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Journal of Burn Care & Research: Official Publication of the American Burn Association logoLink to Journal of Burn Care & Research: Official Publication of the American Burn Association
. 2022 Dec 26;44(Suppl 1):S1–S4. doi: 10.1093/jbcr/irac127

Skin Tissue Engineering Advances in Burns: A Brief Introduction to the Past, the Present, and the Future Potential

Faraz Chogan 1,2, Yufei Chen 3,4, Fiona Wood 5,6,7,8,9, Marc G Jeschke 10,11,12,13,
PMCID: PMC10233492  PMID: 36567473

Abstract

Burn injuries are a severe form of skin damage with a significant risk of scarring and systemic sequelae. Approximately 11 million individuals worldwide suffer burn injuries annually, with 180,000 people dying due to their injuries. Wound healing is considered the main determinant for the survival of severe burns and remains a challenge. The surgical treatment of burn wounds entails debridement of necrotic tissue, and the wound is covered with autologous skin substitutes taken from healthy donor areas. Autologous skin transplantation is still considered to be the gold standard for wound repair. However, autologous skin grafts are not always possible, especially in cases with extensive burns and limited donor sites. Allografts from human cadaver skin and xenografts from pig skin may be used in these situations to cover the wounds temporarily. Alternatively, dermal analogs are used until permanent coverage with autologous skin grafts or artificial skins can be achieved, requiring staged procedures to prolong the healing times with the associated risks of local and systemic infection. Over the last few decades, the wound healing process through tissue-engineered skin substitutes has significantly enhanced as the advances in intensive care ensuring early survival have led to the need to repair large skin defects. The focus has shifted from survival to the quality of survival, necessitating accelerated wound repair. This special volume of JBCR is dedicated to the discoveries, developments, and applications leading the reader into the past, present, and future perspectives of skin tissue engineering in burn injuries.

THE PAST: BIRTH OF SKIN TISSUE ENGINEERING AND CONVENTIONAL TREATMENTS FOR BURNS

The year 1975 appears to be a milestone period in the history of skin tissue engineering.1,2 This took place before the Washington National Science Foundation bioengineering panel adopted the “tissue engineering” terminology, and other academics expanded upon it from 1987 to 1993.3–5

The pioneering research on the development of skin tissue engineering commenced 40 years ago (1975) through the efforts of two groups of American researchers who worked concurrently. The effective in vitro cultivation of human epidermal keratinocytes was stated by Rheinwald and Green in a study of so-called “tissue engineering of the skin epidermis.” Their research highlighted the aforementioned cell’s potential to be expanded for grafting through a minor skin biopsy.6,7 Yannas et al concurrently presented a study in 1975 that forested the ground for the emergence of an engineered dermal skin substitute, culminating in “tissue engineering of the dermis”.2,8,9 It took 6 years for both research teams to publicly demonstrate utilizing their tissue-engineered replacements in the clinic to treat severe and extensive burns, however, in distinct ways. The first conquest in grafting employing sheets of cultured epithelium on two patients with severe burns was revealed in research conducted by O’Connor et al.10,11 Following O’Connor’s study, the effective utilization of an artificial dermis in treating 10 patients with severe burn injuries was also revealed by Burke et al.12

THE PRESENT: COMMERCIALLY AVAILABLE TISSUE-ENGINEERED SKIN SUBSTITUTES

Several methods and technologies have been reported, including acellular skin substitutes, cellular allogeneic/autologous skin substitutes, and synthetic and xenogeneic dermal skin substitutes. Figure 1 depicts milestones in the evolution of tissue-engineered skin substitutes for burn treatments.2,13,14

Figure 1.

Figure 1.

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History of skin tissue engineering in burn treatment—“Burn engineering.” CEA, Cultured Epidermal Autograft; MSCs, mesenchymal stem cells.

