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There are currently hundreds of thousands
of people on transplant lists,
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waiting for critical organs like kidneys,
hearts, and livers
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that could save their lives.
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Unfortunately,
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there aren’t nearly enough donor organs
available to fill that demand.
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What if instead of waiting,
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we could create brand-new, customized
organs from scratch?
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That’s the idea behind bioprinting,
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a branch of regenerative medicine
currently under development.
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We’re not able to print complex
organs just yet,
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but simpler tissues including blood
vessels and tubes
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responsible for nutrient
and waste exchange
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are already in our grasp.
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Bioprinting is a biological
cousin of 3-D printing,
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a technique that deposits layers of
material on top of each other
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to construct a three-dimensional object
one slice at a time.
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Instead of starting with metal, plastic,
or ceramic,
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a 3-D printer for organs and
tissues uses bioink:
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a printable material that
contains living cells.
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The bulk of many bioinks are water-rich
molecules called hydrogels.
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Mixed into those are
millions of living cells
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as well as various chemicals that
encourage cells to communicate and grow.
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Some bioinks include a
single type of cell,
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while others combine several different
kinds to produce more complex structures.
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Let’s say you want to print a meniscus,
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which is a piece of cartilage in the knee
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that keeps the shinbone and thighbone
from grinding against each other.
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It’s made up of cells called chondrocytes,
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and you’ll need a healthy supply of
them for your bioink.
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These cells can come from donors whose
cell lines are replicated in a lab.
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Or they might originate from a
patient’s own tissue
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to create a personalized meniscus less
likely to be rejected by their body.
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There are several printing techniques,
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and the most popular is extrusion-based
bioprinting.
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In this, bioink gets loaded into a
printing chamber
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and pushed through a round nozzle
attached to a printhead.
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It emerges from a nozzle that’s rarely
wider than 400 microns in diameter,
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and can produce a continuous filament
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roughly the thickness
of a human fingernail.
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A computerized image or file guides the
placement of the strands,
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either onto a flat surface or into a
liquid bath
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that’ll help hold the structure in place
until it stabilizes.
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These printers are fast, producing the
meniscus in about half an hour,
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one thin strand at a time.
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After printing, some bioinks
will stiffen immediately;
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others need UV light or an additional
chemical or physical process
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to stabilize the structure.
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If the printing process is successful,
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the cells in the synthetic tissue will
begin to behave
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the same way cells do in real tissue:
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signaling to each other, exchanging
nutrients, and multiplying.
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The hydrogel scaffold can be designed
to degrade as the cells proliferate.
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That way, if the tissue is implanted into
the body,
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the printed structure can fuse
with the surrounding tissue.
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We can already print relatively simple
structures like this meniscus.
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Bioprinted bladders have also been
successfully implanted,
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and printed tissue has promoted facial
nerve regeneration in rats.
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Researchers have created lung tissue,
skin, and cartilage,
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as well as miniature, semi-functional
versions of kidneys, livers, and hearts.
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However, replicating the complex
biochemical environment
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of a major organ is a steep challenge.
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Extrusion-based bioprinting may destroy
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a significant percentage of cells in the
ink if the nozzle is too small,
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or if the printing pressure is too high.
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One of the most formidable challenges
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is how to supply oxygen and nutrients
to all the cells in a full-size organ.
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That’s why the greatest successes so far
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have been with structures
that are flat or hollow—
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and why researchers are busy
developing ways
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to incorporate blood vessels
into bioprinted tissue.
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There’s tremendous potential to use
bioprinting
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to save lives and advance our
understanding
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of how our organs function
in the first place.
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And the technology opens up a dizzying
array of possibilities,
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such as printing tissues with
embedded electronics.
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Could we one day engineer organs that
exceed current human capability,
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or give ourselves features like
unburnable skin?
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How long might we extend human life
by printing and replacing our organs?
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And exactly who—and what—
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will have access to this technology
and its incredible output?
closed TED
