Team:Groningen/Project/Silk
From 2013.igem.org
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- | + | There are many anthropoids that have the ability to produce silk, most popular being the <i>Bombyx mori</i> silk worm used in the production of silk for clothing. However the spider easily takes the crown in terms of applications. | |
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+ | The Spider uses its silk as their Swiss Army Knife,some of these uses include, spinnig webs for catching preys, Dragline's for better movement, and for reproduction. Over the 400 million years of evolution the silk is optimized in many aspects. Like with many fascinating phenomena from nature, humans have learned to utilize the spider webs. Giant spiders() in tropical rain forests() have powerful webs to catch flying birds, and old cultures have used these webs for fishing purposes. | ||
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Revision as of 10:38, 26 September 2013
Silk Silk
Spider silk is regarded by many as the bio-material of the future, this due to is incredible high tensile strength combined with its elasticity. This makes spider silk as strong as steel and tougher than kevlar. However it is way less known that spider silk also has some impressive medical properties. Foremost the fact that spider silk (and silk in general) doesn’t cause a immune response in the human body. Immune response obviously being one of the major concerns when placing implants inside patients, so our iGEM team saw a great opportunity to combine the spider silk with the implants.Silk
Silk is a natural protein fibre that is known for its use in textiles. The best known silk comes from the silk moth pupa but a lot of animals such as arthropods are also capable of producing silk. One of the arthropods well known for its silk is the spider and spider silk is our material of choice for our implant coating.
The spider silk we used is the so called dragline silk from the Argiope aurantia (MaSp2) from Brooks et al (2008). It is the strongest silk produced inside the spider. The spider silk consists out of a big repetitive domain (around 2500 base pairs) with an N and a C terminus (figure 1 b).
Figure 1: schematic drawing of natural spider silk (Lukas Eisoldt et al. 2011) |
The properties of silk
The unique properties of silk are a result of its highly constant and repetitive amino-acid structure. The sequence of amino-acids determines what secondary structures will arise, and thus the final preferred protein conformation. The secondary structures may be beta sheets, beta-spirals, and beta-helices, of which the sheets realize the silk's amazing tensile strength, and the spirals and helices its elongation.
In the figure 2 below a stress-strain diagram can be found. where Clavipus
A final general property of silk it that it can be integrated with the human body, it will not induce an immune response, making it an ideal choice for many biomedical applications. Its compatibility extends to the gastrointestinal tract, that is, it is even safe to eat.
Figure 2: Properties of spidersilk versus other materials (Frank K. Ko, et at. 2001). Spider silk is compared to, Kevlar 29, normal silkworm silk, polyethylene terephthalate (PET), Nylon 6, and Merino wool. The stress-strain diagram relates the degree of deformation to the amount of energy absorbed. |
Silk as a coating material
Silk can be regarded as a superb version of collagen. Collagen is a material used a lot for the coating of implants. Although collagen is a naturally occurring protein found inside the human body, the implants are coated with proteins harvested from cows, which can give an immune response. On the other hand spider silk is an in allergic material and will never give an immune response. Spider Silk is biodegradable, has a low bacterial adherence and can rival any artificial material with the respect of cell growth (1-3). Therefore spider silk is a good candidate for the coating of medical implants.
For example one can think of a cartilage implant. The implant consists of a biodegradable polymer coated with spider silk. The human cells will grow into the implant, slowly degrading the implant. After a certain amount of time the implant is fully degraded, leaving only a new piece of cartilage in for example a knee.
References
(1) Silk-based materials for biomedical applications, A.Leal-Egana (2010)(2) Silk as biomaterial, C. Vepari (2007)
(3) Interactions between spider silk and cells, J.W. Kuhlier (2010)
Alternative (just an idea)
History
There are many anthropoids that have the ability to produce silk, most popular being the Bombyx mori silk worm used in the production of silk for clothing. However the spider easily takes the crown in terms of applications. The Spider uses its silk as their Swiss Army Knife,some of these uses include, spinnig webs for catching preys, Dragline's for better movement, and for reproduction. Over the 400 million years of evolution the silk is optimized in many aspects. Like with many fascinating phenomena from nature, humans have learned to utilize the spider webs. Giant spiders() in tropical rain forests() have powerful webs to catch flying birds, and old cultures have used these webs for fishing purposes.
[Picture cartoon of spider/swiss knife]
Remarkably, the biomedical properties of spider silk have been recognized for a long time. The oldest known application of a spider web as wound dressing is from Ancient Greece. Some other historical mentions date from around 1600. In the Polish book ‘With Fire and Sword’:
‘ “This is nothing, nothing at all” said he, feeling the wounds with his fingers. “He will be well to-morrow. I will take care of him. Mix up bread and spider-webs for me! ’
[Picture cartoon of Shakespearian character with wound and web]
And in Shakespeare’s comedy ‘Midsummer Night’s Dream’:
“I shall desire you of more acquaintance, good master cobweb,
If I cut my finger, I shall make bold of you.”
Apparently the spider webs are suitable as wound cover: they improve the recovery without giving problems. What gives the spider silk such excellent healing properties?
Biomedical properties
Shielding, preventing bacteria, improve wound repair,
No toxicity, no immune response, elasticity, cell adhesion, biodegradation
(See Review 'Silk-based materials for biomedical applications' from Aldo Leal-Egana and Thomas Scheibel, 2010, Biotech. Appl. Biochem)