Medical

New collagen scaffolding technique to benefit tissue engineering

New collagen scaffolding technique to benefit tissue engineering
The bioskiving process (Image credit: Qiaobing Xu)
The bioskiving process (Image credit: Qiaobing Xu)
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Decellularized bovine tendon (left), a stacked multilayered construct (middle), and a tubular construct (right) fabricated by bioskiving
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Decellularized bovine tendon (left), a stacked multilayered construct (middle), and a tubular construct (right) fabricated by bioskiving
The bioskiving process (Image credit: Qiaobing Xu)
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The bioskiving process (Image credit: Qiaobing Xu)

Collagen is the main component of connective tissues and the most abundant protein in the human body. Biocompatible and biodegradable, it is an excellent material for making scaffolding for tissue engineering. The trouble is, conventional techniques disrupt the fibrous structure of collagen and weaken the end product. At the Tufts University School of Engineering, Qiaobing Xu, assistant professor of biomedical engineering, and Ph.D. student Kyle Alberti have developed a new technique for fabricating collagen structures that avoids this disruption and retains collagen’s strength.

Invented by Xu, the new technique is called “bioskiving.” It involves taking collagen from bovine tendons and removing all the cells and other materials from it using special detergents until only the collagen fibers are left. These are then sliced into very thin sheets using a microtome and stacked in layers of ten at right angles to one another like layers of plywood.

Decellularized bovine tendon (left), a stacked multilayered construct (middle), and a tubular construct (right) fabricated by bioskiving
Decellularized bovine tendon (left), a stacked multilayered construct (middle), and a tubular construct (right) fabricated by bioskiving

The result is a collagen scaffolding that is stronger than that produced by conventional processes. This scaffolding can also be formed into tubes by folding the sheets around a Teflon-coated glass rod. These tubes are also stronger than those produced by conventional techniques. These structures can then be seeded with living cells to create blood vessels and other products.

"Alignment gives the scaffold the ability to guide the direction and orientation of cell growth," said Xu. "This capability is beneficial for tissue engineering applications where biocompatibility and the ability to guide unidirectional nerve growth are both desired, such as prosthetic or tissue engineering-based blood vessels or nerve conduits."

The results of Xu and Alberti’s work was published in an article entitled "Slicing, Stacking and Rolling: Fabrication of Nanostructured Collagen Constructs from Tendon Sections" in Advanced Healthcare Materials on December 12, 2012.

Source: Phys.org

Collagen is the main component of connective tissues and the most abundant protein in the human body. Biocompatible and biodegradable, it is an excellent material for making scaffolding for tissue engineering. The trouble is, conventional techniques disrupt the fibrous structure of collagen and weaken the end product. At the Tufts University School of Engineering, Qiaobing Xu, assistant professor of biomedical engineering, and Ph.D. student Kyle Alberti have developed a new technique for fabricating collagen structures that avoids this disruption and retains collagen’s strength.

Invented by Xu, the new technique is called “bioskiving.” It involves taking collagen from bovine tendons and removing all the cells and other materials from it using special detergents until only the collagen fibers are left. These are then sliced into very thin sheets using a microtome and stacked in layers of ten at right angles to one another like layers of plywood.

Decellularized bovine tendon (left), a stacked multilayered construct (middle), and a tubular construct (right) fabricated by bioskiving
Decellularized bovine tendon (left), a stacked multilayered construct (middle), and a tubular construct (right) fabricated by bioskiving

The result is a collagen scaffolding that is stronger than that produced by conventional processes. This scaffolding can also be formed into tubes by folding the sheets around a Teflon-coated glass rod. These tubes are also stronger than those produced by conventional techniques. These structures can then be seeded with living cells to create blood vessels and other products.

"Alignment gives the scaffold the ability to guide the direction and orientation of cell growth," said Xu. "This capability is beneficial for tissue engineering applications where biocompatibility and the ability to guide unidirectional nerve growth are both desired, such as prosthetic or tissue engineering-based blood vessels or nerve conduits."

The results of Xu and Alberti’s work was published in an article entitled "Slicing, Stacking and Rolling: Fabrication of Nanostructured Collagen Constructs from Tendon Sections" in Advanced Healthcare Materials on December 12, 2012.

Source: Phys.org

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