A Stockholm, Sweden-based startup company Epicenter showcased their microchip technology that can be embedded in your arm and display your COVID-19 vaccination status.Stockholm, Sweden-based startup company Epicenter showcased their microchip technology that can be embedded in your arm and display your COVID-19 vaccination status. |
Vaccine Passport Chip Implants Are Real, Alex Jones Right AGAIN As More Cities Declare Vax Mandates
https://www.youtube.com/watch?v=YRjKdziEewc . Source: https://www.youtube.com/watch?v=YRjKdziEewc Tim Pool https://www.youtube.com/user/Timcasts Vaccine Passport Chip Implants Are Real, Alex Jones Right AGAIN As More Cities Declare Vax Mandates. Democrats in Chicago, Boston, and Washington DC announce vaccine mandates starting soon. While Republican states have refused vaccine mandates, mask mandates, and lockdowns Democrat states seem to enjoy them and have no problem This is going to cause geographical polarization alongside ideological which could escalate the culture war to something much worse. According to a viral video, called a subdermal microchip keeps your vaccination record has been verified, says the caption of the video posted to twitter by South China Morning Post. Remember when we were told it was a conspiracy theory that they would use micro microchips to track your vaccine status now we're here and they're saying it's all true 1. https://www.washingtonexaminer.com/news/watch-company-showcases-microchip-that-can-display-covid-vaccine-passport-status-under-skin 2. https://www.scmp.com/tech/tech-trends/article/3129809/pentagon-team-reveals-covid-19-detecting-chip-can-be-implanted 3, https://www.msn.com/en-us/money/other/swedish-company-s-microchip-could-be-used-to-display-covid-19-vaccination-status/ar-AAS29mr 4. https://www.msn.com/en-us/money/other/swedish-company-s-microchip-could-be-used-to-display-covid-19-vaccination-status/ar-AAS29mr |
OBJECTIVE
What doesn't kill you, makes you stronger: Injections of synthetic Nano material; every time you were broken the nanobots replaced the ribosomes changing your DNA and re-engineering your new synthetic tissue.
What doesn't kill you, makes you stronger: Injections of synthetic Nano material; every time you were broken the nanobots replaced the ribosomes changing your DNA and re-engineering your new synthetic tissue.
When Shit Hits The Fan
- Will Technology Destroy Us? - Documentary www.youtube.com/watch?v=pRPpFqufyOo This documentary is a research project in the course New Technology at Reykjavík University 2015. The documentary tries to answer the question if technology will destroy the human race and life on the planet earth. |
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Ribosome
Ribosomes are macromolecular machines, found within all living cells, that perform biological protein synthesis. Ribosomes link amino acids together in the order specified by the codons of messenger RNA molecules to form polypeptide chains. Ribosomes consist of two major components: the small and large ribosomal subunits. Wikipedia mRNA Translation (www.youtube.com/watch?v=TfYf_rPWUdY) |
Medical Nanotechnology and Nanomedicine
authorzilla.com/6mXvY/medical-nanotechnology-and-nanomedicine.html |
Frequencies (Nano Science and Technology - W.L.COLLINS Project Portfolio (weebly.com))
John concierge from Pennsylvania he was looking for a way to fight cancer cells in the human body one night he had the idea of injecting gold nanoparticles and then exposing them to radio frequencies. The radio waves are said to heat the diseased cells and kill them without harming the healthy ones.
