Human cell staining biotechnologies development for human longevity biotech development

I’m 100% convinced that in order to develop the human longevity biotech that I envision, I must first develop and commercialize a biotechnology that can 3D-scan human biomatter at microscopic level, and record the 3D location of every single human cell and count the number of all the cells in a piece of human biomatter such as a human organ, and preferably determine the type of each scanned human cell without additional biochemical analysis.

A biological cell is translucent, so it is not visible; in order to make a biological cell visible under microscope, you have to stain it with a chemical, biochemical, or radiation.

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.

My hunch is that I need to develop and commercialize one or more highly effective biological cell staining methods or biotechnologies, to be able to 3D-scan human biomatter at microscopic level.

So my question is, what is a good way to stain a biological cell? What cellular components are prime candidates for staining in volume?

An animal cell, such as the human cell, has the following cell components. Nucleus with nuclear pore, chromatin, nuclear envelope, nucleus, and nucleolus; plasma membrane, Golgi vesicles (Golgi apparatus), ribosomes, rough endoplasmic reticulum, smooth endoplasmic reticulum, actin filaments; flagellum; peroxisome, microtubule, lysosome, free ribosomes, mitochondrion, intermediate filaments; cytoplasm, secretory vesicle, centrosome (with 2 centrioles).

A plant cell has the following cell components. Nucleus with nuclear pore, nuclear envelope, and nucleolus; chloroplast with thylakoid membrane, and starch grain; vacuole with vacuole and tonoplast; mitochondrion (mitochondria), peroxisome, cytoplasm, Golgi vesicles, Golgi body (Golgi apparatus), rough endoplasmic reticulum, smooth endoplasmic reticulum, ribosomes, small membranous vesicles, filamentous cytoskeleton, plasmodesmata, plasma membrane, cell wall.

Is it possible to manufacture a fluorescent protein that will attach to a certain cell component, making every cell visible under a microscope? I’ll look into that.

I’ll keep working on developing and commercializing human-cell wall staining biotech, human-cell nucleus and genome staining biotech, human-cell telomere staining biotech, human-cell component staining biotech—for eventually developing and commercializing human longevity biotech.

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.

Allen Young

The transhumanistic Asian-American man who publicly promotes and advances AI, robotics, human body biotech, and mass-scale outer space tech.