Regenerative Scar-Free Skin Wound Healing

Abstract

Scar formation is a common consequence of skin injuries that lead to a wide range of adverse effects including physical deformities and psychological disorders. Studies demonstrate that mammalian fetal skin in early gestation is capable of regenerating itself after injury without any scar formation. A number of potential therapies have been developed to reduce scar formation in cutaneous wounds based on differences between the process of adult and fetal wound healing. The ideal approach to eliminate scar formation after skin injury is to use a pro-regenerative matrix along with growth factors and cell types that induce regeneration rather than repair. This work provides a comprehensive review of engineering approaches to scar-free wound healing with emphasis on the use of pro-regenerative biomaterials to minimize scar formation in skin injuries.

Impact Statement

Millions of people every year develop scars in response to skin injuries after surgery, trauma, or burns with significant undesired physical and psychological effects. This review provides an update on engineering strategies for scar-free wound healing and discusses the role of different cell types, growth factors, cytokines, and extracellular components in regenerative wound healing. The use of pro-regenerative matrices combined with engineered cells with less intrinsic potential for fibrogenesis is a promising strategy for achieving scar-free skin tissue regeneration.

Introduction

Millions of people annually develop scars in response to skin injuries after surgery, trauma, or skin burns. These skin injuries result in significant undesired physiological and psychological effects. According to the World Health Organization, more than 11 million burn injuries are reported worldwide annually that require medical attention.¹ According to a fact sheet released by the American Burn Association, more than 480,000 burn injuries occur in the United States each year that require treatment.² It is common for a burn injury to form scar tissue, although the incidence of scar formation is not known.³ In some studies, the prevalence of hypertrophic scar (HTS) formation was estimated between 32% and 72% after burn injuries.⁴ The market for anti-scarring medication is in excess of $12 billion annually.⁵ Based on the results of a cohort study, the cost of anti-scar treatment in postburn patients is approximately $6000 per patient.⁶ Previous studies indicate that scarring dramatically affects the quality of life of patients with skin injuries.⁷

Excessive deposition of connective tissue (mainly collagen) during wound healing leads to scar formation (Figure 1).⁸ It was shown for the first time in 1971 that fetal lamb wounds, before day 120 of gestation, heal without scar formation.⁹ In a similar manner, it was shown that skin injuries in the human fetus in early pregnancy heal to form normal skin tissue without scar formation.¹⁰ Engineering approaches that mimic the process of fetal wound healing can lead to enabling technologies that minimize or eliminate scar formation after injury. Many factors including cellular elements, soluble growth factors, and insoluble extracellular matrix (ECM) proteins as well as mechanics of the tissue are involved in fetal wound healing. Recent studies indicate that the application of a single factor, such as transforming growth factor (TGF)-β3 or interleukin-10 (IL-10), is not sufficient for scar-free wound healing.¹¹ Studies centered on the process of fetal regeneration indicate that scar-free wound healing can be realized by combining multiple cellular and morphogenetic factors within a fetal-mimetic matrix or scaffold. In this review, we provide an update on engineering strategies for scar-free wound healing and discuss the role of different cell types, growth factors, cytokines, and extracellular components in regenerative wound healing with emphasis on the potential of pro-regenerative biomaterials in developing skin equivalents. Finally, this review ends with the future of scar-free skin tissue engineering.

FIG. 1.

Stages of wound healing. (A) Coagulation: platelets in the presence of fibrin form a stable clot. Platelets also produce platelet-derived growth factor that along with bacterial products attract inflammatory cells to the site of injury. (B) Inflammation: neutrophils are recruited to the wound bed. Leucocytes secrete proinflammatory cytokines IL-1, IL-6, and TNF-α that exacerbate the inflammation. M2 macrophages are found mostly in the late phase of inflammation and produce anti-inflammatory cytokine IL-10. (C) Proliferation: granulation tissue is the hallmark of this stage, which is composed of myofibroblasts, new capillaries, and Col III. (D) Remodeling: it is the final stage of wound healing in which Col III is replaced by the stiffer bundles of Col I with MMPs as the main effectors. The end result of wound repair is scar formation at the site of injury. IL, interleukin; Col III, collagen type III; TNF, tumor necrosis factor. Color images are available online.

