Abstract
Dermo-epidermal equivalents based on plasma-derived fibrin hydrogels have been extensively studied for skin engineering. However, they showed rapid degradation and contraction over time and low mechanical properties which limit their reproducibility and lifespan. In order to achieve better mechanical properties, elasticity and biological properties, we incorporated a elastin-like recombinamer (ELR) network, based on two types of ELR, one modified with azide (SKS-N3) and other with cyclooctyne (SKS-Cyclo) chemical groups at molar ratio 1:1 at three different SKS (serine-lysine-serine sequence) concentrations (1, 3, and 5 wt.%), into plasma-derived fibrin hydrogels. Our results showed a decrease in gelation time and contraction, both in the absence and presence of the encapsulated human primary fibroblasts (hFBs), higher mechanical properties and increase in elasticity when SKSs content is equal or higher than 3%. However, hFBs proliferation showed an improvement when the lowest SKS content (1 wt.%) was used but started decreasing when increasing SKS concentration at day 14 with respect to the plasma control. Proliferation of human primary keratinocytes (hKCs) seeded on top of the hybrid-plasma hydrogels containing 1 and 3% of SKS showed no differences to plasma control and an increase in hKCs proliferation was observed for hybrid-plasma hydrogels containing 5 wt.% of SKS. These promising results showed the need to achieve a balance between the reduced contraction, the better mechanical properties and biological properties and indicate the potential of using this type of hydrogel as a testing platform for pharmaceutical products and cosmetics, and future work will elucidate their potential.
Highlights
We studied the biological properties of the elastin-plasma hydrogels and their interaction with human primary fibroblasts (hFBs) and human primary keratinocytes
Dual crosslinked networks based on plasma-derived fibrin with different elastin-like recombinamer (ELR) (SKSN3 and SKS-Cyclo) content were successfully obtained with the purpose of addressing the current limitations of the existing plasma-derived fibrin hydrogels for the generation of dermo-epidermal equivalents
SKSs content is equal or higher than 3%. This fact could be attributed to the formation of a full interpenetrating polymer network (IPN), consisting of both the fibrin network and the second network via click reaction between azide- and cyclooctyne-modified ELRs
Summary
Dermo-epidermal equivalents based on plasma-derived fibrin hydrogels offer a promising approach to skin engineering since they allow the preparation of more sophisticated laboratory-grown skin substitutes which better resemble the structure and function of human skin [1,2,3,4,5,6]. They allow an efficient production of natural collagen by human fibroblasts and a fully autologous process for skin grafting [2,7,8,9]. Another promising strategy could be the preparation of interpenetrating polymer network (IPN)
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