The effect of glycosaminoglycan content on polyethylenimine-based gene delivery within three-dimensional collagen-GAG scaffolds

The design of biomaterials for increasingly complex tissue engineering applications often requires exogenous presentation of biomolecular signals. Integration of gene delivery vectors with a biomaterial scaffold offers the potential to bypass the use of expensive and relatively inefficient growth fa...

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Bibliographic Details
Published in:Biomaterials science 2015-04, Vol.3 (4), p.645-654
Main Authors: Hortensius, Rebecca A, Becraft, Jacob R, Pack, Daniel W, Harley, Brendan A. C
Format: Article
Language:English
Subjects:
Biocompatible Materials - chemistry
Biomaterials
Biomedical materials
Collagen - genetics
Collagen - metabolism
Culture
Gene Transfer Techniques
Genes
Glycosaminoglycans - chemistry
Luciferases - genetics
Luciferases - metabolism
Polyetherimides
Polyethyleneimine - chemistry
Scaffolds
Surgical implants
Tendons - chemistry
Tendons - cytology
Three dimensional
Tissue Engineering
Tissue Scaffolds
Transfection
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Summary:The design of biomaterials for increasingly complex tissue engineering applications often requires exogenous presentation of biomolecular signals. Integration of gene delivery vectors with a biomaterial scaffold offers the potential to bypass the use of expensive and relatively inefficient growth factor supplementation strategies to augment cell behavior. However, integration of cationic polymer based gene delivery vectors within three-dimensional biomaterials, particularly matrices which can carry significant surface charge, remains poorly explored. We examined the potential of polyethylenimine (PEI) as a gene delivery vector for three-dimensional collagen-glycosaminoglycan (CG) scaffolds under development for tendon repair. While acetylated versions of PEI have demonstrated improved transfection efficiency in 2D culture assays, we investigated translation of this effect to a 3D biomaterial that contains significant electrostatic charge. A reporter gene was used to examine the impact of polymer modification, polymer : DNA ratio, and the degree of sulfation of the biomaterial microenvironment on gene delivery in vitro . We observed highest transgene expression in acetylated and unmodified PEI at distinct polymer : DNA ratios; notably, the enhancement often seen in two-dimensional culture for acetylated PEI did not fully translate to three-dimensional scaffolds. We also found highly sulfated heparin-based CG scaffolds showed enhanced initial luciferase expression but not prolonged activity. While PEI constructs significantly reduced tenocyte metabolic health during the period of transfection, heparin-based CG scaffolds showed the greatest recovery in tenocyte metabolic health over the full 2 week culture. These results suggest that the electrostatic environment of three-dimensional biomaterials may be an important design criterion for cationic polymer-based gene delivery. Polyethylenimine was used as a gene delivery vector to tendon cells within three-dimensional collagen scaffolds. Scaffolds functionalized with highly sulfated heparin showed enhanced gene delivery as well as increased cellular metabolic activity.
ISSN:2047-4830
2047-4849
DOI:10.1039/c5bm00033e