Adult Versus Fetal Wound Healing

Human fetal skin in early pregnancy can regenerate after injury without forming a scar tissue.¹⁰ Understanding the differences between the fetal and adult skin wound healing can lead to scar-free skin regenerative therapies. These are illustrated in Figure 2, which demonstrates the differences in cell types, growth factors, cytokines, and ECM composition.

FIG. 2.

Dissimilarities in cell types, growth factors, and extracellular matrix components between adult and fetal wounds. Color images are available online.

Cells

Fibroblasts

They are the most important cell type in the process of wound healing.^12,13 Driskell et al. showed that a unique fibroblast lineage in the lower dermis (reticular layer) is responsible for connective tissue deposition after skin injury.¹⁴ Lineage tracing by Rinkevich et al. led to identification of a single fibroblast lineage (Engrailed-1) as the main effector cell in the production of ECM during wound healing as well as embryonic development in mouse dorsal skin.¹⁵ This unique fibroblast lineage, which was identified by the cell surface marker adenosine deaminase complexing protein-2 (CD26), was 1% of the dermal fibroblasts at the early stage of gestation but its fraction increased to >75% in postnatal skin.¹⁵ Furthermore, it was established that this fibroblast lineage played a major role in the switch from scar-free to scar-forming wound repair in midgestation (Fig. 3).¹⁶ Inhibition of CD26 enzymatic activity reduced scar formation in mouse skin injuries.¹⁵ CD26, which is also known as dipeptidyl peptidase-IV, is a cell surface exopeptidase that cleaves X-proline dipeptides from the N-terminus of oligopeptides.¹⁷ Stromal cell-derived factor-1 (SDF-1), which is also known as C-X-C motif chemokine-12 (CXCL12), is a substrate for CD26. SDF-1 is a strong chemoattractant for the recruitment of CXCR4 (C-X-C chemokine receptor type-4) expressing mesenchymal stem cells (MSCs) to the injury site.¹⁸ It has been shown that the overexpression of hypoxia-induced factor-1 (HIF-1) due to ischemia after tissue injury leads to the upregulation of SDF-1 and subsequent recruitment of MSCs to the site of injury to stimulate regeneration.^19,20 Ghadge et al. showed in a cardiac ischemia model that the overexpression of HIF-1α by administration of prolyl hydroxylase inhibitor resulted in the upregulation of SDF-1 with subsequent improvement in neovascularization and reduction in the size of myocardial scar.²¹ They also detected higher expression levels of anti-inflammatory M2 macrophage phenotype at the site of cardiac infarction, which may have played a role in the regeneration of cardiac tissue.²¹

FIG. 3.

Contribution of Engrailed-1⁺ (En1) fibroblasts (shown in red color) to matrix deposition and scar formation during skin development in the mouse model of wound healing. The En1⁺ fibroblast accounts for 1% of the dermal fibroblasts at the early stage of gestation, but its fraction increases to >75% in postnatal skin. Color images are available online.

It has been reported that SDF-1 plays an important role in neovascularization of injured tissue by recruitment of endothelial progenitor cells.²² Rabbany et al. reported that the delivery of SDF-1 in an alginate hydrogel improved wound closure and mitigated scar formation in a pig skin injury model.²³ Hu et al. used microarray analysis to show that CXCR4 signaling (SDF-1 receptor) is upregulated in the skin wound of adult mice 12 h postinjury compared with fetal mice.²⁴ Ding et al. reported higher expression of SDF-1/CXCR4 signaling in HTSs caused by burn injuries and the injection of interferon α-2b, which downregulates SDF-1 expression, led to remodeling of the scar tissue.²⁵ These results indicate that more research is needed to understand cell signaling pathways that regulate SDF-1/CXCR4 axis and its interaction with CD26 in scar formation of cutaneous wounds.

Fetal fibroblasts play a different function during wound healing compared with adults. Fetal fibroblasts proliferate faster and synthesize predominately collagen type III (Col III) during wound repair.²⁶ Myofibroblasts differentiated from fibroblasts and characterized by the expression of α-smooth muscle actin (α-SMA), which play a role in scar formation in adult wounds, are absent in fetal wound healing.^26,27 Recently, it has been shown that myofibroblasts have plasticity and they are reprogrammed to fat cells upon exposure to bone morphogenetic proteins.²⁸ These studies indicate that morphogens and cytokines can be used to modify the function of fibroblasts and reverse the scarring process in adult dermal wound injuries. It should be mentioned that there exists a critical wound depth for scar formation. Dunkin et al. investigated the effect of wound depth on scar formation in a clinical trial by creating superficial and deep skin wounds in the lateral hip of 113 volunteers.²⁹ They reported a critical injury depth of 0.56 ± 0.03 mm with deeper injuries leading to fibrosis.

