Fibroblast Dynamics Following Partial and Deep Burn Injury in a Reconstructed Human Skin Model

Britt van der Leeden; H. Ibrahim Korkmaz; Sanne Roffel; Chopie Hassan; Paul P.M. van Zuijlen; Bouke K.H.L. Boekema; Hans W.M. Niessen; Paul A.J. Krijnen; Susan Gibbs

doi:10.1007/s13770-025-00770-5

Fibroblast Dynamics Following Partial and Deep Burn Injury in a Reconstructed Human Skin Model

Britt van der Leeden
, H. Ibrahim Korkmaz
, Sanne Roffel
, Chopie Hassan
, Paul P.M. van Zuijlen
, Bouke K.H.L. Boekema
, Hans W.M. Niessen
, Paul A.J. Krijnen
, Susan Gibbs^*

^*Corresponding author for this work

Oral Cell Biology

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

Background: Burn injuries are characterized by extensive and prolonged inflammatory responses that impair wound healing, especially in deep burns. Understanding the post-burn fibroblast dynamics in wound healing is critical to improve recovery and minimize scarring. This study aimed to develop a 3D reconstructed human skin (RhS) burn model to mimic superficial, partial-thickness, and deep burn injuries and assess fibroblast behavior over one week.

Methods: RhS consisted of a reconstructed epidermis on a fibroblast populated collagen hydrogel dermis. Papillary (fibroblast activation protein; FAP +) and reticular (FAP-) fibroblasts located themselves in the upper and lower regions respectively within the dermal compartment in line with native skin. Burns of increasing temperatures (70 °C, 110 °C, and 140 °C) were introduced and RhS was analyzed up to one-week post-burn.

Results: Lactate dehydrogenase (LDH) staining for metabolic active cells in tissue sections enabled distinct histological zones to be observed in RhS with partial (110 °C) and deep burns (140 °C): including a viable fibroblast zone (zone V), a mixed dead and viable fibroblast zone (zone M), and a necrotic zone (zone N). Fibroblast migration from the wound edge (M) into the viable area (V) and changes in fibroblast phenotype, particularly an increase in papillary fibroblast markers (FAP +), were observed, with a marked increased expression of Ki67 in fibroblasts at the burn wound edge (M). Additionally, burn temperature influenced the protein secretion of inflammatory and tissue remodeling mediators SAA, NGAL, MRP8/13, ICAM-1, CCL20, and MMP-9.

Conclusion: The RhS burn model enables complex fibroblast dynamics post-burn to be investigated in an organotypic model, providing a platform for studying burn pathophysiology which can be used for evaluating potential therapeutic strategies for enhancing burn wound healing and minimizing scarring in the future.

Original language	English
Pages (from-to)	185-198
Number of pages	14
Journal	TERM - Tissue Engineering and Regenerative Medicine
Volume	23
Issue number	1
Early online date	25 Nov 2025
DOIs	https://doi.org/10.1007/s13770-025-00770-5
Publication status	Published - Jan 2026

Bibliographical note

Publisher Copyright:
© Korean Tissue Engineering and Regenerative Medicine Society 2025.

Keywords

Fibroblast activating protein
Lactate dehydrogenase
Papillary fibroblasts
Phosphorylated ribosomal protein S6

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10.1007/s13770-025-00770-5

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van der Leeden, B., Korkmaz, H. I., Roffel, S., Hassan, C., van Zuijlen, P. P. M., Boekema, B. K. H. L., Niessen, H. W. M., Krijnen, P. A. J., & Gibbs, S. (2026). Fibroblast Dynamics Following Partial and Deep Burn Injury in a Reconstructed Human Skin Model. TERM - Tissue Engineering and Regenerative Medicine, 23(1), 185-198. https://doi.org/10.1007/s13770-025-00770-5

@article{d3949320e03047f89fe48912eb486828,

title = "Fibroblast Dynamics Following Partial and Deep Burn Injury in a Reconstructed Human Skin Model",

abstract = "Background: Burn injuries are characterized by extensive and prolonged inflammatory responses that impair wound healing, especially in deep burns. Understanding the post-burn fibroblast dynamics in wound healing is critical to improve recovery and minimize scarring. This study aimed to develop a 3D reconstructed human skin (RhS) burn model to mimic superficial, partial-thickness, and deep burn injuries and assess fibroblast behavior over one week.Methods: RhS consisted of a reconstructed epidermis on a fibroblast populated collagen hydrogel dermis. Papillary (fibroblast activation protein; FAP +) and reticular (FAP-) fibroblasts located themselves in the upper and lower regions respectively within the dermal compartment in line with native skin. Burns of increasing temperatures (70 °C, 110 °C, and 140 °C) were introduced and RhS was analyzed up to one-week post-burn.Results: Lactate dehydrogenase (LDH) staining for metabolic active cells in tissue sections enabled distinct histological zones to be observed in RhS with partial (110 °C) and deep burns (140 °C): including a viable fibroblast zone (zone V), a mixed dead and viable fibroblast zone (zone M), and a necrotic zone (zone N). Fibroblast migration from the wound edge (M) into the viable area (V) and changes in fibroblast phenotype, particularly an increase in papillary fibroblast markers (FAP +), were observed, with a marked increased expression of Ki67 in fibroblasts at the burn wound edge (M). Additionally, burn temperature influenced the protein secretion of inflammatory and tissue remodeling mediators SAA, NGAL, MRP8/13, ICAM-1, CCL20, and MMP-9.Conclusion: The RhS burn model enables complex fibroblast dynamics post-burn to be investigated in an organotypic model, providing a platform for studying burn pathophysiology which can be used for evaluating potential therapeutic strategies for enhancing burn wound healing and minimizing scarring in the future.",