Acellular skin substitutes have been employed for superficially wounds and burns since the 1980s. These acellular skin substitutes are typically made up of a “dermis” of nylon mesh (Biobrane®) or collagen and an “epidermis” of silicon membrane (Integra™). Another significant progress was the development of a bilayered “artificial skin.” This acellular-based skin substitute is commercially available as Integra™, designed in the 1980s and introduced commercially in 1996 in the United States. Integra™ is the most extensively used artificial biological dermis substitute, with documented good cosmetic and functional results. Infection, on the other hand, is still the most commonly reported Integra™ complication. Other than Integra™, several other commercially available acellular skin substitutes, including Alloderm®, MatriDerm®, and BTM® (Biodegradable Temporizing Matrix), have also been introduced into the market.3,13–15 NovoSorb™ BTM, a synthetic wound dressing, is used to stimulate neodermis growth during the wound closure. BTM is approved for the management of infected wounds, burns, and traumas.16

Synthetic dermal replacements appear to be less extensively used since their emergence in the 1990s for burn therapy. Transcyte®, Dermagraft®, and Biobrane® are some commercial examples of such products. Transcyte® and Dermagraft® are currently off the market. Biobrane®, however, is still applied as a synthetic skin substitute because of its effectiveness in partial-thickness burns.1–3,13–17

Cellular allogeneic skin substitutes are mostly obtained by culturing foreskin fibroblast cells on a mesh or matrix that has been clinically tested. Dermagraft®, Apligraf®, and Graftskin® are a few commercially available examples. Dermagraft® is an allogeneic dermal replacement made from foreskin fibroblast cells combined with biodegradable mesh. Once implemented in the wounds, the cryopreserved fibroblasts at −80°C acquire viability and begin to create growth factors and extracellular matrix (ECM) components.3,13–17

Allogeneic skin replacements, both cellular and acellular, can cover wounds temporarily. In the case of severe burn wounds, the dermal scaffold affords an environment of tissue-guided regeneration; the epidermal replacement some weeks later is achieved with a traditional split skin graft cultured autologous cells or noncultured cell populations. Cellular autologous skin replacements come in two classifications: Cultured Epidermal Autograft (CEA) and Cultured Skin Substitutes (CSS).2,13–16

CEAs have been used in burn therapy since 1981. A small biopsy of healthy skin tissue can be used to grow keratinocytes, which are then expanded into sheets over a few weeks. Cuono reported satisfactory graft take in a full-thickness wound bed by combining cultured epithelial autografts with split-thickness allografts in the mid-1980s. However, they need a delivery vehicle or a supportive dressing because CEA is costly, difficult to handle, and its uptake is unpredictable. Since the dermal–epidermal interface of CEA has not yet fully developed, friction-induced blister development is another issue. In addition, this method has also reported several possible side effects, including scarring, contracture, and hyperkeratosis.2,3,14–16

CSS is a type of autologous graft that includes both epidermal and dermal layers. It offers a permanent covering, has a well-formed dermal–epidermal junction, and is simple to apply. CSS demonstrates clinical outcomes that are close to autograft skin tissue and decrease the necessity for donor skin autograft for wound treatments.18 CSS enables decreased morbidity and mortality in treating burns, chronic wounds, and dermal reconstruction.19 However, CSS costs more and takes a longer time to produce. The most promising autologous dermo-epidermal skin substitute known as PermaDerm™ was established in Cincinnati, Ohio, in the United States.2,3,13–17

Hydrogels are deemed to be safe and biocompatible for burn wound treatment. Hydrogels could be used in irregularly shaped and deep burn wounds. Hydrogels have recently been used as carriers for delivering therapeutics to wounded areas. Growth factors, antimicrobials, and antibiotics are some therapeutics that can be loaded into hydrogel carriers to improve burn wound healing.17,20

ReCell, a cell suspension spray obtained from the dermal–epidermal interface at the point of care, has gained popularity for various indications, including superficial second-degree burns, widely meshed donor sites, and donor sites. The data of the larger multicenter trials are emerging, indicating the efficacy and potential of this cell suspension spray technique. In 2019, this technology became commercially available and shortened patients’ recovery, minimizing pain and scarring while also allowing for faster healing.1,21

Self-Assembled Skin Substitute, a biological skin substitute from fibroblasts and keratinocytes, has entered the clinical arena with promising data. Currently, a large multicenter trial is underway to determine its efficacy.21 All the aforementioned skin substitutes have disadvantages, and no perfect or ideal skin substitute has yet to be developed.

