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The transcript asserts that the Moderna technology used in COVID shots is described in a 248-page patent filed in 2020, which lists several embodiments or variations of the technology. It states that although it is unknown which embodiment each batch used, several different batch numbers were deployed, and some were far deadlier than others. According to the Moderna patent, the technology contains self-assembled nanoparticles, and in certain variations these nanoparticles can be used for the controlled release of compounds once they are in the human body. The lipid nanoparticles are encapsulated into a polymer hydrogel, a controlled release coating that includes polyvinyls. This has been verified by Anna Mielchia and Clifford Karnikom's research. In a 2013 TEDMED talk, Doctor Ito Bachelet says that these nanorobots have already been successfully developed in Israel and that they can be injected into the human body with a basic syringe. He shows an image of what they look like, and they appear to be the same structures that the fifth column found in their research and claimed was powered by five g, which was confirmed by doctor Bachelet. Speaker 1 adds that developed nanorobots carry antennas made from metal nanoparticles, and the antenna enable the nanobots to respond to externally applied electromagnetic fields, so these versions of nanobots can actually be activated with a press of a button on a joystick. The transcript further cites work by Todd Callender's team at Vaxchoice dot com, which has concluded that these shots contain a variety of synthetic pathogens that can be released with external five g frequencies. It states that the Moderna patent describes these nanoparticle mimics, which mimic the delivery of a variety of pathogens and lists over a hundred of them within the patent. According to the work at Vaxchoice, these synthetic pathogens each have an IP address. They are cataloged by the Department of Energy, and they use cesium-137, which the transcript claims we have been contaminated with from the environment, as a building block for their construction within our bodies using external frequency. The research allegedly shows that the Microsoft patent filed in 2020-06-06 060606 cryptocurrency system using body activity data is now in effect and that this technology is turning the human body into an antenna, which can output energy, meaning that humans are being turned into batteries to fuel the digital AI prison that is being built around us. And it is claimed that if you choose not to comply, the technology includes a built-in kill switch. The transcript closes by noting that independent researchers and scientists are uncovering this agenda, but they continue to walk freely among us, unrestrained by any justice whatsoever.

New materials can change shape on command, becoming almost muscular, allowing aircraft to optimize their shape for different flight conditions. Carbon nanotubes can be embedded to make conductive structures, so information flows through the structure itself, not just a wire. Small, maple-seed-like devices, like the Lockheed Samurai, can fly with sensors and cameras. Unmanned autonomous vehicles may carry cargo where there is no infrastructure. Small swarms of vehicles could interact with a larger vehicle, sharing information. Heterogeneous swarms, where elements have different functions like carrying sensors, can adapt to changing environments. The true value of research is in finding answers you didn't know to look for.

We're testing a device using sound frequencies to put out fires. It could be used in kitchens or attached to drones for forest or building fires. Professor Brian Mark helped us a lot. Engineering is about finding simple solutions to complex problems.

A programmable liquid created by Harvard is revolutionizing technology. It can change properties like springiness, optical features, and viscosity. Made of tiny elastomer spheres, it can switch between flowing like water and resisting flow. This liquid showcases advancements in science, not just a movie plot. Welcome to the era of programmable liquids.

We are developing graphene nanopores for DNA sequencing. Graphene's single-atom thickness allows for high-tech applications. Graphene's conductivity surpasses copper, enabling various uses like conductive paints and faster electronics. Graphene's strength and transparency make it ideal for smart devices and solar panels. Graphene circuits can revolutionize healthcare by detecting health issues early. The push for 5G networks aims to connect devices and improve industries like healthcare and transportation. The integration of technology into daily life raises questions about its impact on society. The goal is to bridge the digital divide and create a more connected world.

MIT engineers have developed a method to mass produce tiny robots called thin cells. These cells can be used to monitor conditions in pipelines or detect diseases in the bloodstream. The process, called auto perforation, uses the fracturing process of atomically thin brittle materials like graphene. By controlling the natural fracture lines, engineers can create minuscule pockets with electrical circuits and materials for data collection. To build these cells, a layer of graphene is placed on a surface, followed by the deposition of polymer dots containing electronics. Another layer of graphene is then added, causing high strain in the material. This controlled strain leads to the formation of round graphene pieces. The researchers believe this production method has great potential for micro and nano fabrication.

MC10 has developed a developmental system with an antenna and sensors embedded in it. They plan to work on advancing a tattoo for authentication. Young people may not want to wear a watch, but they would be interested in wearing an electronic tattoo with a cool design. Additionally, authentication could be integrated into daily habits, such as taking a vitamin. MC10 has created a pill with a small chip and a switch inside. When swallowed, the acids in the stomach power it up, creating an 18-bit ECG-like signal in the body, making the entire body an authentication tool.

These cell-sized microrobots, crafted with electronic circuits and tiny particles, are so small they can navigate through blood vessels. We've created robots about the size of a human egg cell that can sense their environment, store data, and perform computations. These robots are 3D printed with tiny electronic circuits that react to electronic or magnetic signals. Best of all, they're self-powered, needing no external power or batteries. We can guide them to areas standard drugs can't reach, revolutionizing drug delivery and potentially breaching the blood-brain barrier. Stay tuned for more updates.

Our technology can detect people's emotions even if they don't show them on their faces. Using a wireless device, we analyze the reflections it captures from a person's body to infer their emotions. By focusing on the minute variations in breathing and heartbeat, our algorithms extract these signals and feed them into a machine learning algorithm. With an accuracy of 87%, our device can automatically recognize if a person is excited, angry, sad, or happy. We believe this technology, called EQ Radio, has various applications. It can help movie makers evaluate user experience, enable smart environments to detect emotional states like depression, and even adjust lighting or music based on our moods. To learn more, please check out our research.