keywords = "Fibroblast activating protein, Lactate dehydrogenase, Papillary fibroblasts, Phosphorylated ribosomal protein S6",

author = "\{van der Leeden\}, Britt and Korkmaz, \{H. Ibrahim\} and Sanne Roffel and Chopie Hassan and \{van Zuijlen\}, \{Paul P.M.\} and Boekema, \{Bouke K.H.L.\} and Niessen, \{Hans W.M.\} and Krijnen, \{Paul A.J.\} and Susan Gibbs",

note = "Publisher Copyright: {\textcopyright} Korean Tissue Engineering and Regenerative Medicine Society 2025.",

year = "2026",

month = jan,

doi = "10.1007/s13770-025-00770-5",

language = "English",

volume = "23",

pages = "185--198",

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T1 - Fibroblast Dynamics Following Partial and Deep Burn Injury in a Reconstructed Human Skin Model

AU - van der Leeden, Britt

AU - Korkmaz, H. Ibrahim

AU - Roffel, Sanne

AU - Hassan, Chopie

AU - van Zuijlen, Paul P.M.

AU - Boekema, Bouke K.H.L.

AU - Niessen, Hans W.M.

AU - Krijnen, Paul A.J.

AU - Gibbs, Susan

PY - 2026/1

Y1 - 2026/1

N2 - Background: Burn injuries are characterized by extensive and prolonged inflammatory responses that impair wound healing, especially in deep burns. Understanding the post-burn fibroblast dynamics in wound healing is critical to improve recovery and minimize scarring. This study aimed to develop a 3D reconstructed human skin (RhS) burn model to mimic superficial, partial-thickness, and deep burn injuries and assess fibroblast behavior over one week.Methods: RhS consisted of a reconstructed epidermis on a fibroblast populated collagen hydrogel dermis. Papillary (fibroblast activation protein; FAP +) and reticular (FAP-) fibroblasts located themselves in the upper and lower regions respectively within the dermal compartment in line with native skin. Burns of increasing temperatures (70 °C, 110 °C, and 140 °C) were introduced and RhS was analyzed up to one-week post-burn.Results: Lactate dehydrogenase (LDH) staining for metabolic active cells in tissue sections enabled distinct histological zones to be observed in RhS with partial (110 °C) and deep burns (140 °C): including a viable fibroblast zone (zone V), a mixed dead and viable fibroblast zone (zone M), and a necrotic zone (zone N). Fibroblast migration from the wound edge (M) into the viable area (V) and changes in fibroblast phenotype, particularly an increase in papillary fibroblast markers (FAP +), were observed, with a marked increased expression of Ki67 in fibroblasts at the burn wound edge (M). Additionally, burn temperature influenced the protein secretion of inflammatory and tissue remodeling mediators SAA, NGAL, MRP8/13, ICAM-1, CCL20, and MMP-9.Conclusion: The RhS burn model enables complex fibroblast dynamics post-burn to be investigated in an organotypic model, providing a platform for studying burn pathophysiology which can be used for evaluating potential therapeutic strategies for enhancing burn wound healing and minimizing scarring in the future.

AB - Background: Burn injuries are characterized by extensive and prolonged inflammatory responses that impair wound healing, especially in deep burns. Understanding the post-burn fibroblast dynamics in wound healing is critical to improve recovery and minimize scarring. This study aimed to develop a 3D reconstructed human skin (RhS) burn model to mimic superficial, partial-thickness, and deep burn injuries and assess fibroblast behavior over one week.Methods: RhS consisted of a reconstructed epidermis on a fibroblast populated collagen hydrogel dermis. Papillary (fibroblast activation protein; FAP +) and reticular (FAP-) fibroblasts located themselves in the upper and lower regions respectively within the dermal compartment in line with native skin. Burns of increasing temperatures (70 °C, 110 °C, and 140 °C) were introduced and RhS was analyzed up to one-week post-burn.Results: Lactate dehydrogenase (LDH) staining for metabolic active cells in tissue sections enabled distinct histological zones to be observed in RhS with partial (110 °C) and deep burns (140 °C): including a viable fibroblast zone (zone V), a mixed dead and viable fibroblast zone (zone M), and a necrotic zone (zone N). Fibroblast migration from the wound edge (M) into the viable area (V) and changes in fibroblast phenotype, particularly an increase in papillary fibroblast markers (FAP +), were observed, with a marked increased expression of Ki67 in fibroblasts at the burn wound edge (M). Additionally, burn temperature influenced the protein secretion of inflammatory and tissue remodeling mediators SAA, NGAL, MRP8/13, ICAM-1, CCL20, and MMP-9.Conclusion: The RhS burn model enables complex fibroblast dynamics post-burn to be investigated in an organotypic model, providing a platform for studying burn pathophysiology which can be used for evaluating potential therapeutic strategies for enhancing burn wound healing and minimizing scarring in the future.

KW - Fibroblast activating protein

KW - Lactate dehydrogenase

KW - Papillary fibroblasts

KW - Phosphorylated ribosomal protein S6

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DO - 10.1007/s13770-025-00770-5

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C2 - 41288956

AN - SCOPUS:105022865809

SN - 1738-2696

VL - 23

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JO - TERM - Tissue Engineering and Regenerative Medicine

JF - TERM - Tissue Engineering and Regenerative Medicine

IS - 1

ER -

Fibroblast Dynamics Following Partial and Deep Burn Injury in a Reconstructed Human Skin Model

Abstract

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