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Cellular Surgeons: The New Era of Nanomedicine
https://www.youtube.com/watch?v=FzFY5ms3AUc 49:00 mim.sec into video NANOBOT |
Nanorobotics
Nanorobotics is an emerging technology field creating machines or robots whose components are at or near the scale of a nanometer. More specifically, nanorobotics refers to the nanotechnology engineering discipline of designing and building nanorobots, with devices ranging in size from 0.1 to 10 micrometres and constructed of nanoscale or molecular components. en.wikipedia.org/wiki/Nanorobotics |
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Artificial Intelligence was coined in 1955 to introduce a new discipline of computer science. It is rapidly and radically changing the various areas of our daily lives as the market for AI technologies is demanding and flourishing. There is a significant race between many start-ups and internet giants to acquire them. In this article we will discuss Top 15 Hot Artificial Intelligence technologies that one should know. Following pointers will be covered in this article,
A.rtificial I.mmortality
A.rtificial I.mmortality asks the question: If you were able to create an immortal version of yourself, would you? The film explores the latest advancements in AI, robotics and biotech with visionaries who argue for a new age of post biological life. As scientists point us toward a world where humans and machines merge, we have to ask ourselves will AI be the best, or the last thing we ever do? Features Deepak Chopra, who has created his own A.I. mind twin.
A.rtificial I.mmortality - Northernstars.ca https://www.northernstars.ca/a-rtificial-i-mmortality/ ALT: vimeo.com/558287325 |
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09:42 min/sec RECREATING PANDEMICS THROUGH GENOME TECHNOLOHY
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TECHNOLOGY Ray Kurzweil The Singularity Is Near www.kurzweilai.net/the-singularity-is-near Watch how change has taken place since 2017. Change is not a constant it's actually getting faster and faster. It's gonna get to a point where change is so fast that we won't be able to follow it unless we actually enhance our own intelligence. We refer to that as the singularity. 25:08 longevity escape velocity 30:26 medical Nano robots & 31:38 records all the traffic in your brain 30:48 artificial blood cells 35:16 gray goo scenario |
Contributions ~ https://en.wikipedia.org/wiki/Charles_M._Lieber
Nanomaterials synthesis. In his early work Lieber articulated the motivation for pursuing designed growth of nanometer-diameter wires in which composition, size, structure and morphology could be controlled over a wide range,[25] and outlined a general method for the first controlled synthesis of free-standing single-crystal semiconductor nanowires,[26][27] providing the groundwork for predictable growth of nanowires of virtually any elements and compounds in the periodic table. He proposed and demonstrated a general concept for the growth of nanoscale axial heterostructures[28] and the growth of nanowire superlattices with new photonic and electronic properties,[29] the basis of intensive efforts today in nanowire photonics and electronics. Nanostructure characterization. Lieber developed applications of scanning probe microscopies that could provide direct experimental measurement of the electrical and mechanical properties of individual carbon nanotubes and nanowires.[30][31] This work showed that semiconductor nanowires with controlled electrical properties can be synthesized, providing electronically tunable functional nanoscale building blocks for device assembly. Additionally, Lieber invented chemical force microscopy to characterize the chemical properties of materials surfaces with nanometer resolution.[32] |
Nanoelectronics and nanophotonics. Lieber has used quantum-confined core/shell nanowire heterostructures to demonstrate ballistic transport,[33] the superconducting proximity effect,[34] and quantum transport.[35] Other examples of functional nanoscale electronic and optoelectronic devices include nanoscale electrically driven lasers using single nanowires as active nanoscale cavities,[36] carbon nanotube nanotweezers,[37] nanotube-based ultrahigh-density electromechanical memory,[38] an all-inorganic fully integrated nanoscale photovoltaic cell[39] and functional logic devices and simple computational circuits using assembled semiconductor nanowires.[40] These concepts led to the integration of nanowires on the Intel roadmap, and their current top-down implementation of these structures.[41]
