A suspended layer additive manufacturing approach to the bioprinting of tri-layered skin equivalents.

Richard J A Moakes,Jessica J Senior,Amy Naylor,Anthony D Metcalfe,Aleksandar Atansov,Thomas E Robinson,Alan M Smith,Liam M Grover,Miruna Chipara

doi:10.1063/5.0061361

Richard J A Moakes, Jessica J Senior + Show 7 more

Open Access

https://doi.org/10.1063/5.0061361

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Abstract

Skin exhibits a complex structure consisting of three predominant layers (epidermis, dermis, and hypodermis). Extensive trauma may result in the loss of these structures and poor repair, in the longer term, forming scarred tissue and associated reduction in function. Although a number of skin replacements exist, there have been no solutions that recapitulate the chemical, mechanical, and biological roles that exist within native skin. This study reports the use of suspended layer additive manufacturing to produce a continuous tri-layered implant, which closely resembles human skin. Through careful control of the bioink composition, gradients (chemical and cellular) were formed throughout the printed construct. Culture of the model demonstrated that over 21 days, the cellular components played a key role in remodeling the supporting matrix into architectures comparable with those of healthy skin. Indeed, it has been demonstrated that even at seven days post-implantation, the integration of the implant had occurred, with mobilization of the adipose tissue from the surrounding tissue into the construct itself. As such, it is believed that these implants can facilitate healing, commencing from the fascia, up toward the skin surface—a mechanism recently shown to be key within deep wounds.

Highlights

Chronic wounds that arise following trauma, surgery, or disease pose a major healthcare problem, with around 2.2 Â 106 people requiring treatment in the UK alone.[1]
This study reports the use of suspended layer additive manufacturing to produce a continuous tri-layered implant, which closely resembles human skin
It is believed that these implants can facilitate healing, commencing from the fascia, up toward the skin surface—a mechanism recently shown to be key within deep wounds

Summary

Introduction

Chronic wounds that arise following trauma, surgery, or disease pose a major healthcare problem, with around 2.2 Â 106 people requiring treatment in the UK alone.[1] Such wounds are a result of an imbalance within the healing equilibrium, often caused by infection or over production of cytokines within the wound, and preventing the wound from exiting the inflammatory stage of healing.[2,3] as frequently observed in ulceration, this can often drive necrosis of the underlying tissue, forming deep wounds.[4,5,6]. The donor site is not always of sufficient in thickness to compensate for the extent of tissue damage. The technique faces many other challenges, including morbidity, rejection, and strains on donor banks and tissue demand.[8]

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