Synthetic Platelets Could Eventually Be Used For Biomedical Applications
By LabMedica International staff writers Posted on 07 Jun 2012 |
Image: Diagram, an artist's rendering of artificial platelets and artificial red blood cells alongside their natural counterparts (Photo courtesy of Peter Allen).
Scientists have succeeded in making synthetic platelets, which after optimization and exhaustive testing, could be suitable for a number of biomedical applications
At University of California (UC) Santa Barbara (USA) scientists used a polymeric template––a core upon which layers of proteins and polyelectrolytes were deposited, layered, and crosslinked to create a stable synthetic platelet-shaped particle. The rigid polymeric core was then dissolved to give the particle the desired flexibility. The particle was then coated with proteins found on the surface of activated natural platelets or damaged blood vessels, a procedure performed by the researchers at Scripps Research Institute (Scripps Research Institute (La Jolla, CA, USA). Scientists at Sanford-Burnham Institute (La Jolla, CA, USA) collaborated in the project.
Smaller than red blood cells, platelets are flexible, disk-shaped cells that are 2-4 µm in size. They are the components of blood that allow it to prevent excessive bleeding and to heal wounds. The synthetic platelets can be used not only to perform the typical functions of human platelets. They may also be used to carry imaging agents to identify damaged blood vessels or to deliver drugs that dissolve blood clots.
The synthetic platelets represent one of the most advanced efforts over the last century to mimic platelet function. While clotting factors and platelets from outside donors are used widely to halt bleeding, immune system responses and thrombosis have been issues.
The development is a significant milestone in the field of biomimetic materials," said Samir Mitragotri, professor of chemical engineering, director of UC Santa Barbara's Center for Bioengineering, and an author of a paper published in the journal Advanced Materials on May 29, 2012. "By capitalizing on our capabilities in engineering materials, […] our synthetic platelets combine unique physical and biological attributes that mimic natural platelets."
Related Links:
University of California, Santa Barbara
Scripps Research Institute
Sanford-Burnham Institute
At University of California (UC) Santa Barbara (USA) scientists used a polymeric template––a core upon which layers of proteins and polyelectrolytes were deposited, layered, and crosslinked to create a stable synthetic platelet-shaped particle. The rigid polymeric core was then dissolved to give the particle the desired flexibility. The particle was then coated with proteins found on the surface of activated natural platelets or damaged blood vessels, a procedure performed by the researchers at Scripps Research Institute (Scripps Research Institute (La Jolla, CA, USA). Scientists at Sanford-Burnham Institute (La Jolla, CA, USA) collaborated in the project.
Smaller than red blood cells, platelets are flexible, disk-shaped cells that are 2-4 µm in size. They are the components of blood that allow it to prevent excessive bleeding and to heal wounds. The synthetic platelets can be used not only to perform the typical functions of human platelets. They may also be used to carry imaging agents to identify damaged blood vessels or to deliver drugs that dissolve blood clots.
The synthetic platelets represent one of the most advanced efforts over the last century to mimic platelet function. While clotting factors and platelets from outside donors are used widely to halt bleeding, immune system responses and thrombosis have been issues.
The development is a significant milestone in the field of biomimetic materials," said Samir Mitragotri, professor of chemical engineering, director of UC Santa Barbara's Center for Bioengineering, and an author of a paper published in the journal Advanced Materials on May 29, 2012. "By capitalizing on our capabilities in engineering materials, […] our synthetic platelets combine unique physical and biological attributes that mimic natural platelets."
Related Links:
University of California, Santa Barbara
Scripps Research Institute
Sanford-Burnham Institute
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