Despite substantial investment, there are many failed attempts to develop and manufacture a blood substitute. At this time there are no currently approved products for use as blood substitutes in North America or Europe. We propose in this application to take a biomimetic approach to the design of red blood cells (RBC) using a powerful molding technique called PRINT(R) (Particle Replication in Non-wetting Templates) developed at the University of North Carolina at Chapel Hill. PRINT will be used synthesize shape-specific, colloidally stable, hydrogel particles with dimensions and mechanical properties which resemble red blood cells and that are individually deformable in a manner to allow them to pass through the 3 micron sized sinusoids in the spleen. Previous approaches for the design of synthetic blood have focused on i) fluorocarbon emulsions which can dissolve large amounts of blood gases;ii) PEGylated hemoglobin;and iii) liposomal delivery of hemoglobin. Heretofore, no one has reported direct molding of RBC mimics which have the same evolutionarily designed shapes and deformability or modulus as RBCs. The PRINT molding technique allows us to independently design and investigate the key criteria necessary for a true replacement for blood, including: shape control, particle modulus or flexibility, surface chemistry and surface ligands including markers of self, flow characteristics and gas transport characteristics. The molded particles will be designed to sequester hemoglobin and allosteric effectors as a cargo, preventing the release and circulation of free-hemoglobin. The RBC mimics facilitate life-like oxygen carrying capacity, but have it in a form that isolates it from physical contact with various organs to avoid the documented side effects associated with free hemoglobin and its cross-linked derivatives. In addition, we also propose to conjugate """"""""markers of self"""""""" onto these deformable molded RBC mimics to minimize elimination by the reticuloendothelial system (RES). Key goals of the program will be to develop and test a long circulating red blood cell mimic that has the classical sigmoidal shape of the oxygen equilibrium curve with a surface to volume ratio associated with a true RBC for optimal oxygen carrying and release capacity as demonstrated by in vitro and in vivo studies.

Public Health Relevance

The need to develop safe and effective synthetic blood substitutes for civilian and military uses is immediate, particularly shelf-stable supplies that don't require blood antigen type matching. There will be an estimated shortage of as much as 4 million units of donor blood in the United States alone by 2030. In addition, there is increasing risk of disease transmission from current blood supplies including HIV, Hepatitis A virus, B19 parvovirus, Hepatitis C virus, and infectious prion proteins - the agents associated with variant Creutzfeldt- Jakob disease, mad cow disease and scrapie. A biomimetic approach will be taken to design red blood cells mimics with the same evolutionarily designed shapes and deformability or modulus as RBCs using a powerful molding technique called PRINT(R) (Particle Replication in Non-wetting Templates), which allows for control over shape, particle modulus, surface chemistry and surface ligands, flow characteristics and gas transport characteristics.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21HL096011-01A1
Application #
7786863
Study Section
Erythrocyte and Leukocyte Biology Study Section (ELB)
Program Officer
Mitchell, Phyllis
Project Start
2010-03-11
Project End
2012-02-29
Budget Start
2010-03-11
Budget End
2011-02-28
Support Year
1
Fiscal Year
2010
Total Cost
$201,684
Indirect Cost
Name
University of North Carolina Chapel Hill
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
608195277
City
Chapel Hill
State
NC
Country
United States
Zip Code
27599
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Chen, Kai; Merkel, Timothy J; Pandya, Ashish et al. (2012) Low modulus biomimetic microgel particles with high loading of hemoglobin. Biomacromolecules 13:2748-59
Merkel, Timothy J; Chen, Kai; Jones, Stephen W et al. (2012) The effect of particle size on the biodistribution of low-modulus hydrogel PRINT particles. J Control Release 162:37-44
Wang, Jin; Byrne, James D; Napier, Mary E et al. (2011) More effective nanomedicines through particle design. Small 7:1919-31