3D-scanning every cell in human body (Robocentric biotech research plan)
Subscribe: Apple Podcasts | Google Podcasts | Spotify | RSS | More
My view is that advancing medical biotech and human longevity biotech requires detecting, scanning, recording, and publishing the location and type of every single cell in the human body; a technology to do so doesn’t exist yet, and I aim to create and commercialize such a technology.
I’ve no educational background in biology and biotech, so I need to first learn the existing available measurement technologies and techniques in biology and biotech, and develop the necessary technology for detecting, scanning, and recording every single cell in the human body, all 37 trillion of them, in a fully automated fashion.
A quick advertisement before I continue on this topic. You can invest in my startup company with as little as US$100, for supporting advancing AI, robotics, biotech, and nuclear-fusion powered outer space tech. Visit Robocentric.com/Investors to invest in my startup.
I’ve a multidecadal commitment to advancing AI, robotics, biotech, and nuclear-fusion powered outer space tech. To learn more about my cause, check out my books, which are available at Robocentric.com/Checkout, Amazon, Apple Books, Spotify, and other online audiobook retailers. Now, back to the main content.
Also, I have a self-imposed cost limitation: I want to be able to detect, scan, record, and publish the location and type of every single cell in the entire human body with under US$250,000 initially, then eventually reduce the cost down to under US$10,000.
The initial approach I’ll attempt when the money and circumstances permit is staining donated dead human body organs, tissues, and cells, and using second-near infrared light to scan the stained human cells in dead human organs and tissues in 3D. If a successful result gets created, I’ll patent and commercialize the technology, of course.
I’ll first do 3D bioscanner experiments on nonhuman biological organs and tissues, such as grocery-store meats and laboratory rat organs and tissues. In the U.S., you don’t need a regulatory permission for performing biotech experiments on rats; but registering each bioscience or biotech experiment with NIH or National Institute of Health is recommended, to let others know what you’re up to, and to be a part of the biomedical science and technology research community.
In later videos, I’ll talk about biophotonics, and cover how light interacts with biological matter at molecular and atomic levels; I’ll especially cover light reflection in biomatter, which is an extremely important topic in developing 3D biomatter scanner. I’ll look into the quantum physics that relates to light behavior, especially reflection, with biomolecules and bioatoms.
There is a program called “the Human BioMolecular Atlas Program (HuBMAP)” funded by National Institutes of Health, which aims to create a cellular map of the entire human body, to catalog and image each of the 200 or more types of cells from the 80 known organs and identify the genes that are active in these cells. It sounds like this is a project similar to what I am up to; I’ll keep on doing my own thing in biotech development and commercialization according to my own plan.
You can invest in my startup company with as little as US$100, for supporting advancing AI, robotics, biotech, and nuclear-fusion powered outer space tech. Visit Robocentric.com/Investors to invest in my startup.
My books on advancing AI, robotics, biotech, and nuclear-fusion powered outer space tech are available at Robocentric.com/Checkout, Amazon, Apple Books, Spotify, Google Play Store, and other online audiobook retailers.
I am Allen Young; I’m an Asian-American man who focuses on advancing AI, robotics, human longevity biotech, and nuclear-fusion powered outer space tech.