THE FUTURE: ADVANCED APPROACHES IN TISSUE ENGINEERING

Developing skin substitutes and tissue engineering products for human patients is already a reality. Even while tissue-engineered skin substitutes have become a reality in effectively treating severe burns, the fact is that current skin replacements have therapeutic limitations. They all have the same issues: high costs, subpar skin microstructure, and erratic engraftment, particularly in full-thickness burns. The optimistic vision is to develop a dermo-epidermal substitute that vascularizes quickly, accommodates stratifying epidermal grafts optimally on a biodegradable matrix, and is easy to handle by the surgeon.14 The following are some of the most recent advances in tissue engineering, along with a brief description of each:

Stem Cell Therapy

Available skin substitutes are mostly made up of fibroblasts and keratinocytes and cannot thus induce differentiated structures, including hair and sweat glands. Consequently, utilizing the new cell types, eg, endothelial cells, mesenchymal stem cells, and Induced Pluripotent Stem Cells (iPSCs) in engineered skin substitutes, could have promising results.1 The capability of stem cells to self-renew and differentiate into various cell types makes them unique. These characteristics provide stem cells with the ability to regenerate and uniquely replace tissue. Employing co-cultured cells in conjunction with complex three-dimensional (3D) models has recently been introduced to create artificial tissues similar to their native counterparts.1

New Skin Substitutes

Full-thickness skin substitutes such as Tiscover™, DenovoDerm™, and DenovoSkin™ are currently being tested. DenovoSkin™ (CUTISS) is a bioengineered tailored autologous human skin that may be provided from a small patch of healthy skin substitute recognized as an Advanced Therapy Medicinal Product that can be produced from a small skin biopsy. It reduces the number of corrective procedures required in the future, especially in children. DenovoSkin™ is undergoing Phase IIb clinical trials in Switzerland.3,22–24 Currently, there are a variety of skin substitutes on the market. However, a promising new approach is emerging that utilizes biomaterials and stem cells/iPSCs to develop skin substitutes.

Full-Thickness Skin Bioprinting

Skin bioprinting is a relatively new technology with unique properties in skin tissue engineering. 3D bioprinting provides distinct benefits for developing clinically relevant skin constructs. Additionally, the skin has been rebuilt utilizing 3D bioprinting, which entails layer-by-layer deposition of cells on top of supporting materials over damaged tissues. In recent years, stem cell therapies combined with 3D bioprinting and biofabrication techniques have proven to be valuable research platforms in regenerative medicine and burn wound healing.25–27

Skin Spray

Other wound coverage options include in situ cell sprays and skin guns transporting autologous cells to the wounded areas to stimulate reepithelialization. They can be applied for any burn on any part of the body. ReCell, a cell suspension spray obtained from the dermal–epidermal interface at the point of care, has gained popularity for various indications, including superficial second-degree burns, widely meshed donor sites, and donor sites. The data of the larger multicenter trials are emerging, indicating the efficacy and potential of this cell suspension spray technique. In 2019, this technology became commercially available and shortened patients’ recovery, minimizing pain and scarring while also allowing for faster healing.1,28

In Situ Tissue-Engineered Products: Skin Biopens, and Handheld Bioprinters

Handheld bioprinters are advanced coaxial extrusion devices that could be used as 3D bioprinters. Handheld devices deliver cells within a bioink similarly to 3D bioprinters. O’Connell et al presented the prototype of the biopen to fabricate 3D tissue scaffolds in situ and deliver human stem cells for tissue regeneration.29 In 2018, the first handheld 3D bioprinting equipment prototype was unveiled. Hakimi et al successfully demonstrated printing mesenchymal stem cells to improve reepithelialization and neovascularization in porcine models of full-thickness burn.30

CONCLUSION

Recent biomedical advancements have enabled the application of innovative methodologies and new biomaterials to mimic the biological, structural, and functional complexity of native skin. These techniques range from cellular-scale therapies like the delivery of mesenchymal stem cells or growth factors to large-scale biofabrication techniques such as 3D bioprinting, both in the lab and at the point of care. In developing new stem cell-based therapies, concerns like availability, biocompatibility, immunological rejection, vascularization, reinnervation, and adnexal skin structures will have to be addressed. In addition, the pathways employed by new 3D bioprinted skin substitutes to deliver stem cells in the wound are being finessed. The field of stem cell and 3D bioprinting in burn wound healing is promising, and it has the potential to become the next standard of treatment for burn wounds in the future.

Funding: We received funding from the following sources: Canadian Institutes of Health Research (# 123336), CFI Leader’s Opportunity Fund: Project (#25407), National Institutes of Health (#2R01GM087285-05A1), Ontario Institute of Regenerative Medicine, and a generous donation from Toronto Hydro.

