Interfacial optimization of fiber-reinforced hydrogel composites for soft fibrous tissue applications

Interfacial properties and the effect of inter-fiber spacing for UHMWPE-PVA hydrogel composites were analyzed, where PVA-grafted UHMWPE fibers showed significantly improved fiber-matrix stress transfer. [Display omitted] Meniscal tears are the most common orthopedic injuries to the human body, yet t...

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Bibliographic Details
Published in:Acta biomaterialia 2014-08, Vol.10 (8), p.3581-3589
Main Authors: Holloway, Julianne L., Lowman, Anthony M., VanLandingham, Mark R., Palmese, Giuseppe R.
Format: Article
Language:English
Subjects:
Adhesion
Adhesiveness
Animals
Biocompatible Materials - chemical synthesis
Biocompatible Materials - therapeutic use
Composite
Elastic Modulus
Fibers
Grafting
Hardness
Humans
Hydrogel
Hydrogels
Hydrogels - chemistry
Hydrogels - therapeutic use
Interfacial properties
Interfacial shear strength
Interfacial strength
Materials Testing
Meniscus
Optimization
Poly(vinyl alcohol)
Polyethylenes
Polyethylenes - chemistry
Polyethylenes - therapeutic use
Polyvinyl Alcohol - chemistry
Polyvinyl Alcohol - therapeutic use
Soft Tissue Injuries - therapy
Stress, Mechanical
Surface Properties
Tensile Strength
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Summary:Interfacial properties and the effect of inter-fiber spacing for UHMWPE-PVA hydrogel composites were analyzed, where PVA-grafted UHMWPE fibers showed significantly improved fiber-matrix stress transfer. [Display omitted] Meniscal tears are the most common orthopedic injuries to the human body, yet the current treatment of choice is a partial meniscectomy, which is known to lead to joint degeneration and osteoarthritis. As a result, there is a significant clinical need to develop materials capable of restoring function to the meniscus following an injury. Fiber-reinforced hydrogel composites are particularly suited for replicating the mechanical function of native fibrous tissues due to their ability to mimic the native anisotropic property distribution present. A critical issue with these materials, however, is the potential for the fiber–matrix interfacial properties to severely limit composite performance. In this work, the interfacial properties of an ultra-high-molecular-weight polyethylene (UHMWPE) fiber-reinforced poly(vinyl alcohol) (PVA) hydrogel are studied. A novel chemical grafting technique, confirmed using X-ray photoelectron spectroscopy, is used to improve UHMWPE–PVA interfacial adhesion. Interfacial shear strength is quantified using fiber pull-out tests. Results indicate significantly improved fiber–hydrogel interfacial adhesion after chemical grafting, where chemically grafted samples have an interfacial shear strength of 256.4±64.3kPa compared to 11.5±2.9kPa for untreated samples. Additionally, scanning electron microscopy of fiber surfaces after fiber pull-out reveal cohesive failure within the hydrogel matrix for treated fiber samples, indicating that the UHMWPE–PVA interface has been successfully optimized. Lastly, inter-fiber spacing is observed to have a significant effect on interfacial adhesion. Fibers spaced further apart have significantly higher interfacial shear strengths, which is critical to consider when optimizing composite design. The results in this study are applicable in developing similar chemical grafting techniques and optimizing fiber–matrix interfacial properties for other hydrogel-based composite systems.
ISSN:1742-7061
1878-7568
DOI:10.1016/j.actbio.2014.05.004