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Materials

Synthetic Platelets Boost Clotting

Materials Science: Deformable microgels mimic natural platelets

by Celia Henry Arnaud
September 15, 2014 | A version of this story appeared in Volume 92, Issue 37

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Credit: Nat. Mater.
Synthetic platelets (red, about 2 µm across) embedded in a fibrin network (blue) contribute to clot contraction, as shown here at the beginning (top) and end of a computational simulation.Synthetic platelets (red, about 2 µm across) embedded in a fibrin network (blue) contribute to clot contraction, as shown here at the beginning and end of a computational simulation.
Computer simulation of fibrin network with synthetic platelets before and after clot contaction.
Credit: Nat. Mater.
Synthetic platelets (red, about 2 µm across) embedded in a fibrin network (blue) contribute to clot contraction, as shown here at the beginning (top) and end of a computational simulation.Synthetic platelets (red, about 2 µm across) embedded in a fibrin network (blue) contribute to clot contraction, as shown here at the beginning and end of a computational simulation.

Platelets are specialized blood cells that participate in the clotting process the body uses to stanch bleeding. A team of researchers at Georgia Tech led by chemist L. Andrew Lyon and biomedical engineer Thomas H. Barker has designed new synthetic platelets that have the potential to boost clotting when traumatic injury overwhelms the natural clotting process (Nat. Mater. 2014, DOI: 10.1038/nmat4066).

The synthetic platelets are made of poly(N-isopropylacrylamide-co-acrylic acid) microgels with ultralow levels (< 0.5%) of cross-linking. Compared with previous synthetic platelets, they boost clotting specifically at injury sites without causing unwanted clotting elsewhere. That’s because each particle is studded with recognition motifs that bind fibrin, an insoluble protein that forms only after clotting has already started.

“In principle, we can inject our particles and they can circulate freely in the bloodstream without causing any detrimental off-target effects,” says Ashley C. Brown, a research scientist working with Barker and Lyon. “Our trigger to augment clotting is more specific than previous synthetic platelets.”

Another key feature of the new synthetic platelets is their ability to induce clot contraction, which is thought to help stabilize the clot and protect it from breaking down. This is a function of natural platelets that has not previously been seen in synthetic platelets. The researchers think these synthetic platelets can induce clot contraction because they are highly deformable, which permits more extensive engagement of the clot through the recognition motifs. That deformability is a direct result of the low level of cross-linking. “With the addition of even small amounts of cross-linker—2% cross-linking density—we inhibited clot contraction,” Brown says.

The researchers injected the synthetic platelets into rats. Rats that received the synthetic platelets bled less when cut than rats that didn’t receive them.

More data are needed on the biodistribution and clearance of the particles, says Erin Lavik, a biomedical engineer at Case Western Reserve University who is also working on synthetic platelets. “With inflexible particles, we’re limited in how large we can make them and get good clearance from uninjured tissues,” she says. “If these flexible ones avoid that issue, they could have significant application.”

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