Supplement sponsorship: This article appears as part of the supplement “Skin Regeneration and Wound Healing in Burn Patients: Are We There Yet?,” sponsored by Mallinckrodt Pharmaceuticals.

Conflict of interest statement: All authors have no conflicts of interest to declare.

Contributor Information

Faraz Chogan, Sunnybrook Research Institute, Toronto, Ontario, Canada; Institute of Medical Science, University of Toronto, Toronto, Ontario, Canada.

Yufei Chen, Sunnybrook Research Institute, Toronto, Ontario, Canada; Institute of Medical Science, University of Toronto, Toronto, Ontario, Canada.

Fiona Wood, Department of Burns, Perth Children’s Hospital, Nedlands, Western Australia, Australia; Department of Burns, Fiona Stanley Hospital, Murdoch, Western Australia, Australia; Division of Surgery, University of Western Australia, Crawley, Western Australia, Australia; Burn Injury Research Unit, School of Biomedical Sciences, University of Western Australia, Crawley, Western Australia, Australia; Fiona Wood Foundation, Fiona Stanley Hospital, Murdoch, Western Australia, Australia.

Marc G Jeschke, Sunnybrook Research Institute, Toronto, Ontario, Canada; Department of Immunology, Ross Tilley Burn Centre, Sunnybrook Health Sciences Centre, Toronto, Ontario, Canada; Division of Plastic and Reconstructive Surgery, Department of Surgery, Faculty of Medicine, University of Toronto, Toronto, Ontario, Canada; Ross Tilley Burn Centre, Sunnybrook Health Science Centre, Toronto, Ontario, Canada.

