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Artificial cells and molecules can be programmed and injected into the body to target health issues like heart disease, cancer, diabetes, Alzheimer's, epilepsy, and Crohn's disease. These nano machines can extend lifespan by cooperating to attack specific areas. Interdisciplinary teams of biologists, programmers, and medical professionals are needed to design and code these devices effectively.

We are developing non-scale machines that mimic bacteria and aim to enhance life longevity through genetic engineering. The concept is similar to the mRNA technology used in COVID vaccines. Our long-term goal is to create genetically engineered human cells, which is more challenging than manipulating bacterial cells. While some may view this as unethical, our focus is on the potential benefits. We utilize a lentiviral vector, a type of virus, to introduce new DNA into cardiac cells, enabling them to combat unhealthy cells. Welcome to this institute event; I’m Maurice Pomerantz, the Executive Director.

Recent developments have shown that nanoparticle materials can be stabilized for distribution. These materials exist on a very small scale, smaller than a cell, and can be engineered to have specific properties. They can self-aggregate and target specific areas based on their biology and chemical sensitivity. Now, there is a new advancement where nanomaterials can be aerosolized, creating controllable nano-scale robotic units that can penetrate even the most robust biochemical filters. These units can enter the body through various membranes and can affect the brain's vascular system or directly diffuse into the brain. These materials can be transformed into weapons and are almost impossible to detect, making it difficult to trace their origin. The speaker demonstrates that a small amount of nanomaterials could potentially affect a large population without the need for a large weapon. They suggest using unmanned aerial or ground delivery systems like drones or insects for dispersal.

Speaker 0 describes a theory they’re exploring: every vaccine examined, and the patents and testimony from the Department of Energy, point to a 500,000-strong collection of bioweapons categories, including plague, HIV, anthrax. They claim all these bacteria and yeasts have been mutated and converted into a “hybrid gamma irradiated” form, advanced and radioactive, and that these are entering humanity. They say, regarding a nuclear stockpile, humanity itself becomes the host of these radioactive materials, since they are digital and can be activated to detonate a mass casualty event. Speaker 1 clarifies by restating the concern: they can create a pandemic at any moment by activating materials that have infiltrated our bodies. Speaker 0 adds that they have become involved in helping families legally; their law firm supports families because some school districts have become worse than during COVID, even though childhood vaccines are still largely recommended federally. They claim school districts and scientists are desperate to get these materials into children, with Catholic schools allegedly no longer honoring religious or medical exemptions. They describe children with severe reactions and contraindications being denied entry to schools, faced with truancy threats or expulsion. They insist there is nothing healing about these vaccines and call it an infiltration system necessary for AI to function properly. Speaker 1 mentions the U.S. allegedly cutting ties with the WHO, but says research by John Fleetwood shows the U.S. maintains relationships relating to vaccines and influenza, with substantial taxpayer funding. They assert that with a digital ID, one’s bank account can be cut off if they don’t get certain vaccines or comply to maintain the digital ID, arguing the agenda has continued and accelerated with AI. Speaker 0 adds that the WHO remains a standing organization but has been rebranded, and emphasizes that the United States is front and center in partnerships with the WHO. Speaker 1 introduces Biomems (biomedical microelectromechanical systems) as a subset of MEMS used in biomedical research and medical devices, noting that this has existed for years. They describe sensors under the skin that transmit data to pharmaceuticals or governments, not just pacemakers. They reference Albert Bourla, who stated that a pill has been designed to track compliance. Speaker 0 confirms: “They tell us what they're doing.”

Scientists have discovered electromagnetic devices in vials that self-assemble when exposed to electromagnetic frequencies from smartphones or towers. These devices, made of Graphene Oxide, can mimic cells and proteins to build structures in the body. Graphene Oxide, combined with biological proteins, creates transducers that alter the body's electromagnetic field. mRNA is described as temporary instructions for cells to produce proteins, with DNA as the storage. This technology is likened to an operating system on Moderna's website.

Researchers at MIT have developed tiny micro robots, comparable in size to a human egg cell, made of electronic circuits and minute particles. These robots can swim through blood vessels, sense their environment, store data, and perform computational tasks. They are self-powered, requiring no external power source or batteries, and can be guided to hard-to-reach areas in the body, enhancing drug delivery systems. This technology may enable drugs to bypass the blood-brain barrier, opening new possibilities for treatment.

MIT researchers have created cell-sized microrobots that can swim between blood vessels. These robots, potentially the smallest yet, can sense their environment, store data, and perform computations. The microrobots, about the size of a human egg cell, consist of tiny 3D-printed electronic circuits that react to electronic or magnetic signals. They are self-powered, requiring no external power source or batteries. These robots can be guided to areas inaccessible to standard drugs, adding a new dimension to drug delivery systems. This delivery method may enable drugs to cross the blood-brain barrier.

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.

