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Printing technique creates effective skin equivalent, heals wounds

Material mimics all three layers of the skin, allows for complex printing structures

Date:
December 3, 2021
Source:
American Institute of Physics
Summary:
Researchers have developed an approach to print skin equivalents, which may play a future role in facilitating the healing of chronic wounds. They used suspended layer additive manufacturing, creating a gel-like material to support the skin equivalent that can then support a second phase of gel injection. During printing, the skin layers are deposited within the support gel. After printing, the team washed away the support material, leaving behind the layered skin equivalent.
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Chronic wounds are deep and difficult to repair. Often, the top of the injury heals before the bottom, so the wound collapses in on itself. Over time, this can result in scar tissue and reduced skin function.

In APL Bioengineering, by AIP Publishing, researchers from the University of Birmingham and University of Huddersfield developed an approach to print skin equivalents. The material may play a future role in facilitating the healing of chronic wounds.

The technique is the first of its kind to simulate three layers of skin: the hypodermis, or fatty layer, the dermis, and the epidermis.

"You effectively have three different cell types. They all grow at different speeds," said author Alan Smith. "If you try to produce tri-layered structures, it can be very difficult to provide each of the requirements of each different layer."

To solve this problem, the scientists used suspended layer additive manufacturing (SLAM). They created a gel-like material to support the skin equivalent, twisting and altering the structure of the gel as it formed to create a bed of particles that can then support a second phase of gel injection.

During printing, the skin layers are deposited within the support gel, which holds everything in place. After printing, the team washed away the support material, leaving behind the layered skin equivalent.

If the researchers moved a needle through the supporting gel, it repaired itself faster than other similar techniques. This results in higher resolution printing than previous methods and allows for the printing of complicated skin structures.

The authors tested the skin substitute by cutting a hole in pig tissue and printing a skin equivalent to fill the hole. After culturing the model system for 14 days, they saw signs of wound repair.

"We used a stain that allowed us to quantify the integration we got between original material and tissue," said author Liam Grover. "We were able to demonstrate some integration even after a short period of time."

The team cannot assess chronic wound healing with the skin substitute because that process takes more time than their model allowed, which was only 14-21 days. However, their next step is to test longer, appropriate models for chronic deep wounds. The ultimate goal is to repair human skin and reduce scarring for all patient scenarios.


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Materials provided by American Institute of Physics. Note: Content may be edited for style and length.


Journal Reference:

  1. Richard J. A. Moakes, Jessica J. Senior, Thomas E. Robinson, Miruna Chipara, Aleksandar Atansov, Amy Naylor, Anthony D. Metcalfe, Alan M. Smith, Liam M. Grover. A suspended layer additive manufacturing approach to the bioprinting of tri-layered skin equivalents. APL Bioengineering, 2021; 5 (4): 046103 DOI: 10.1063/5.0061361

Cite This Page:

American Institute of Physics. "Printing technique creates effective skin equivalent, heals wounds." ScienceDaily. ScienceDaily, 3 December 2021. <www.sciencedaily.com/releases/2021/12/211203131213.htm>.
American Institute of Physics. (2021, December 3). Printing technique creates effective skin equivalent, heals wounds. ScienceDaily. Retrieved March 28, 2024 from www.sciencedaily.com/releases/2021/12/211203131213.htm
American Institute of Physics. "Printing technique creates effective skin equivalent, heals wounds." ScienceDaily. www.sciencedaily.com/releases/2021/12/211203131213.htm (accessed March 28, 2024).

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