Skin is anatomically composed of three layers, namely epidermis, dermis, and hypodermis with the dermis further divided into superficial (papillary) and deep (reticular) dermis. Wang et al. investigated the properties of fibroblasts isolated from the superficial and deep layers of human normal dermis and HTS tissue in an in vitro tissue culture system.³⁰ They reported that deep dermal fibroblasts were larger, proliferated slower, and expressed higher levels of TGF-β1, connective tissue growth factor (CTGF), α-SMA, and collagen but lower levels of collagenase in comparison with superficial fibroblasts.³⁰ They further reported that deep dermal fibroblasts and fibroblasts isolated from HTS tissue had similar properties.³⁰ Therefore, deep dermal fibroblasts may be responsible for scar formation in relatively deep skin injuries.

Inflammatory cells

Reduced inflammation is the hallmark of fetal wound healing. Neutrophils are the initial inflammatory cells recruited to the site of injury.³¹ It has been shown that a lower number of neutrophils are recruited to the site of injury in fetal wounds compared with adults. Fetal neutrophils express lower levels of adhesion molecules compared with adults, which in turn decreases their ability to migrate to the wound bed.^32,33 Macrophages contribute to cell growth, differentiation, ECM formation, and remodeling in both adult and fetal wound healing by serving as reservoirs for the release of growth factors³⁴; however, their recruitment to the wound bed is reduced in early gestation during fetal development.³⁵ There are fewer mast cells in fetal skin wounds with fewer granules in their cytoplasm.³⁶ Mast cells are believed to play a role in transition from scar-free to scar-forming in fetal wound healing. There was less scar formation during wound healing in a mouse model deficient in skin mast cells compared with the wild type.³⁶ Furthermore, the application of mast cell lysate to a skin injury in a mouse model of scarless wound healing distorted the healing process. Jeong et al. reported that intraperitoneal injection of poly(deoxyribonucleotide), which is known to reduce mast cell degranulation and release of inflammatory cytokines during the inflammatory phase, decreased the number of inflammatory cells and scar size in a rat model of skin wound healing.³⁷ Walraven et al. performed immunohistochemical staining on human adult and second-trimester fetal skin tissues and lymph nodes and reported lower number of macrophages, dendritic and T cells, mast and Langerhans cells in the fetal tissue compared with the adult.³⁸ They showed using the CD45 leukocyte marker that the fetal skin had lower number of leukocytes but higher cell number in the lymph nodes. They further reported a higher ratio of M2 (anti-inflammatory) to M1 (proinflammatory) macrophages in the fetal skin compared with the adult, even though the overall number of macrophages in the fetal skin was lower than that in the adult. They also reported no significant differences in vascular density between the fetal and adult skin. They concluded from the results that the lower number of immune cells in the fetal skin is not due to lower vascular density or the immune system immaturity.

Wounds in the oral mucosa, which heal with less scarring, are also characterized by a lower number of macrophages.³⁹ Wilgus et al. reported that the expression level of inflammatory mediators cyclooxygenase-2 (COX2) and prostaglandin-E2 (PGE2) was significantly lower in scarless wound healing compared with those with scarring.⁴⁰ Furthermore, they reported that the application of PGE2 to the fetal wound increased the expression of TGF-β1 and scarring.

Platelets

Platelets vary functionally in different stages of gestation. Olutoye et al. reported that there is less platelet aggregation in pig fetal skin than the adult with lower concentrations of TGF-β and platelet-derived growth factor (PDGF). The high amount of hyaluronic acid (HA) in the fetal skin can be attributed to these functional differences.⁴¹ Studies on the effect of platelet-rich plasma (PRP) on wound healing have produced controversial results. Kushida et al. reported that PRP induces differentiation of dermal fibroblasts to myofibroblasts with subsequent increase in wound contraction.⁴² Caceres et al. observed that the expression of myofibroblast differentiation marker α-SMA in gingival fibroblasts increased upon exposure to PRP for 12 h in a dose-dependent manner.⁴³ Chellini et al. reported that the addition of PRP to fibroblasts cultured in a differentiation medium supplemented with TGF-β1 attenuated myofibroblast differentiation.⁴⁴ This effect was attributed to the inhibition of TGF-β1/SMAD3 signaling pathway upon the addition of PRP, which was mediated by the vascular endothelial growth factor (VEGF) receptor-1. Therefore, the effect of PRP on wound healing remains inconclusive, and more research is needed to understand the role of PRP on scar formation in skin injuries.