Nanostructure assembly and computing. Lieber has originated a number of approaches for parallel and scalable of assembly of nanowire and nanotube building blocks. The development of fluidic-directed assembly[42] and subsequent large-scale assembly of electrically addressable parallel and crossed nanowire arrays was cited as one of the Breakthroughs of 2001 by Science.[43] He also developed a lithography-free approach to bridging the macro-to-nano scale gap using modulation-doped semiconductor nanowires.[44][45] Lieber recently introduced the assembly concept ‘nanocombing,’[46] to create a programmable nanowire logic tile[47] and the first stand-alone nanocomputer.[48]
Nanoelectronics for biology and medicine. Lieber demonstrated the first direct electrical detection of proteins,[49] selective electrical sensing of individual viruses[50] and multiplexed detection of cancer marker proteins and tumor enzyme activity.[51] More recently, Lieber demonstrated a general approach to overcome the Debye screening that makes these measurements challenging in physiological conditions,[52] overcoming the limitations of sensing with silicon nanowire field-effect devices and opening the way to their use in diagnostic healthcare applications. Lieber has also developed nanoelectronic devices for cell/tissue electrophysiology, showing that electrical activity and action potential propagation can be recorded from cultured cardiac cells with high resolution.[53] Most recently, Lieber realized 3D nanoscale transistors[54][55] in which the active transistor is separated from the connections to the outside world. His nanotechnology-enabled 3D cellular probes have shown point-like resolution in detection of single-molecules, intracellular function and even photons.[56]
Nanoelectronics and brain science. The development of nanoelectronics-enabled cellular tools underpins Lieber's views[57] on transforming electrical recording and modulation of neuronal activity in brain science. Examples of this work include the integration of arrays of nanowire transistors with neurons at the scale that the brain is wired biologically,[58] mapping functional activity in acute brain slices with high spatiotemporal resolution[59] and a 3D structure capable of interfacing with complex neural networks.[60] He developed macroporous 3D sensor arrays and synthetic tissue scaffold to mimic the structure of natural tissue, and for the first time generated synthetic tissues that can be innervated in 3D, showing that it is possible to produce interpenetrating 3D electronic-neural networks following cell culture.[61] Lieber's current work focuses on integrating electronics in a minimally/non-invasive manner within the central nervous system.[62][63] Most recently, he has demonstrated that this macroporous electronics can be injected by syringe to position devices in a chosen region of the brain.[64] Chronic histology and multiplexed recording studies demonstrate minimal immune response and noninvasive integration of the injectable electronics with neuronal circuitry.[64][65][66] Reduced scarring may explain the mesh electronics’ demonstrated recording stability on time scales of up to a year.[67][68] This concept of electronics integration with the brain as a nanotechnological tool potentially capable of treating neurological and neurodegenerative diseases, stroke and traumatic injury has drawn attention from a number of media sources. Scientific American named injectable electronics one of 2015's top ten world changing ideas.[69] Chemical & Engineering News called it “the most notable chemistry research advance of 2015.”[70]
Nanostructure assembly and computing. Lieber has originated a number of approaches for parallel and scalable of assembly of nanowire and nanotube building blocks. The development of fluidic-directed assembly[42] and subsequent large-scale assembly of electrically addressable parallel and crossed nanowire arrays was cited as one of the Breakthroughs of 2001 by Science.[43] He also developed a lithography-free approach to bridging the macro-to-nano scale gap using modulation-doped semiconductor nanowires.[44][45] Lieber recently introduced the assembly concept ‘nanocombing,’[46] to create a programmable nanowire logic tile[47] and the first stand-alone nanocomputer.[48]
Nanoelectronics for biology and medicine. Lieber demonstrated the first direct electrical detection of proteins,[49] selective electrical sensing of individual viruses[50] and multiplexed detection of cancer marker proteins and tumor enzyme activity.[51] More recently, Lieber demonstrated a general approach to overcome the Debye screening that makes these measurements challenging in physiological conditions,[52] overcoming the limitations of sensing with silicon nanowire field-effect devices and opening the way to their use in diagnostic healthcare applications. Lieber has also developed nanoelectronic devices for cell/tissue electrophysiology, showing that electrical activity and action potential propagation can be recorded from cultured cardiac cells with high resolution.[53] Most recently, Lieber realized 3D nanoscale transistors[54][55] in which the active transistor is separated from the connections to the outside world. His nanotechnology-enabled 3D cellular probes have shown point-like resolution in detection of single-molecules, intracellular function and even photons.[56]
