From Penn Statehttps://www.psu.edu/news/research/story/self-powered-biosensors-may-open-new-paths-medical-tracking-treatments/Notes from Miser:NO NEED FOR BATTERIES.
You are the battery!
They say "one day" but my friend who worked in the CRISPR lab at Cedar Sinai, Los Angeles, told me this tech was already developed five years ago. So when I heard Dr Madej talk about this I thought, "Oh. They are starting to roll it out now."
Five years ago when my friend told me about this I asked her why, if they can cure cancer and prevent all of these diseases with the tech available now, why don't they make it available to the public. She said they were just waiting for the right time to roll it all out in unison so it would all work together. She was excited because then we will no longer need doctors or hospitals because our health will be monitored 24/7 by our phone and our AI doctor will signal our body to make the drugs we need.
See the video of Michael Collins, director of the NIH, talking at DAVOS/WEF and describing this plan which I posted near the beginning of this thread. I've posted several other videos on this topic including a presentation from a MIT/Harvard doc describing the tech several years ago in the Blockchain Slavery thread.
Anyway, my friend was young, in her 20's, and had just landed this prestigious job working with CRISPR gene editing tech, right out of college after making the right connections and jumping through hoops. To her the "graphene revolution" sounded amazing! She described all of the amazing things graphene can do which I have given pages of evidence of throughout this thread. We won't need lightbulbs and cars will use it to run without fuel etc. She explained how we already can cure cancer with these health monitors and nanobots to kill cancer cells.
I thought it sounded good too until I realized the "dual use" of the technology. Dual use means for both good and for evil.
We can see that easily with the gene editing serums. They sell it as good for you and keeping you safe and caring for your health, when in reality it's the exact opposite.
To understand the significance of the evidence I'm sharing here:
What commonly conducts electricity for piezoelectronics? GRAPHENE
What makes them stretchy and biocompatible (able to be accepted by your body and fuse to your tissue permanently)? HYDROGEL
Reading the below it's not hard to imagine how "sustainability" will mean providing for your own electricity from your bodily functions! The WEF/UN sustainability internet of bodies docuмents tell us this is their plan. This means "keeping your carbon footprint to zero" because you----YOUR BODY---provides all the energy needed.
In any case, you can watch the short video at the start of the Blockchain Slavery thread to learn how bankers are monitizing the tracking and tracing of biosensors on all living things including humans. I also provided evidence in that thread for the Barcode of Life project which is funded by the Rockefeller foundation. That means barcoding all life (including humans) and tracking and tracing them.
*******************Self-powered biosensors may open up new paths to medical tracking, treatmentsAn international team of researchers led by Penn State engineers are exploring the development of stretchable self-powered biosensors that could one day lead to wearable devices that do not need to be recharged, or even sensors that are powered by the very bodily process they are designed to monitor. Credit: Penn State. Creative Commons
“In this particular review, we are looking at possible energy supply without the need for batteries and other components, so it’s of particular interest to
create these energy harvesters for self-powered devices, or ones that could also be used to charge up a battery,” said Cheng.
Cheng said the team reviewed the field from two perspectives: creating devices that can harvest energy, and developing sensors that can power themselves.
He said that an energy harvester can create energy to power other devices, while self-powered sensors can provide their own energy to serve as stand-alone devices. Cheng added that, in some cases, the motion that generates the energy for the sensor may also be the data that the sensor is trying to collect.“It can serve as a sensor directly because it can harvest energy, so it can provide the capability to monitor the motion — for example the heartbeat — or whatever the sensor is applied to,
and then it can transmit that information from the environment, or from the body, so it can be analyzed,” said Cheng.These sensors could lead to more precise healthcare and remote health opportunities, according to the researchers, who report their findings in a review article in Biosensors and Bioelectronics, currently online.
The researchers said that stretchable piezoelectric materials — which are solid substances that can accuмulate electrical charges — are critical to this development. Because human tissues are soft and constantly changing shape, the materials need to be able to flex and stretch as these tissues flex and move.
“These devices could include wearables on the skin surface,” said Cheng. “For these types of devices, we can capture information from the skin surface in the form of blood flow, heartbeat, respiration rate and similar movements that create vibrations.”
With new materials, the flexing motion of moving muscles, which typically are a hindrance for often-rigid wearable devices, could actually help create the energy that would then be captured and used as power by these biosensors.
However, according to the researchers,
biosensors may not just be relegated to the skin surface, but could one day be implanted in the body. According to Cheng, advances in material design and development in the last decade have helped researchers develop piezoelectric materials that are flexible and rugged enough that
they can withstand the environment inside the body, yet are so sensitive and efficient that they can capture and convert very minute motions, such as heartbeats and respiration.“
That’s the amazing thing about these devices, people think that these types of motion are very minimal and don’t think about harvesting this energy,” said Cheng. “It was in the past decade or two when people began to see the possibilities to generate rather large signals from these movements through the high-efficiency circuits and also to use the high-efficiency rectifying circuit, which would consume a lot of energy if it isn’t designed correctly.”
The team is also eyeing creating sensors that can
perform double duty — they can harvest energy from the very bodily processes they have been designed to monitor. For example, a sensor could harvest energy from heartbeats and also transfer the information on the heart to doctors who are monitoring a patient’s cardiovascular condition.