Biological evaluation of human hair keratin scaffolds for skin wound repair and regeneration.

The cytocompatibility, in vivo biodegradation and wound healing of keratin biomaterials were investigated. For the purposes, three groups of keratin scaffolds were fabricated by freeze-drying reduced solutions at 2 wt.%, 4 wt.% and 8 wt.% keratins extracted from human hairs. These scaffolds exhibited evenly distributed high porous structures with pore size of 120-220 µm and the porosity >90%. NIH3T3 cells proliferated well on these scaffolds in culture lasting up to 22 days. Confocal micrographs stained with AO visually revealed cell attachment and infiltration as well as scaffold architectural stability. In vivo animal experiments were conducted with 4 wt.% keratin scaffolds. Early degradation of subcutaneously implanted scaffolds occurred at 3 weeks in the outermost surface, in concomitant with inflammatory response. At 5 weeks, the overall porous structure of scaffolds severely deteriorated while the early inflammatory response in the outermost surface obviously subsided. A faster keratin biodegradation was observed in repairing full-thickness skin defects. Compared with the blank control, keratin scaffolds gave rise to more blood vessels at 2 weeks and better complete wound repair at 3 weeks with a thicker epidermis, less contraction and newly formed hair follicles. These preliminary results suggest that human hair keratin scaffolds are promising dermal substitutes for skin regeneration.

Characterisation of low abundance wool proteins through novel differential extraction techniques.

Fibres from human hair and wool are characterised by two main types of proteins: intermediate filament proteins (IFPs) and keratin associated proteins (KAPs). The IFPs, comprising over 50% of the fibre, tend to dominate 2-D electrophoretic maps, hindering identification of the less-abundant KAPs. This has been compounded in wool fibres by the relatively limited amount of sequence information available, with approximately 35 distinct protein sequences from ten KAP families being available, in contrast to human hair, where the sequences from well over 80 proteins from 26 KAP families are known. Additional complications include the high degree of homology within these families, ranging from 70 to 95%, and the dominance of cysteine residues in a number of KAP families with their high propensity to form cross-links. The lack of sequence information for wool KAPs has been partly overcome through the recent acquisition of new sequences. Fractionation of the proteins on the basis of their solubility with pH, urea and DTT concentration has resulted in protein extracts in which the IFP concentration has been considerably reduced. These improvements have enabled the identification of low-abundance proteins in 2-D electrophoretic maps and represent a significant advance in our knowledge of the wool proteome.