References

  • 1. Kareem  NA, Aijaz A, Jeschke MG. Stem cell therapy for burns: story so far. Biologics 2021;15:379. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 2. Chua  AW, Khoo YC, Tan BK, Tan KC, Foo CL, Chong SJ. Skin tissue engineering advances in severe burns: review and therapeutic applications. Burns & trauma. 2016;4: s41038-016-0027-y. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 3. Vig  K, Chaudhari A, Tripathi Set al.  Advances in skin regeneration using tissue engineering. International journal of molecular sciences. 2017;18:789. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 4. Nerem  RM. Tissue engineering in the USA. Med Biol Eng Comput 1992;30:CE8–12. [DOI] [PubMed] [Google Scholar]
  • 5. Langer  R. I articles. Science 1993;260:5110. [DOI] [PubMed] [Google Scholar]
  • 6. Rheinwatd  JG, Green H. Seria cultivation of strains of human epidemal keratinocytes: the formation keratinizin colonies from single cell is. Cell 1975;6:331–43. [DOI] [PubMed] [Google Scholar]
  • 7. Green, H, Kehinde O, Thomas, J. Growth of cultured human epidermal cells into multiple epithelia suitable for grafting. Proc Natl Acad Sci USA 1979;76:5665–8. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 8. Yannas  IV, Burke JF, Huang C, Gordon PL. Correlation of in vivo collagen degradation rate with in vitro measurements. J Biomed Mater Res 1975;9:623–8. [DOI] [PubMed] [Google Scholar]
  • 9. Burke  JF. Design of an artificial skin. I. Basic design principles. J Biomed Mater Res 1980;14:65–81. [DOI] [PubMed] [Google Scholar]
  • 10. O’Connor  N, Mulliken J, Banks-Schlegel S, Kehinde O, Green H. Grafting of burns with cultured epithelium prepared from autologous epidermal cells. The Lancet. 1981;317:75–8. [PubMed] [Google Scholar]
  • 11. Higgins  JP, Thomas J, Chandler J, Cumpston M, Li T, Page MJ, Welch VA, editors. Cochrane handbook for systematic reviews of interventions. John Wiley & Sons; 2019. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 12. Burke  JF, Yannas IV, Quinby WC Jr, Bondoc CC, Jung WK. Successful use of a physiologically acceptable artificial skin in the treatment of extensive burn injury. Annals of surgery. 1981;194:413. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 13. Böttcher-Haberzeth  S, Biedermann T, Reichmann E. Tissue engineering of skin. Burns 2010;36:450–60. [DOI] [PubMed] [Google Scholar]
  • 14. Keyhan  SO, Hemmat S, Asayesh MA, Mehriar P, Khojasteh A. A New Horizon in Facial Plastic Surgery: Skin Tissue-Engineering and Stem Cell Therapy—Reality or Dream?. The American Journal of Cosmetic Surgery. 2014;31:207–24. [Google Scholar]
  • 15. Yu  JR, Navarro J, Coburn JCet al.  Current and future perspectives on skin tissue engineering: key features of biomedical research, translational assessment, and clinical application. Adv Healthcare Mater 2019;8:1801471. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 16. Crowley  K, Balaji S, Stalewski H, Carroll D, Mariyappa-Rathnamma B. Use of Biodegradable Temporizing Matrix (BTM) in large trauma induced soft tissue injury: a two stage repair. J Pediatr Surg Case Rep 2020;63:101652. [Google Scholar]
  • 17. Rahmanian-Schwarz  A, Beiderwieden A, Willkomm L-M, Amr A, Schaller H-E, Lotter O. A clinical evaluation of Biobrane® and Suprathel® in acute burns and reconstructive surgery. Burns 2011;37:1343–8. [DOI] [PubMed] [Google Scholar]
  • 18. Boyce  ST, Warden GD. Principles and practices for treatment of cutaneous wounds with cultured skin substitutes. Am J Surg 2002;183:445–56. [DOI] [PubMed] [Google Scholar]
  • 19. Boyce  ST. Cultured skin substitutes: a review. Tissue Eng 1996;2:255–66. [DOI] [PubMed] [Google Scholar]
  • 20. Kamoun  EA, Kenawy ES, Chen X. A review on polymeric hydrogel membranes for wound dressing applications: PVA-based hydrogel dressings. J Adv Res 2017;8:217–33. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 21. Boa  O, Cloutier CB, Genest Het al.  Prospective study on the treatment of lower-extremity chronic venous and mixed ulcers using tissue-engineered skin substitute made by the self-assembly approach. Adv Skin Wound Care 2013;26:400–9. [DOI] [PubMed] [Google Scholar]
  • 22. Moiemen  N, Schiestl C, Hartmann-Fritsch Fet al.  First time compassionate use of laboratory engineered autologous Zurich skin in a massively burned child. Burns Open 2021;5:113–7. [Google Scholar]
  • 23. Schiestl  C, Meuli M, Vojvodic Met al.  Expanding into the future: combining a novel dermal template with distinct variants of autologous cultured skin substitutes in massive burns. Burns Open 2021;5:145–53. [Google Scholar]
  • 24. Meuli  M, Hartmann-Fritsch F, Hüging Met al.  A cultured autologous dermo-epidermal skin substitute for full-thickness skin defects: a phase I, open, prospective clinical trial in children. Plast Reconstr Surg 2019;144:188–98. [DOI] [PubMed] [Google Scholar]
  • 25. Visconti  RP, Kasyanov V, Gentile C, Zhang J, Markwald RR, Mironov V. Towards organ printing: engineering an intra-organ branched vascular tree. Expert Opin Biol Ther 2010;10:409–20. [DOI] [PMC free article] [PubMed] [Google Scholar]
  • 26. Mironov  V, Kasyanov V, Drake C, Markwald RR. Organ printing: promises and challenges. (2008):93–103. [DOI] [PubMed]
  • 27. Fedorovich  NE, Alblas J, de Wijn JR, Hennink WE, Verbout AJ, Dhert WJA. Hydrogels as extracellular matrices for skeletal tissue engineering: state-of-the-art and novel application in organ printing. Tissue Eng 2007;13:1905–25. [DOI] [PubMed] [Google Scholar]
  • 28. Wood  FM, Giles N, Stevenson A, Rea S, Fear M. Characterisation of the cell suspension harvested from the dermal epidermal junction using a ReCell® kit. Burns 2012;38:44–51. [DOI] [PubMed] [Google Scholar]
  • 29. D O’Connell  C, Di Bella C, Thompson Fet al.  Development of the Biopen: a handheld device for surgical printing of adipose stem cells at a chondral wound site. Biofabrication. 2016;8:015019. [DOI] [PubMed] [Google Scholar]
  • 30. Hakimi  N, Cheng R, Leng Let al.  Handheld skin printer: in situ formation of planar biomaterials and tissues. Lab Chip 2018;18:1440–51. [DOI] [PMC free article] [PubMed] [Google Scholar]

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