Electrospun ultrafine fibrous wheat glutenin scaffolds with three-dimensionally random organization and water stability for soft tissue engineering

•Wheat glutenin was dissolved via de-crosslinking while preserving the backbones and then electrospun into scaffolds with ultrafine fibers oriented randomly and three-dimensionally.•Wheat glutenin is a plant protein with low risk to transmit zoonotic diseases.•The scaffolds showed water-stability without external crosslinking due to the high crosslinked structure of wheat glutenin.•The three-dimensional ultrafine fibrous scaffolds mimicked the native extracellular matrices of soft tissues, such as adipose tissue.•The three-dimensional fibrous scaffolds supported attachment, proliferation and adipogenic differentiation of adipose derived mesenchymal cells.

Wheat glutenin, the highly crosslinked protein from wheat, was electrospun into scaffolds with ultrafine fibers oriented randomly and evenly in three dimensions to simulate native extracellular matrices of soft tissues. The scaffolds were intrinsically water-stable without using any external crosslinkers and could support proliferation and differentiation of adipose-derived mesenchymal stem cells for soft tissue engineering. Regeneration of soft tissue favored water-stable fibrous protein scaffolds with three-dimensional arrangement and large volumes, which could be difficult to obtain via electrospinning. Wheat glutenin is an intrinsically water-stable protein due to the 2% cysteine in its amino acid composition. In this research, the disulfide crosslinks in wheat glutenin were cleaved while the backbones were preserved. The treated wheat glutenin was dissolved in aqueous solvent with an anionic surfactant and then electrospun into bulky scaffolds composed of ultrafine fibers oriented randomly in three dimensions. The scaffolds could maintain their fibrous structures after incubated in PBS for up to 35 days. In vitro study indicated that the three-dimensional wheat glutenin scaffolds well supported uniform distribution and adipogenic differentiation of adipose derived mesenchymal stem cells.

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