Stem cells

Higher number of MSCs is detected in fetal wound healing.⁴⁵ Exosomes derived from adipose MSCs upregulate the expression of Col III, TGF-β3, and matrix metalloproteinases-3 (MMP3) in skin wounds, which leads to less scarring.⁴⁶ Kim and Hemmati reported that the co-culture of MSCs and macrophages induced M2 phenotype in the macrophages, which led to the upregulation of IL-10 and IL-6 expressions and downregulation of IL-12 and tumor necrosis factor-α (TNF-α).⁴⁷ These results indicate that MSCs have an immune-modulatory effect on wound healing. Sabapathy et al. reported that mouse skin wounds treated with Wharton's jelly MSCs cultured on a decellularized amniotic membrane (AM) had less scarring and more tissue regeneration after 10 days.⁴⁸ Liu et al. reported that intradermal injection of MSCs attenuated scar formation in a rabbit model of skin wound healing.⁴⁹ They showed increased expression of collagen type I (Col I), α-SMA, TNF-α stimulated gene/protein6, inducible nitric oxide synthase, indoleamine 2,3-dioxygenase, COX2, and IL-10 after injection of MSCs in the wound bed. Subcutaneous injection of adipose-derived stem cells-conditioned medium prevented fibrosis and scar tissue formation by inhibition of the P38/MAPK signaling pathway.⁵⁰ On the contrary, Doi et al. reported that injection of umbilical cord blood MSCs and Wharton's jelly MSCs to the wound bed of nude mice failed to attenuate scarring.⁵¹ However, the failure of MSCs to reduce scarring in Doi's experiments may be related to the absence of immune system in the nude mouse.

Extracellular matrix

The ECM comprising proteins, glycosaminoglycans (GAGs), and proteoglycans (PGs) provides a dynamic scaffold for cell migration, adhesion, proliferation, differentiation, and maturation. The mechanical properties of ECM play a pivotal role in activation of fibroblasts during wound healing. It has been shown that matrix stiffness increases with gestational age as the number of collagen cross-links increases.^27,52 The expression of lysyl oxidase that catalyzes collagen cross-linking is downregulated in early-gestation fetal fibroblasts.^27,52 Furthermore, fibroblasts cultured in vitro on stiff hydrogels showed higher expression of α-SMA compared with soft hydrogels.^53,54 Goffin et al. reported that the granulation tissue in the mouse model of skin injury begins to express α-SMA at 20 kPa tissue stiffness.⁵⁵ The focal adhesion kinase (FAK) pathway has been implicated as a link between mechanical forces and scar formation. Wong et al. showed that scarring after skin injury in FAK-knockout mice was less than the wild type.⁵⁶ Furthermore, they reported that the expression of TGF-β1, α-SMA, and monocyte chemoattractant protein-1 (MCP-1) was downregulated and the number of macrophages was lower in FAK-deficient mouse compared with the wild type.⁵⁶ Their results indicate that mechanical loading activated FAK leading to the expression of MCP-1, which in turn induced the recruitment of inflammatory cells and a fibrotic reaction. Therefore, scar formation can be induced through an inflammatory process by mechanical activation of FAK.