Nanoelectronics and brain science. The development of nanoelectronics-enabled cellular tools underpins Lieber's views[57] on transforming electrical recording and modulation of neuronal activity in brain science. Examples of this work include the integration of arrays of nanowire transistors with neurons at the scale that the brain is wired biologically,[58] mapping functional activity in acute brain slices with high spatiotemporal resolution[59] and a 3D structure capable of interfacing with complex neural networks.[60] He developed macroporous 3D sensor arrays and synthetic tissue scaffold to mimic the structure of natural tissue, and for the first time generated synthetic tissues that can be innervated in 3D, showing that it is possible to produce interpenetrating 3D electronic-neural networks following cell culture.[61] Lieber's current work focuses on integrating electronics in a minimally/non-invasive manner within the central nervous system.[62][63] Most recently, he has demonstrated that this macroporous electronics can be injected by syringe to position devices in a chosen region of the brain.[64] Chronic histology and multiplexed recording studies demonstrate minimal immune response and noninvasive integration of the injectable electronics with neuronal circuitry.[64][65][66] Reduced scarring may explain the mesh electronics’ demonstrated recording stability on time scales of up to a year.[67][68] This concept of electronics integration with the brain as a nanotechnological tool potentially capable of treating neurological and neurodegenerative diseases, stroke and traumatic injury has drawn attention from a number of media sources. Scientific American named injectable electronics one of 2015's top ten world changing ideas.[69] Chemical & Engineering News called it “the most notable chemistry research advance of 2015.”[70]
Hundreds of doctors and scientists have studied vaccines, their ingredients, and the physiological mechanisms affected by those ingredients. The following criteria, and the rationale for these criteria, are the results of their work. Vaccine industry spokespeople say vaccines are safe and effective. But are they? https://childrenshealthdefense.org/.../what-does-a-safe... Image: Children’s Health Defense’s https://childrenshealthdefense.org/wp-content/uploads/what-does-a-safe-and-effective-vaccine-look-like.pdf?fbclid=IwAR1KkKSmh5TueZ8IQdLdIFWpTm2y6gietafvCQeI6CQ4XAg--o1kS4R88xA |
Tactile Defensiveness, or touch sensitivity
Individuals who are sensitive to touch may respond by avoiding sensations or having a bigger reaction than would be expected by others. For example, refusing to wear socks with seams because the seam or texture of the sock irritates their skin. To date, there is no confirmed cause of tactile sensitivity but it is frequently reported by autistic individuals. Touch pressure and proprioceptive sensory input can help to reduce sensitivity to touch.
If you want to understand more: ,www.griffinot.com/what-is-tactile-defensiveness/
If you want to understand more: ,www.griffinot.com/what-is-tactile-defensiveness/
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2 Broad Categories of Cervical Spondylomyelopathy
Osseous-Associated
Osseous-Associated Cervical SPondylomyelopathy Multifactorial process w/ vertebral malformation & canal stenosis Also osteoarthritis, synovial cysts & ligamentous hypertrophy Osseous-Associated Cervical SPondylomyelopathy: Signalment Young large & giant breed dogs Esp. Great Danes Mean age is 3.8 years but can present as early as a few months Osseous-Associated Cervical Spondylomyelopathy: Pathophys Predominantly dorsolateral compression from articular osseous & soft tissue changes Osseous-Associated Cervical SPondylomyelopathy: Clinical Signs Usually chronic & progressive Cervical hyperesthesia but presenting complaint is usually abnormal "2 engine gait" w/ LMN dz signs on thoracic limbs & UMN dz on pelvic limbs Upper Motor Neuron vs. Lower Motor Neuron Disease https://www.cmvpr.org/wp-content/uploads/2019/04/1.-Upper-Motor-Neuron-vs.-Lower-Motor-Neuron-Disease.pdf |
Disc-Associated Disc-Associated Cervical Spondylomyelopathy: Signalment Older to large breed dogs Esp. Dobermans Most present after 3 years w/ mean age of 6.8 years Disc-Associated Cervical Spondylomyelopathy: Pathophys Congenital stenosis, Type II disc disease, hypertrophy of soft tissue structures over time = predominantly ventral compression from disc protrusion Overall similar to Type II disc disease but there is a lot more happening than just a disc protrusion Main lesions usually at C5-C6 Disc-Associated Cervical Spondylomyelopathy: Clinical Signs Chronic & progressive Cervical hyperesthesia + toe-in posture Disc-Associated Cervical Spondylomyelopathy: Medical Management Rehab + controlled activity/lifestyle Coticosteroids +/- analgesiabe |
