PROOF: Bill Gates Putting Implantable Chips In Vaccines

PROOF: Bill Gates Putting Implantable Chips In Vaccines

April 12, 2021

The Alex Jones Show

Alex Jones breaks down the undeniable proof that Bill Gates is funding implantable chip technology for vaccines.

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Storing Medical Information Below The Skin's Surface

Dec. 18, 2019

Massachusetts Institute of Technology

Specialized dye, delivered along with a vaccine, could enable “on-patient” storage of vaccination history.

MIT researchers have now developed a novel way to record a patient’s vaccination history: storing the data in a pattern of dye, invisible to the naked eye, that is delivered under the skin at the same time as the vaccine.

“In areas where paper vaccination cards are often lost or do not exist at all, and electronic databases are unheard of, this technology could enable the rapid and anonymous detection of patient vaccination history to ensure that every child is vaccinated,” says Kevin McHugh, a former MIT postdoc who is now an assistant professor of bioengineering at Rice University.

The researchers showed that their new dye, which consists of nanocrystals called quantum dots, can remain for at least five years under the skin, where it emits near-infrared light that can be detected by a specially equipped smartphone.

The research was funded by the Bill and Melinda Gates Foundation and the Koch Institute Support (core) Grant from the National Cancer Institute.

https://news.mit.edu/2019/storing-vaccine-history-skin-1218

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Injectable Body Sensors Take Personal Chemistry to a Cell Phone Closer to Reality

March 19, 2018

"While fitness trackers and other wearables provide insights into our heart rate, respiration and other physical measures, they don't provide information on the most important aspect of our health: our body's chemistry," explained Natalie Wisniewski, Ph.D. "Based on our ongoing studies, tissue-integrated sensor technology has the potential to enable wearables to live up to the promise of personalized medicine, revolutionizing the management of health in wellness and disease." Dr. Wisniewski, who leads the team of biosensor developers, is the chief technology officer and co-founder of Profusa Inc., a San Francisco Bay Area-based life science company.

Conventional sensors, such as those found in continuous glucose monitors, have a sensing elec­trode wire that penetrates the skin to measure a target chemical in the fluid that surrounds cells. But because the body "sees" the electrode as foreign material, it needs to be removed and replaced within several days at a different location to avoid the effects of inflammation and scar tissue that eventually prevents the electrode from functioning accurately.

The team at Profusa is developing a family of tiny biosensors composed of a tissue-like hydrogel, similar to a soft contact lens, that are painlessly placed under the skin with a single injection. Rather than being isolated from the body, the biosensors work fully integrated within the body's tissue — without any metal device or electronics, thereby overcoming the body's attempts to reject it. To date, the injected biosensors have functioned for as long as four years.

Smaller than a grain of rice, each biosensor is a flexible fiber about 5 mm long and half a millimeter wide, comprised of a porous scaffold that induces capillary and cellular ingrowth from surrounding tissue. The hydrogel is linked to light-emitting fluorescent molecules that continuously signal in proportion to the concentration of a body chemical, such as oxygen, glucose, or other biomolecule of interest.

Conventional sensors, such as those found in continuous glucose monitors, have a sensing elec­trode wire that penetrates the skin to measure a target chemical in the fluid that surrounds cells. But because the body "sees" the electrode as foreign material, it needs to be removed and replaced within several days at a different location to avoid the effects of inflammation and scar tissue that eventually prevents the electrode from functioning accurately.

The team at Profusa is developing a family of tiny biosensors composed of a tissue-like hydrogel, similar to a soft contact lens, that are painlessly placed under the skin with a single injection. Rather than being isolated from the body, the biosensors work fully integrated within the body's tissue — without any metal device or electronics, thereby overcoming the body's attempts to reject it. To date, the injected biosensors have functioned for as long as four years.

Smaller than a grain of rice, each biosensor is a flexible fiber about 5 mm long and half a millimeter wide, comprised of a porous scaffold that induces capillary and cellular ingrowth from surrounding tissue. The hydrogel is linked to light-emitting fluorescent molecules that continuously signal in proportion to the concentration of a body chemical, such as oxygen, glucose, or other biomolecule of interest.