This is a bit of welcome news on
the prosthetics front. Most likely this
will make the need for replacement rare.
Otherwise, it looks to be a technology that can be implemented rather
quickly, so we should see it around within the next several years if not
quicker.
Everything else about all this is
too well understood for delays to be overly likely.
Those facing the need to replace
joint structures will be able to have the peace of mind that it is effectively
forever. In the past, the lifetime issue
made postponing surgery a sometimes reasonable option. Yet the disablement is normally costly to the
victim who typically relied on those joints to provide him his living.
Radiation boost for artificial joints
by Staff Writers
A blast of gamma radiation could toughen up plastic prosthetic joints
to make them strong enough to last for years, according to researchers in China
Whole joint replacement, such as hip and knee replacement, commonly use
stainless steel, titanium alloys or ceramics to replace the damaged or diseased
bone of the joint. Non-stick polymer or nylon is usually used to coat the
artificial joint to simulate the cartilage. However, none of these materials
are ideal as they produce debris within the body as the joint is used, which
leads to inflammation, pain and other problems.
Now, Maoquan Xue of the Changzhou Institute of Light Industry
Technology, has investigated the effect of adding ceramic particles and fibers
to two experimental materials for coating prosthetic joints, UHMWPE
(ultra-high-molecular-weight polyethylene) and PEEK (polyether ether ketone).
Alone neither UHMWPE nor PEEK is suitable as a prosthetic cartilage
materials because both crack and fracture with the kind of everyday stresses
that a hip or knee joint would exert on them. The problem is that the long
polymer chains within the material can readily propagate applied forces causing
tiny fractures to grow quickly and the material to fail.
Xue has now demonstrated that by adding ceramic particles to the
polymers and then blasting the composite with a short burst of gamma-radiation
it is possible to break the main polymer chains without disrupting the overall
structure of the artificial cartilage. There is then no way for microscopic
fractures to be propagated throughout the material because there are no long
stretches of polymer to carry the force from one point to the next.
The resulting treated material is thus much tougher than the polymer
alone and will not produce the problematic debris within a joint that might
otherwise lead to inflammation and pain for the patient.
Xue adds that the treated composite materials might also be more
biocompatible and so less likely to be rejected by the patient's immunesystem on
implantation. He suggests that the particular structure of the composites
would also be receptive to addition of bone-generating cells, osteocytes or
stem cells, that could help a prosthetic joint be incorporated more naturally
into the body.
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