's largest physician-owned medical malpractice insurer found that 53% of physicians are optimistic about the prospects of AI in medicine. 35% are using AI in their practices. 66% believe that AI will lead to faster diagnosis. 66% believe that AI will lead to more accurate diagnosis. Potential benefits from AI in healthcare include assistance with case triage, enhanced image scanning and segmentation, supported decision making, integration and improvement of workflow, disease risk prediction, patient appointment and treatment tracking. But there are also potential risks such as false positives or negatives, systems error, over reliance, unexplainable results, unclear lines of accountability, new skill requirements, network systems vulnerable to malicious attack. To lessen these risks, physicians must seek training in the use of AI and adhere to the standards provided by the device companies. Training will also enable physicians to fully and clearly articulate potential harms to patients in order to obtain true informed consent. The AMA also has proposed that AI training should be incorporated as a standard component of medical education. Hospitals and other practices are also key to ensuring proper development, implementation and monitoring of protocols and best practices for use of AI systems in healthcare. So, again, for the folks out there that come to the channel and you do not need to listen to me talk, you do not need to hang around. You will find that you can just pick up all the different things we talk about in the links and I try to leave the links every time I post something different. Electrical stimulation, a panacea for disease July 2016, IEEE Pulse, DARPA investigates new bio electrical interfaces for a range of disorders. It seems simple, send a small electrical current to a major nerve in the body and stimulate hormones and organs to react in the way you want. New efforts by research teams are doing just that. Zapping peritroners attach to major organs in the hopes of addressing problems as diverse as inflammatory bowel disease, chronic pain and post-traumatic stress disorder. Thanks to the continued advance of smaller and more efficient electronics, researchers are finding new ways to develop implantable biological devices to treat a wide range of ailments. So, there you go. And for those of you that are unaware, I just want to make sure I do put this in here at the end. The, from nano communications to body area networks, it's truly personal communication and this is IEEE from 2020 talking about the optical and wireless radio transmissions, inductive and body coupling, soluteursounds, a number of mature technologies existing already. The main goal of this article is to identify the potential mechanisms that can be exploited to provide interfaces in between nano and, excuse my nose, and micro scale systems in body area networks. These interfaces have to bridge the existing gap between the two worlds in order to allow for truly personal, truly personal communication systems to become a reality. The extraordinary applications of such systems are also discussed as their strong drivers of research in this area. For those of you that wish to do your own continuing research, another place that I would suggest looking is nanoworks.com, nanowork. nanowork.com, they always have all sorts of different things they talk about daily, some hotsware and what they're working on. Pushing the boundary on ultra low frequency gravitational waves, wireless light bulbs for biomedical applications, bio-reabsorbable multileir films enable long-lasting bio-electronic implants, physics-based predictive tools speed up battery and superconductor research to a deep biometallic. Moff derives selenium electrocatalis for water splitting. So that's basically it. Again, there are links on my videos so if you do not wish to listen to me speak and you do not need to hear it explain to you because you're simply there to get the data. There's nothing wrong with that. I am not offended. If you do not know that we record neurons, that's this is the last paper I wanted to make sure I got in here. It's called neural recording and I would definitely suggest that you take a look at it because it's scalable and this is from October 2013. I'm going to be going deeper into this because it's a huge industry of recording and interrupting your neurons because again they have the entire human bio field which is 80% of your immune system and they listen to your neurons communicate and neural networks. Okay, make sure I have everything here. I want to thank you for your time. Whoever it is that of your loved ones that sent you to the channel, I'm sure the main reason they wanted you to know is again that human activity recognition radar because we are way further down the line with transhumanism than most people cared to admit to and for that reason we have a lot of folks who are relatively jared because they weren't aware for example of the neural recording electrode technologies that we have. It's a lot more than just reading your brain. Single neuron representation of individuals, brain gate, neural prosthesis for tetraplegics, silicon probe with integrated micro LEDs, silicon probe with microfluidic channels, neural recording electrode technologies that neuronal loop is closed because we use an FMRI or EEG to read your brain wave states from the air molecules. Those are via wireless sensor networks. Here's you on the left and the different data that is data collection and pre-processing component then they create a model of it. So here's your features, your feature values. Then they have a model of it and they put it through the different compressions and learning models that they want to change and they hit send. And the reason that they're able to do that is all of this deporting math that then creates a radar cube in which the data is processed in a very specific way in a one moment. And inside of our radar data cube and we take what we want to change. See it says the range the time and the frequency. We take a look at the surface of the topology of the cell structures into great range of how we're going to fire back and forth. This is a convolutional neural network. These are all different ways to verify that the math is accurate before making the change from your feature extraction to the feature selection and then aim and fire in order to execute an electrical signal inside of a biological unit. The wireless body or a network routing protocols are built off of things like this body vitals user contacts, since Dan Lang walking climbing and running. Again, data collection, pre-processing, feature extraction, sensor fusion and machine learning, detailed activity and intensity of activities. I definitely wanted to grab that really quick. Two things for those of you that do not know what SOSA is, sensors, open system architecture. And what that is is the SOSA approach enabled establishes guidelines for command control, communications, computers, cyber intelligence, surveillance and reconnaissance systems. And there's our MQ9 Reaper and I think it's your Kratos. Yeah. So your sensors open system architecture with the global information grid is in use by everybody. Mosa is your modular open systems approach. modular open systems approach. Okay. Can we define as a technical and business strategy for designing an affordable and adaptable system? Yeah, I'm going to talk about that too much because this is the hardware software side to make certain things work or make other things not work for safety and security. Okay. What was that? My radar cue. What was I looking for? Oh, the WBAN protocols. They are also in the synergy tech matured PDF. WBAN routing protocols. You click on images and you're going to find the same thing that repeats in the main five are quality of service, cluster based, cross layered, posture based and thermal aware. Energy efficient routing protocols in the WBAN with their complimentary bioelectric magnetic algorithms. Routing protocols for wireless body area sensor networks are also temperature aware cross layer cost effective, but they're a little different. C cost effective and self organized and they also have different bioelectric magnetic complimentary algorithms. Just a second. Where are you? Different listing. Might make it a little easier to understand maybe not. So again, postural movement based routing delay tolerant aware routing cross layered quality of service and thermal aware and adaptive thermal aware WBAN routing protocols. Same thing. Okay. So your wireless sensor networks though they get pretty crazy with their different ways that they route through the body plus other equipment. And I grab this one really quick. The wireless sensor network routing protocols path establishment network structure protocol operation initiator of communication. As I said, the 8 or 2.15.5, which is these guys, they run a bit differently because they're more random and they're typically more machine than human. So given that the FDA has already in 2022 decided that the digital twin is the way the future. I would greatly advise that we get ready by educating our loved ones as best we can what their choices really are. If you continue to use the systems that they have built, you will have more nano machines and bots inside of your body. Because the internet of bio nano things is only going to increase in market share and electronic drug delivery given the time period of instability with the economy etc etc. That is where these folks brought us on purpose. Nobody was confused with the deployment of all of this. Not at all. This w