Col I is the most abundant protein in the fetal and adult skin. Fetal skin is characterized by a high ratio of Col III/Col I. Col III is thought to have a critical role in regenerative healing as observed in the mouse blastema during digit tip regeneration.⁵⁷ Fetal wounds have a high GAG and high-molecular-weight hyaluronic acid (HMW-HA) content compared with adult wounds. HMW-HA reduces angiogenesis and inflammation, whereas low-molecular-weight hyaluronic acid (LMW-HA) is involved in scar formation.⁵⁸ HA persists for longer times in fetal wound healing. Longaker et al. measured the level of HA in adult and fetal ewe wounds and reported that HA persisted in fetal wounds for 3 weeks, whereas it disappeared from adult wounds after 7 days.^59,60 Higher amounts of HA in the blastema of lizard and zebrafish during tail regeneration is evidence of HA importance in regenerative wound healing.^61,62

There is also a difference in the concentration of PGs between fetal and adult wounds. Decorin (DCN) expression increases during skin development and reaches its highest amount in adulthood. It is interesting to note that DCN has antifibrotic effects as it is an inhibitor of TGF-β1.¹³ Higher incidence of scarring in deep wounds is attributed to the lower DCN content of reticular dermis.⁶³ The PG fibromodulin (FMOD) is downregulated in adult wounds, but it is found in high amounts in normal fetal ECM.⁶⁴ High levels of FMOD was measured in the fetal wound of rodents, which decreased the expression of TGF-β1 and consequently reduced scarring.⁶⁵ Zheng et al. showed that intradermal injection of human recombinant FMOD in adult rodent or porcine cutaneous wounds decreased the scar size.⁶⁶ Furthermore, they observed that FMOD had dual effect on TGF-β1 signaling by simultaneously increasing the contraction of fibroblasts to decrease wound size and suppressing fibrosis. Furthermore, they showed in FMOD-deficient mouse model of cutaneous wound that TGF-β3 expression in fibroblasts increased within the first day postinjury, which in turn decreased fibroblast motility, delayed wound closure, increased wound size, and scarring.⁶⁷ Based on these results, Zheng et al. concluded that the antimotility effect of TGF-β3 promoted scar formation in the early stages of wound healing, whereas its antifibrotic effect impeded scar formation in the later stages.⁶⁷ In fact, the failure of a single TGF-β3 application or inhibition of TGF-β1 expression in clinical trials for wound healing can be attributed to this dual effect. However, in the failed clinical trials, TGF-β3 was injected in the cutaneous wound bed in the first day after injury.^11,66,67 Therefore, the timing of TGF-β3 delivery should be considered in future clinical trials.

Elastin, which is responsible for elasticity and resilience of connective tissue, is expressed 22 weeks after gestation during fetal development.⁶⁸ Impaired production of elastin fibers in adult cutaneous injuries leads to changes in mechanical properties of the skin.⁶⁹ The role of elastin in fetal and adult wound healing is not well understood and needs to be investigated in future studies.⁶⁹

Fibronectin as a major glycoprotein found in various connective tissues including skin plays many roles during wound healing.⁷⁰ The role of fibronectin in cell–cell and cell–matrix interactions has been thoroughly investigated. The organization of fibronectin, which is connected to the intracellular actin filaments by integrin cell surface receptors, is dependent on the activity of FAK.⁷¹ The fetal wound is distinguished from the adult by early deposition of fibronectin, which facilitates cell attachment to the matrix and cell migration within the matrix by association with the adhesion glycoprotein tenascin. As an indication of the role of fibronectin in re-epithelialization, integrin receptors are upregulated on keratinocytes in fetal cutaneous lesions for interaction with fibronectin and tenascin.^72,73 Furthermore, the reduced production of fibronectin via the expression of IL-4 in atopic dermatitis delayed re-epithelialization in mouse model of wound healing.⁷⁴

Growth factors and cytokines

Transforming growth factor-β

TGF-β signaling is required for wound repair and regeneration as the lack of TGF-β expression leads to a chronic nonhealing wound. Inhibition of TGF-β signaling prevents regeneration of limbs in amputated axolotls.⁷⁵ The three isoforms of TGF-β family of growth factors, namely TGF-β1, TGF-β2, and TGF-β3, are encoded by different genes, but their action is propagated through the SMAD intracellular pathway. Binding of the three TGF-β isoforms to TGF-β receptors I and II initiates a signaling cascade resulting in phosphorylation and activation of SMAD2, SMAD3, and co-SMAD4, their nuclear localization, and the expression of SMAD-specific genes.^76,77