Scientists have created xenobots, the world's first living robots, which can now reproduce. Developed from frog cells, these machines are less than a millimeter wide and can move towards a target and self-heal. Xenobots are a new class of programmable organisms, neither traditional robots nor existing animal species. Composed of approximately 3,000 cells, xenobots form a sphere and replicate. An AI-guided evolutionary algorithm discovered body shapes that improved replication. Researchers state that xenobots are confined to the lab, biodegradable, and easily controlled. Currently, they help scientists understand cell cooperation in forming complex organisms. Future applications include cleaning microplastics from oceans and targeted drug delivery. Xenobots can be created using a patient's own cells, avoiding immune system attacks. Personalized xenobots could remove plaque from arteries and, with bioengineering, find and treat diseases.

MIT researchers have created cell-sized microrobots that can swim between blood vessels. These robots, potentially the smallest yet, can sense their environment, store data, and perform computations. The microrobots, about the size of a human egg cell, consist of tiny 3D-printed electronic circuits that react to electronic or magnetic signals. They are self-powered, requiring no external power source or batteries. These robots can be guided to areas inaccessible to standard drugs, enhancing drug delivery systems. This delivery method may enable drugs to cross the blood-brain barrier.

The speaker discusses body sensor networks that can be injected into the human body to monitor health, detect tumors, and fight viruses. They mention bio nanoscale machines and mRNA vaccines as examples of this technology. They aim to mimic biological processes in the body by creating artificial nano scale machines like bacteria and molecular motors. Translation: The speaker talks about using body sensor networks to monitor health by injecting them into the body. They mention bio nanoscale machines and mRNA vaccines as examples of this technology. They aim to mimic biological processes in the body by creating artificial nano scale machines like bacteria and molecular motors.

Researchers at MIT have developed tiny micro robots, comparable in size to a human egg cell, that can navigate through blood vessels. These robots are made of 3D-printed electronic circuits and can sense their environment, store data, and perform computational tasks. They are self-powered, eliminating the need for external power sources or batteries. This innovative technology allows for targeted drug delivery to areas of the body that traditional methods cannot reach, potentially enabling drugs to cross the blood-brain barrier.

We can now stabilize nano particulate matter for distribution. This matter is extremely small, smaller than a cell, and can be controlled to aggregate in specific areas based on biological or chemical sensitivity. Recently, it was discovered that nanomaterials can be aerosolized, creating a nano swarm that can penetrate various membranes, including the brain. These materials can be weaponized and are difficult to detect. Only a small amount is needed to affect a large number of people, and delivery can be done through drones or other unmanned devices.

Bionano scale machines are being developed for injecting into the body and monitoring health. This is progressing well, as seen with COVID vaccines. mRNAs are nanoscale machines that are programmed and injected. These nanoscale technologies will be part of 7G and beyond.

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.

The telecom and health industries are developing the Internet of bionanothinks in the cardiovascular system. This network consists of nanodevices controlled externally, containing sensors and actuators in the body.

You are looking at a cell sized microrobot. These microrobots made of electronic circuits coupled to minute particles are so small that they can swim in between blood vessels. Researchers at MIT have created what may be the smallest robots yet. These bots can sense their environment, store data, and even carry out computational tasks. These robots, which are about the size of a human egg cell, consist of tiny electronic circuits that have been three d printed and react to electronic or magnetic signals. These tiny robots are self powered and require no external power source or even internal batteries. They can be guided into areas of the body that standard drugs cannot reach, adding a whole new level to drug delivery systems. It may be possible now using this delivery method to bring drugs past the blood brain barrier. Follow me for more info like this.

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.

Evil Rockefellas and their associates have different plans for humans. The blood brain barrier, made up of endothelial cells, controls what substances can enter the brain. While iron and glucose can pass through, most medicines are rejected as if they were toxins. Scientists are working on ways to bypass this barrier. One method involves disguising medicine as substances that the barrier allows, such as nanoparticles coated in proteins similar to those that transport ions. Another approach is using harmless viruses to exploit their ability to enter cells. However, some question whether toxic nanoparticles caused health issues in the first place.

Recently, I shared a briefing from the European Parliament discussing smart bodies for smart cities and the Internet of Bio Nano Things. On page 7, BJ Torg's work is cited, highlighting injectable nano sensor technology for seamless human body connectivity. These sensors are designed for use both on and within the human body. BJ Onutolk collaborates with Professor Ian F. Akiris from the International Telecommunications Union on this topic. The focus is on graphene-based, injectable intra-body nano sensor networks. This emerging nanotechnology allows for the creation of devices that can sense, process, and communicate at the nanoscale. The paper also presents a concept for localizing and tracking bionano sensors within the bloodstream.

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.

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.

The speaker examined a Pfizer BioNTech COVID-19 injection under 100x magnification and observed extreme activity with blinking lights, which they identified as nano and micro robots communicating via light signals. These robots collaborate to self-assemble larger structures identified as microchips emitting a MAC address. The speaker claims to have found 54 undeclared chemical elements, including fluorescent Graphene Oxide, in COVID-19 injections and documented fluorescence in the blood. They state that childhood vaccinations contain the same self-assembling nanotechnology. Analysis of embalmed blood from a vaccinated individual who had been deceased for 8 months revealed similar filaments and micelles filled with blinking lights, exhibiting ongoing self-assembly.