Nano Science and nano technology in Architecture, Sammar Zain El Abdin Moh. Allam
Abstract
applications like Pharmacy, electronics, medicine, and materials.The task for architects today, is to seize hold of new technologies, judiciously apply them to buildings, delight in the symbolic potential, and endow them with poetic expression. Nanomaterials has played a significant role into many fields like pharmacy, electronics, medicine, and has found its way into architecture materials. Architects will not build with the same conventional glass, concrete, bricks, instead new nanotech materials that will serve future needs. Nevertheless, sustainable and ecological ones will come to field. |
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Healthcare Companies
Medtronic has acquired China Kanghui, the medical device maker, for $816 million. The purchase increases Medtronic's presence in China for its portfolio of medical devices, which ranges from pacemakers and stents to spinal implants and surgical instruments. Healthcare companies in four different categories have been favored recently by investment analysts, due to high-liquid cash positions that allow them to fund research and development strategies. They are:
Nanosphere, maker and marketer of the Verigene System that enables genomic and protein testing on a single platform., a biopharmaceutical company that develops medicines for the treatment of inflammatory diseases
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Derma Sciences, a medical technology company
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Trinity Biotech, which manufactures and sells self-diagnostic test kits
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Nanosphere, maker and marketer of the Verigene System that enables genomic and protein testing on a single platform.
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Aurobindo Pharma has received tentative approval from the FDA for its antidiabetic tablets. The new tablets are the generic equivalent of Actoplus Met Tablets. They are indicated as an adjunct to diet and exercise to improve glycemic control in adults with tye-2 diabetes.
This blood test flags variations that might make individuals unusually sensitive to particular drugs or even mutations that the signal heightened, risk for disease, in less than two hours after drawing your blood. The results are in it turns out that the test has some interesting news for me about my sensitivity to a blood thinning drug called warfarin or coumadin it's commonly prescribed to stroke and cardiac patients it's a potentially life-saving drug but if the dosage is wrong it can cause fatal bleeding so what's my warfarin dosage? They call it double heats – so you have two genes that are mutated and therefore you're very sensitive to warfarin and your calculated dose is 2.7 milligrams.
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Nanotechnology Of The Future [Full Documentary] https://www.youtube.com/watch?v=2RCDMQMYxBk |
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The Promise of Human Regeneration: Forever Young
The Promise of Human Regeneration: Forever Young - YouTube https://www.youtube.com/watch?v=e0vKOYQUmgg 03:02 BRIAN HEARD ABOUT AN EXPERIMENTAL PROCEDURE AT THE UNIVERSITY OF PITTSBURGH THAT USESAN EXTRACELLULAR MATRIX TO REGROW DAMAGED MUSCLE TISSUE.A YEAR AFTER TREATMENT IN 2013, THINGS WERE REMARKABLY DIFFERENT WITH HIS ARM. 20:00 So this incredibly simple message months ago which was, change your electrical potential and this entire limb has grown back and it’s the right shape and it stops when it’s done. |
Transhumanism
The New American Magazine posted a video to playlist Behind the Deep State With Alex Newman. December 6, 2021 · Follow Deep State maniacs and minions are openly working on technology that will hook human brains up to super computers and artificial intelligence, warns The New American magazine Senior Editor Alex Newman in this episode of Behind The Deep State. From installing electrodes in the brain to using genetically engineered viruses to activate certain areas of the brain, the research has been going on for decades. Elon Musk's "neuralink" directly connects brains to computers and is already working in animals. Next will be humans. Alex also discusses Mark Zuckerberg's so-called Metaverse and "trans-species individuals" who claim not to be fully human because they have "upgraded" themselves. And the Deep State is making great progress in this drive to merge the human brain and mind with technology. The end goal is total tyranny. |