The CTGF is known as a downstream mediator of TGF-β.⁷⁸ A single application of CTGF or TGF-β into mouse subcutaneous tissue resulted in transient formation of granulation tissue, whereas co-injection of CTGF and TGF-β led to long-term formation of fibrotic tissue.⁷⁹ TGF-β1 and TGF-β2 are involved in scar formation as inhibition of these isoforms by the addition of exogenous antibodies reduced scarring after skin injury. Conversely, TGF-β3 is believed to have an antifibrotic effect⁸⁰ as the ratio of TGF-β3/TGF-β1 is found to be higher in fetal wounds compared with adults.^11,81 However, a phase III clinical trial based on recombinant TGF-β3 therapy to reduce scarring in wound healing failed to meet the primary and secondary endpoints. The failure of TGF-β3 clinical trial is indicative of more complex roles for the TGF-β family of growth factors, which needs to be explored in future studies.¹¹

Wnt/β-catenin

Wingless protein signaling pathway plays a critical role in embryonic development and organogenesis,⁸² and it is thought to contribute to fibrosis of different organs including skin. Beyer et al. showed that the accumulation of β-catenin in fibroblasts as a result of increased expression of Wnt3 and Wnt10b led to fibrosis.⁸³ Wnt3 induced differentiation of fibroblasts to myofibroblasts in vitro and increased the expression of TGF-β through SMAD2, suggesting a cross talk between the TGF-β signaling and Wnt/β-catenin pathway.⁸⁴ Carre et al. reported that fetal fibroblasts show higher expression of TGF-β3 in response to Wnt3a, whereas postnatal fibroblasts show higher TGF-β1 expression.⁸⁵ There is debate on the effect of the Wnt/β-catenin pathway on wound healing. The Wnt/β-catenin pathway is believed to be required for hair follicle formation during prenatal as well as postnatal development.^86,87 Collins et al. showed that epidermal activation of β-catenin in vivo in mouse skin reprogrammed adult dermis to a neonatal state with higher fibroblast density and deposition of an immature matrix.⁸⁶ Topical application of liposomal Wnt3a in adult mouse model of wound healing resulted in faster healing, which was correlated with the activation of dermal Wnt signaling.⁸⁸ Driskell and colleagues showed that dermal β-catenin is upregulated during wound healing, which resulted in the growth of reticular fibroblasts lacking the ability for hair follicle formation.^14,89 However, ablation of β-catenin expression resulted in regeneration of hair follicles in adult mouse model of wound healing after skin injury.^14,89 More studies should be performed in the future to understand the precise role of the Wnt/β-catenin signaling pathway in cutaneous wound healing.

Heparin-binding epidermal growth factor

Heparin-binding epidermal growth factor (HB-EGF) has been reported to play a major role in re-epithelialization during wound healing by increasing migration of keratinocytes.⁹⁰ HB-EGF decreases during gestation in the rat skin. The expression of HB-EGF changes markedly in transition from scar-forming to scar-free wound healing.⁹¹

Platelet-derived growth factor

PDGF consists of five isoforms that are produced by platelets, macrophages, endothelial cells, fibroblasts, keratinocytes, and smooth muscle cells.⁸ PDGF along with TGF-β stabilize the newly formed blood capillaries in the granulation tissue.⁸ However, PDGF is not necessary for the initiation of angiogenesis as it has been reported that basic fibroblast growth factor and VEGF have a stronger angiogenic effect compared with PDGF.⁹² PDGF plays a role in re-epithelialization and stimulates proliferation and differentiation of fibroblasts to myofibroblasts.⁹² PGDF is involved in the remodeling phase of wound healing by increasing the expression of MMPs.^8,92 PDGF with two B subunits (PDGF-BB or becaplermin) is the only recombinant growth factor approved by the Food and Drug Administration (FDA) for the treatment of chronic wounds⁹² and as a profibrotic agent.⁹³ It has been reported that the expression of PDGF-BB gene is increased with gestational age in fetal rat with a sharp increase in expression during the transition from scarless to scar-forming wound healing.⁹¹ Furthermore, there is a difference in the expression of PDGF-BB growth factor in fetal and adult wounds after injury as PDGF-BB disappeared after 24 h in fetal wounds, whereas it persisted for up to 72 h in adult wounds.⁹⁴

