The Remote Control of Neural Circuits of Living Creatures.
I sent the following email to phd@rockefeller.edu today which is 7th June 2022 at 4.29 pm Irish time which is Grenwich Mean Time. Please forward this email to the Neural Research Department, Dear Neural Research Department of the Rockefeller University, New York City, I have recently discovered that your research involves remote controlling the neural circuits of living creatures. I and many of my fellow country men and country women of the Republic of Ireland are non-consensual and extremely unwilling subjects of remote controlled neural research where data is harvested from our brains and bodies and other data is being braodcast into our brains and bodies in the form of words, images, electric shock, pain, forced muscle movement and forced muscle immobilization among other unwanted experiences. We have attempted to inform the Irish police but whenever we attempt to do so our freedom is threatened by them having us forceably sent for psychiatric evaluation where we then must withdraw part of our claims lest we are incarcerated inside psychiatric hospitals if we uphold our claims. We are now afraid to ever approach the Irish police about anything in case instead of listening to us and validating our statements we instead lose all our human rights inside a psychiatric hospital where we don't even have the right to decide what is put into our bodies. By your continued work researching how to remote control the neural circuits of living creatures you are furthering the remote enslavement, the remote torture and the remote genocide of men and women throughout the world. I believe that your work is profoundly evil under the guise of doing something beneficial. Please inform the Irish police who are known as the Gardai of the scientific capabilitiy of remote controlling the neural circuits of a living creature because they are certainly not informed about it at the moment. I have had electric shocks transmitted into my body from an unknown remote location which has made me scream loudly with pain. Is this the future you wish to see for the human race, a future where others can torture us from unknown remote locations while they themselves remain anonymous cowards. I have made and uploaded approximately 240 videos of my experiences of remote controlled partial enslavement and torture to an online video platform called bitchute under the name grettafahey with no spaces between both names if you wish to check any of them out. Yours Sincerely, Gretta Fahey, Newbrook, Claremorris, Co. Mayo, Eircode F12 Y560, Republic of Ireland. My landline home phone number is 094 9360901.
| |||||||||||||
remote control of neural circuits (2)
REMOTE CONTROL OF BIOLOGICAL CIRCUITS.
ThE article found here below is available at the following online link https://www.rockefeller.edu/.../9091-radiogenetics-seeks...
NEWS > SCIENCE NEWS
‘Radiogenetics’ seeks to remotely control cells and genes
December 15, 2014
It’s the most basic of ways to find out what something does, whether it’s an unmarked circuit breaker or an unidentified gene — flip its switch and see what happens. New remote-control technology may offer biologists a powerful way to do this with cells and genes. A team at Rockefeller University and Rensselaer Polytechnic Institute is developing a system that would make it possible to remotely control biological targets in living animals — rapidly, without wires, implants or drugs.
141215_Friedman_radiogeneticsTied together: Researchers experimented with different configurations for their remote control system, and they found the best relies on an iron nanoparticle (blue), which is tethered by a protein (green) to an ion channel (red). Above, all three appear within cell membranes.
Today (December 15) in the journal Nature Medicine, the team describes successfully using electromagnetic waves to turn on insulin production to lower blood sugar in diabetic mice. Their system couples a natural iron storage particle, ferritin, to activate an ion channel called TRPV1 such that when the metal particle is exposed to a radio wave or magnetic field it opens the channel, leading to the activation of an insulin producing gene. Together, the two proteins act as a nano-machine that can be used to trigger gene expression in cells.
“The method allows one to wirelessly control the expression of genes in a living animal and could potentially be used for conditions like hemophilia to control the production of a missing protein. Two key attributes are that the system is genetically encoded and can activate cells remotely and quickly,” says Jeffrey Friedman, Marilyn M. Simpson Professor head of the Laboratory of Molecular Genetics at Rockefeller. “We are now exploring whether the method can also be used to control neural activity as a means for noninvasively modulating the activity of neural circuits.” Friedman and his Rensselaer colleague Jonathan S. Dordick were co-senior researchers on the project.
Other techniques exist for remotely controlling the activity of cells or the expression of genes in living animals. But these have limitations. Systems that use light as an on/off signal require permanent implants or are only effective close to the skin, and those that rely on drugs can be slow to switch on and off.
The new system, dubbed radiogenetics, uses a signal, in this case low-frequency radio waves or a magnetic field, to heat or move ferritin particles. They, in turn, prompt the opening of TRPV1, which is situated in the membrane surrounding the cell. Calcium ions then travel through the channel, switching on a synthetic piece of DNA the scientists developed to turn on the production of a downstream gene, which in this study was the insulin gene.
In an earlier study, the researchers used only radio waves as the ‘on’ signal, but in the current study, they also tested out a related signal – a magnetic field –to activate insulin production. They found it had a similar effect as the radio waves.
“The use of a radiofrequency-driven magnetic field is a big advance in remote gene expression because it is non-invasive and easily adaptable,” says Dordick, who is Howard P. Isermann Professor of Chemical and Biological Engineering and vice president of research at Rensselaer. “You don’t have to insert anything — no wires, no light systems — the genes are introduced through gene therapy. You could have a wearable device that provides a magnetic field to certain parts of the body and it might be used therapeutically for many diseases, including neurodegenerative diseases. It’s limitless at this point.”
The choice to look at insulin production was driven by the equipment they used to generate the radio waves and magnetic fields. Because the coil that generates these signals is currently small i.e; only three centimeters in diameter, it was necessary to anesthetize the mice to keep them still. Since anesthesia can repress the production of insulin, the hormone that reduces blood sugar, Stanley and her colleagues designed the genetically encoded system to replace the insulin that is normally reduced by anesthesia in mice.
“Ferritin, a protein-coated iron storage molecule, is normally found throughout the mouse and human body, but in our experiments, we modified it, placing the ferritin particles in different positions to see if we could improve our results,” says co-first author Sarah Stanley, a senior research associate in Friedman’s lab. “We found tethering the ferritin to the channel to be most effective.”
The team’s positive results suggest other applications for the system. In late September, Stanley received a first-round BRAIN grant from the ambitious federal initiative seeking to create a dynamic map of the brain in action. Stanley and colleagues plan to adapt this system to switch neurons on and off, and so examine their roles within the brain.
“In this current study, we’ve shown that by opening the TRPV1 channel to allow calcium ions to enter the cell, we can turn on a gene. Since neurons can be depolarized by calcium and other positively charged ions, such as those the TRPV1 channel controls, we hope that this system may be effective at regulating neural activity.”
141215_Friedman_NatureMedicine Nature Medicine online: December 15, 2014
Remote regulation of glucose homeostasis in mice using genetically encoded nanoparticles
Sarah A Stanley, Jeremy Sauer, Ravi S Kane, Jonathan S Dordick and Jeffrey M Friedman
