Medical biomaerials Tsubouchi (1999

Medical biomaerials

Tsubouchi (1999a) developed a silk fibroin-based wound dressing the could accelerate healing and could be peeled off without damaging the newly formed skin. The non-crystalline fibroin film of the wound dressing had a water content of 3-16% and a thickness of 10-100 um. Subsequently, the wound dressing was made with a mixture of both fibroin and sericin (Tsubouchi,1999b). The non-crystalline fibroin-sericin film had a degree of crystallization of less than 10%. The film had a thickness of 10-130 um and a density of 1100-1400 kg .The occlusive dressing had a 10% or greater solubility in water at room temperature and a water absorptivity of 10% or more at room temperature.
A membrane composed of sericin and fibron is an effective substrate for the proliferation of adherent animal cells and can be used as a substitute for collagen. Minoura et al. (1995) and Tsukada et al.(1999) investigated the attachment and growth of animal cells on films made of sericin and fibroin. Cell attachment and growth were dependent on maintaining a minimum of around 90% sericin in the composite membrane. Films of pure component proteins(i.e.,fibroin or sericin) permitted cell attachment and growth comparable to that on collagen, a widely use substrate for mammalian cell culture.
Film made of sericin and fibroin has an excellent oxygen permeability and is similar to human cornea in its functional properties. It is hoped that the sericin-fibroin blend film can be used to form artificial corneas (Murase,1994). For making the film, the silk protein is dissolved in a haloacetic acid such as trifluoroacetic acid, CF3COOH (Murase,1994). Fully dissolving 1 g cocoon shell (sericin and fibroin) in 3 ml or 98% CF3COOH produces a gel-like substance that is poured into molds or formed int a film. The solidified molding is