Fibroblast growth factor

Fibroblast growth factor (FGF) is a family of growth factors consisting of 23 members.^8,92 The most characterized FGFs in wound healing are FGF-2 (basic FGF), FGF-7, FGF-9, and FGF-10.⁹² FGFs are released by many cell types and interact with a group of receptors that have tyrosine kinase activity.⁸ It is well established that FGF-2 plays a role in angiogenesis, migration of macrophages and fibroblasts, as well as re-epithelialization.^8,92 Ortega et al. showed that wound healing is delayed in FGF-2-knockout mice.⁹⁵ FGF-7 or keratinocyte growth factor-1 (KGF-1) and FGF-10 (KGF-2) are postulated to play a role in re-epithelialization and later stages of angiogenesis by stimulation of endothelial cells and induction of VEGF expression.⁹² Despite this hypothesis, FGF-7-knockout mice showed normal wound healing.⁹⁶ FGF-9 is necessary for the development of hair follicles as FGF-9 expressed by γδT cells upregulated Wnt expression in fibroblasts and subsequently induced hair follicle formation in a mouse model of wound healing.⁹⁷ Furthermore, the overexpression of FGF-9 increased hair neogenesis by two- to threefolds.⁹⁷ In human skin lesions, the formation of hair follicles does not occur after scarring, which can be attributed to the lack of FGF-9 expressing γδT cells in human dermis.⁹⁷ Whitby and Ferguson reported that FGF-2 is absent in fetal wounds; however, their measurement method could not detect low levels of FGF-2.⁹⁴ Later, it was reported that the expression of FGF-5, FGF-7, and FGF-10 increased during fetal skin development in rat while FGF-2 and FGF-9 remained unchanged.⁹⁸ Furthermore, they showed that the overall expression of FGFs was downregulated in scarless fetal wound healing.

Vascular endothelial growth factor

VEGF family of growth factors are expressed by many cell types in the wound bed, including endothelial cells, fibroblasts, smooth muscle cells, platelets, keratinocytes, neutrophils, and macrophages.⁹⁹ VEGF-A, which is generally called VEGF, is the key growth factor in the early stage of angiogenesis after tissue injury.^8,92,99 Injury to the tissue leads to disruption of blood capillaries and hypoxia, which leads to the upregulation of HIF-1α expression and subsequent expression of VEGF and its receptors in the wound site to stimulate angiogenesis.⁹⁹ VEGF is not only necessary in the early phase of angiogenesis, but it also contributes to scar formation. It is reported that the expression of VEGF was downregulated in scarless fetal wounds and the application of exogenous VEGF resulted in scar formation.¹⁰⁰

Interleukins

IL-10 is known to mitigate fibrosis as a potent anti-inflammatory factor in different organs, including the heart, lung, kidney, liver, and intestine.¹⁰¹ IL-10 expression is upregulated in scarless fetal wounds, and wound healing in IL-10-deficient fetal mouse proceeds with scar formation.¹⁰² Recently, it has been shown that IL-10 stimulates HMW-HA production in adult fibroblasts through a signal transducer and activator of transcription-3-dependent signaling pathway, thus imparting a regenerative phenotype to the fibroblasts.¹⁰³ Therefore, the antifibrotic effect of IL-10 is not solely due to its anti-inflammatory properties. It should be mentioned that the recombinant human IL-10 (Prevascar) clinical trial for wound healing in which the cytokine was injected intradermally to the wound edge was not successful.¹¹ Although IL-10 therapy reduced scar formation after 1 month in clinical trials, scarring was similar to the control group over long-term.¹¹ Lower levels of proinflammatory cytokines IL-6 and IL-8 are detected in fetal wounds compared with adults. Liechty et al. reported that IL-6 and IL-8 mRNA were detectable in adult wounds for up to 72 h compared with 12 h in fetal wounds, and the addition of IL-6 to fetal wounds led to scar formation.^104,105 IL-6 is believed to promote inflammation through MCP-1 as well as direct activation of macrophages.¹⁰⁴ IL-8 is a potent chemoattractant for neutrophils and stimulates re-epithelialization via increasing the migration and proliferation of keratinocytes.⁹² IL-8 also plays a role in the remodeling phase of wound healing by upregulating the expression of MMPs.⁹²

