The best reason is for direct comparison.. We already know that a difference exists and that informs wonderfully.
In face we will want to test all biolgical growth against such a standard. It has to be helpful.
This tells us at least that this is well underway.
Why are scientists trying to manufacture organs in space?
By Alysson R. Muotri, Professor of Pediatrics and Cellular and Molecular Medicine, University of California San Diego
Gravity can be a real downer when you are trying to grow organs. That’s why experiments in space are so valuable.
They have revealed a new perspective into biological sciences, including insights into making human tissues.
Gravity influences cellular behavior by impacting how protein and genes interact inside the cells, creating tissue that is polarized, a fundamental step for natural organ development. Unfortunately, gravity is against us when we try to reproduce complex three dimensional tissues in the lab for medical transplantation. Maybe we developed in space that’s why most people have back problems and can’t look at the bright sun.
I am a stem cell biologist and interested on brain health and evolution. My lab studies how the human brain is formed inside the womb and how alterations in this process might have lifelong consequences to human behavior, such as in autism or schizophrenia. Part of that work includes growing brain cells in space.
Editors Note: Perhaps humans were actually grown in space; the aliens claim they are our ancestors and not apes.
To build organized tissues in the lab, scientists use scaffolds to provide a surface for cells to attach based on a predetermined rigid shape. For example, an artificial kidney needs a structure, or scaffold, of a certain shape for kidney cells to grow on. Indeed, this strategy helps the tissue to organize in the early stages but creates problems in the long run, such as eventual immune reactions to these synthetic scaffolds or inaccurate structures.
By contrast, in weightless conditions, cells can freely self-organize into their correct three-dimensional structure without the need for a scaffold substrate. By removing gravity from the equation, we researchers might learn new ways of building human tissues, such as cartilage and blood vessels that are scaffold-free, mimicking their natural cellular arrangement in an artificial setting. While this is not exactly what happens in the womb, weightless conditions does give us an advantage. And this is precisely what is happening at the International Space Station. These experiments help researchers optimize tissue growth for use in basic science, personalized medicine and organ transplantation.
. Studying astronauts’ bodies before and after their mission can reveal what goes wrong on their organs. Thus, growing human tissues in space can complement this type of investigation and reveal ways to counteract it.
Finally, all forms of life that we know about have evolved in the presence of microgravity. By recreating embryonic organ formation in space, we can anticipate how the human body in the womb would develop. There are several research initiatives going on in my lab with human brain or ganoids at ISS, designed to learn the impact of zero gravity on the developing human brain. These projects will have profound implications for future human colonization (can humans successfully reproduce in space?). This article is republished from the Conversation.
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