This could mean that it will become possible to decellularize an entire body and then transplant a brain. That is extreme but we are certainly doing it already in part. It is still far from ideal but that will happen when we grow the components fresh. That is coming too.
Body regeneration will become a universal standard regardless. It means that any failed component can be replaced with a biological that matches past performance. Mechanicals will become obsolete and disability will become a thing that is a passing problem.
It is already happening and this shows us were the present limits are. We can replace a limb without secondary effects from rejection. That is a huge advance that covers the majority of battle and road injuries..
Scientists come a step closer to "regrowing" limbs
The decellularized rat forelimb is injected with
muscle and vascular cells
(Credit: Bernhard Jank, MD, Ott Laboratory,
Massachusetts General Hospital Center for Regenerative Medicine)
Currently, recipients of arm or leg transplants need to take
immunosuppressive drugs for the rest of their lives, in order to keep
the donated parts from being rejected. If we could grow our own
replacement limbs, however, that wouldn't be necessary. And while we do
already possess the progenitor cells needed to grow such parts, what's
been lacking is a method of assembling them into the form of the desired
limb. Now, however, scientists have created a shortcut of sorts –
they've stripped the cells from one rat's forelimb and replaced them
with live cells from another rat, creating a functioning limb that the
second rat's immune system won't reject.
Led by Dr. Harald Ott, a team at the Massachusetts
General Hospital started by perfusing the donor limb with a detergent
that stripped away all of its living cells. After the cellular debris
was removed, all that remained was the empty non-living extracellular matrix that formerly contained the cells.
As this task was in process, progenitor cells from the recipient rat were being being grown in culture to produce muscle and vascular cells.
Once the limb was stripped of its original cells, it was
placed in a nutrient solution-filled bioreactor and injected with the
lab-grown cells – the muscle cells went into the individual muscle
sheath sections of the matrix, while the vascular cells went into the
main artery. After five days of being in the reactor, electric
stimulation was applied to help the muscles grow. Two weeks later, upon
being removed from the reactor, the limb was found to have functioning
muscle cells in the muscle fibers and live vascular cells in the blood
vessel walls.
When the muscles were activated using electrical
stimulation, they were found to have 80 percent the strength of a
newborn rat's forelimb muscles. Additionally, when the limb was
transplanted onto the recipient rat, its blood vessels soon filled with
blood and became part of the circulatory system.
Ott and his team are now looking at ways of regrowing
other limb tissues such as bone, cartilage and connective tissue. The
regrowth of nerves should hopefully happen on its own. "In clinical limb
transplantation, nerves do grow back into the graft, enabling both
motion and sensation, and we have learned that this process is largely
guided by the nerve matrix within the graft," he says. "We hope in
future work to show that the same will apply to bioartificial grafts."
The decellularization technique utilized by the
Massachusetts scientists, incidentally, has previously been used to
create transplantable mouse hearts and rat kidneys.
However, this is the first time that it's been used for something more
complex than an organ. The scientists have also decellularized a baboon
forearm, indicating that the procedure could work on primates.
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