Wearable authentication methods are advancing, but mechanical mismatch between humans and electronics remains a challenge. A researcher at the University of Illinois developed stretchable electronics, leading to electronic tattoos. One such tattoo, made by MC10, contains an antenna and sensors and could be used for authentication. Another authentication method involves a vitamin pill containing a chip with a switch and an inside-out potato battery. Once swallowed, stomach acids power the chip, creating an 18-bit ECG-like signal, turning the body into an authentication token. This pill, developed by Proteus for medical applications, is CE stamped and FDA cleared, with a dosage of up to 30 pills per day. The technology could enable authentication through touch, granting the user a "superpower."

In this video, we discuss the future of implants. It is predicted that within the next ten years, we will be able to implant technology into our clothing. Eventually, we may even consider implanting it into our brains or skin, leading to direct communication between our brains and the digital world. This fusion of the physical, digital, and biological realms is what we are witnessing.

Positive applications of this technology are vast. It offers incredible propulsion properties, allowing for movement of objects anywhere. When it enshrouds items, it can make them disappear, which has been demonstrated in laboratory settings. This concept relates to teleportation, as the items can be transported and reappear elsewhere. Additionally, it serves as an incredible energy source, potentially solving our energy and propulsion challenges.

Dimitri introduces a concept that sounds like science fiction: a hypercar without a gearbox or axles, with the motor built right into the wheel rim. The Finnish startup Donut Lab has raised €25,000,000 to develop a new generation of in-wheel motors, bringing the motor out from under the hood and integrating it directly into the wheel. This design eliminates the need for a transmission and differential, which in turn makes electric cars lighter and cheaper to produce. The described 21-inch wheel version weighs about 40 kilograms and delivers “six thirty kilowatts” and 4,300 Newton meters of torque. Donut Lab asserts that this configuration provides hypercar-level performance while maintaining or improving handling, since the motor is embedded in the wheel rather than mounted elsewhere in the drivetrain. A key claim is that the technology addresses the long-standing issue of unsprung mass, which traditionally challenges in-wheel motor systems due to the added weight and inertia at the wheel. Donut Lab emphasizes that the technology is not limited to automobiles; they see potential applications across multiple domains. The in-wheel motor concept could suit drones, ships, and even military robots, suggesting a versatile platform that can be adapted to various form factors and use cases. The speaker describes the Donut concept as “a true Donut of the future”—lightweight, powerful, and appealing to the market—portraying it as a transformative approach for propulsion in diverse vehicles and devices. In summary, the transcript presents Donut Lab’s in-wheel motor as a revolutionary propulsion solution that removes the need for traditional drivetrain components, reduces vehicle weight and cost, and claims to deliver substantial power and torque from a wheel-integrated motor. The technology is pitched as capable of enhancing handling and efficiency while enabling applications beyond cars, including aerial, maritime, and defense contexts. The financial backing of €25,000,000 underscores investor confidence in bringing this in-wheel motor technology to market.

Neuralink introduces the PRIME study, a clinical trial for a device that can transform the lives of people with paralysis. The device, a small implant in the brain, allows users to connect with loved ones, browse the web, and play games using their thoughts. No physical movement is required. The study is open to those with quadriplegia or ALS. By participating, individuals can redefine human capability and shape the future of interaction and independence. A dedicated team will support participants throughout the journey. To learn more and apply, visit the Neuralink website.

These micro robots, inspired by ants and developed by South Korean scientists, are 600 micrometers tall and communicate through magnetic fields. They can unclog tubes mimicking blocked blood vessels, potentially aiding medical treatments. The swarm can transport materials, like metal indium, to complete electrical circuits, demonstrating precise control. They work together to overcome obstacles, using centrifugal force to propel themselves. A group of 200 microrobots separated and reassembled heavy liquid metal into a smooth sphere in seconds. They can also create floating structures to carry heavy loads across water, useful for delivering medical supplies. By manipulating their movements, they can guide small organisms, like ants, for pest management or behavioral studies. Their configurations can be adjusted based on magnetic field strength, allowing them to navigate complex environments efficiently.

Neuralink is developing a brain chip, with the first recipient being a quadriplegic who will be able to control their computer and phone with their thoughts. The technology is described as "like telepathy." A subsequent Neuralink product, tentatively named "blindsight," aims to restore sight, even in individuals who have lost their eyes or optic nerve. This technology could potentially provide high-resolution sight across multiple wavelengths, including ultraviolet, infrared, and even radar. It would function via a camera that can receive photons of many wavelengths, enabling vision even in complete darkness.

We are exploring body sensor networks that can be injected into the human body to monitor health, detect tumors, and fight viruses collectively. Bio-nano scale machines, like mRNA vaccines, are being developed to mimic biological processes and communicate within the body. These artificial nano scale machines aim to replicate neurons, hormones, bacteria, and molecular motors for health monitoring and treatment.

The speaker demonstrates the stretchiness of a material by pulling on it, comparing it to a rubber band. They mention it broke but show how it can stretch like a rubber band. Another speaker points out the size difference after stretching.

Our body uses electrical signals in nerves to communicate with organs. By implanting microchips on peripheral nerves, we can read and correct messages to organs, potentially treating chronic diseases. These chips are specific, local, and only intervene when needed, ensuring patient compliance.