Researchers in the laboratory of Samuel I. Stupp at Northwestern University have an interesting approach for tackling some major health problems: gather raw materials and then let them self-assemble into structures that can address a multitude of medical needs.
At the core of the research are peptide amphiphiles (PA), small synthetic molecules that Stupp first developed seven years ago, which have been essential in his work on regenerative medicine. By tailoring these molecules and combining them with others, the researchers can make a wide variety of structures that may provide new treatments for medical issues including spinal cord injuries, diabetes and Parkinson's disease.
In a clever demonstration of self-repair, if the sac's membrane had a hole (from a needle injection, for example), Capito simply placed a drop of the PA solution on the tear, which interacted with the HA inside, resulting in self-assembly and a sealed hole.
While the underlying, highly ordered structures of the sacs and membranes have dimensions on the nanoscale, the sacs and membranes themselves can be of any dimension and are visible to the naked eye.
These sacs can be tailored to include bioactive regions, allowing researchers to incorporate a variety of designs into one sac structure. This capability opens the door to the creation of new methods for stem cell delivery. Stem cells can be loaded in the sac, which can be tailored to release the cells at the point of injury.
Previous work has shown that the PA molecules can be dissolved to form fibril structures with diameters of 5 to 8 nanometers. These gel structures can be used for regenerative medicine, and the research group has in vivo data for spinal cord repair, angiogenesis and bone and cartilage regeneration.
More information about research in the Stupp laboratory is available at stupp.northwestern.edu.
Contact: Megan Fellman fellman@northwestern.edu 847-491-3115 Northwestern University
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