Abstract
Biological tissues are viscoelastic, demonstrating a mixture of fluid and solid responses to mechanical strain. Whilst viscoelasticity is critical for native tissue function, it is rarely used as a design criterion in biomaterials science or tissue engineering. We propose that viscoelasticity may be tailored to specific levels through manipulation of the hydrogel type, or more specifically the proportion of physical and chemical crosslinks present in a construct. This theory was assessed by comparing the mechanical properties of various hydrogel blends, comprising elastic, equilibrium, storage and loss moduli, as well as the loss tangent. These properties were also assessed in human articular cartilage explants. It was found that whilst very low in elastic modulus, the physical crosslinks found in gellan gum-only provided the closest approximation of loss tangent levels found in cartilage. Blends of physical and chemical crosslinks (gelatin methacrylamide (GelMA) combined with gellan gum) gave highest values for elastic response. However, a greater proportion of gellan gum to GelMA than investigated may be required to achieve native cartilage viscoelasticity in this case. Human articular chondrocytes encapsulated in hydrogels remained viable over one week of culture. Overall, it was shown that viscoelasticity may be tailored similarly to other mechanical properties and may prove a new criterion to be included in the design of biomaterial structures for tissue engineering.
Highlights
Viscoelasticity is present in numerous materials, appearing within the majority, if not all, biological tissues [1,2,3]
Hydrogels are viscoelastic materials that are commonly used in tissue engineering (TE), in compression it is only their elastic properties that are typically characterized, and viscoelasticity in compression is rarely used as a deterministic criterion for scaffold design
In this study we present hydrogel blends consisting of the photocrosslinkable gelatin methacrylamide (GelMA) and gellan gum methacrylate (GGMA), in various combinations with gellan gum (GG)
Summary
Viscoelasticity is present in numerous materials, appearing within the majority, if not all, biological tissues [1,2,3]. It describes the simultaneous viscous and elastic response of a material, and is typically observed due to the properties of the structural components of a material (such as fibers or filaments), and the fluid flow between these components, and the chemical (e.g., ionic) interactions of any fluid and the structural components [3,4,5]. Viscoelastic characteristics including elastic modulus (E), equilibrium modulus (EEQ), elastic storage and loss moduli (E1 and E2 respectively) and loss factor/tangent (tan δ) may provide a more accurate quantification of material response to loading. E1 and E2 are indicative of the character of the elastic and viscous components of the tested materials under variable strain rates, whilst tan δ indicates the ratio of E2 to E1 (the tangent of the angle between the E2 and E1 vectors) or the proportion of viscous response to elastic response
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