Extracorporeal environment

Amniotic fluid (AF), which is enriched in HA and growth factors including epidermal growth factor (EGF), TGF-α, and insulin-like growth factor 1 (IGF-1), provides a sterile environment for fetal growth and development.¹⁰⁶ Longaker et al. showed that AF not only contained high levels of HA, but it also stimulated HA production in the fetal wound.¹⁰⁷ We previously discussed that HA has a major role in wound regeneration. It has been reported that stem cells derived from human AF, which were identified as CD-117-positive cells, accelerated re-epithelization after injection to the wound edge in a mouse model and attenuated scar formation.¹⁰⁸ The AM is also shown to have antimicrobial and antifibrotic effects.¹⁰⁹ Murphy et al. fabricated a hydrogel composed of solubilized AM and HA (SAM-HA) and investigated the regenerative properties of the hydrogel in a full-thickness mouse wound. They reported that the hydrogel accelerated wound re-epithelialization and closure. Higher amount of angiogenesis was observed in SAM-HA-treated wounds compared with nontreated or HA-only-treated wounds.¹¹⁰ Despite the regenerative properties of the AM and AF and their role in wound healing, it is well established that scarless wound healing is an intrinsic characteristic of the fetal skin.¹⁵ Longaker et al. made cutaneous wounds on adult sheep skin, which was transplanted into a fetus. They reported scar formation in the adult skin while the adjacent fetal skin healed without scarring.¹¹¹

Advances in ECM-Based Pro-regenerative Materials

ECM not only provides structural support for the cells, but it also plays a critical role in cell fate determination through interactions with integrin receptors on the cell surface. These interactions regulate the strength of cell adhesion to ECM, cell polarization, migration, proliferation, differentiation, and cell phenotype.^112,113 The ideal response to skin injury is regeneration and the formation of a normal tissue structure. However, our body's reaction to injury is repair rather than regeneration in which a fibrotic tissue (scar) replaces the normal skin tissue.¹¹⁴ In fetal wound healing during early gestation, a regenerative matrix is formed that leads to the formation of a scar-free normal skin tissue. Recapitulation of ECM properties of the fetal wound has been the subject of numerous studies.^45,115 The list of clinically approved cellular and acellular regenerative constructs as skin substitutes is provided in Tables 1^116–125 and 2,^126–136 respectively. The focus of this section is on those combinations of biomaterials, cells, and growth factors that restore the normal architecture of the skin tissue after injury.

Table 1.

List of Clinically Approved Cellular Tissue Constructs for Skin Regeneration

Product name	Comments	Refs.
Apligraf^®	First FDA-approved bilayer skin substitute composed of neonatal fibroblasts derived from foreskin seeded in bovine type I collagen scaffold on which neonatal keratinocytes are cultured; used for venous ulcers and diabetic wounds	^129,130
denovoSkin™	Fibroblasts and keratinocytes harvested from the patient's skin, cultured in vitro, and seeded in a collagen scaffold; ongoing phase II clinical trial; used for burn injuries	¹³¹
Epicel^®	Autologous keratinocytes cultured in vitro to produce sheets composed of 2–8 layers and bonded to petroleum gauze; used for deep full-thickness dermal burns in which at least 30% of the body surface area are affected by the injury	¹³²
Orcel^®	Allogeneic fibroblasts and keratinocytes cultured in a porous bovine collagen type I sponge as a bilayer skin substitute; approved by the FDA for donor site wounds in burn patients	¹³³
StrataGraft™	Adult progenitor keratinocytes cultured in vitro to form a fully stratified epidermal layer on a dermal matrix; used for deep burn injuries; ongoing phase III clinical trial	¹³⁴
TransCyte^®	Neonatal fibroblasts from foreskin seeded on a collagen-coated nylon mesh and bonded to a silicone substrate; temporary skin substitute for partial-thickness burns	¹³⁵
Hyalograft 3D	Autologous fibroblasts seeded on a benzylic ester of hyaluronic acid scaffold; used as a skin substitute in combination with Laserskin^® (autologous keratinocyte substitute) for chronic foot ulcers	^132,136
Dermagraft^®	Neonatal fibroblasts from foreskin cultured on a resorbable polyglactin mesh and cryopreserved; used for full-thickness burn wounds	¹³⁷
Bioseed-S	Autologous cultured keratinocytes in a fibrin sealant; applied to chronic wounds	¹³⁸

Table 2.

List of Clinically Approved Acellular Tissue Constructs for Skin Regeneration

Product name	Comments	Refs.
Biobrane™	A semi-permeable membrane composed of a nylon layer coated with peptides derived from porcine collagen type I and bonded to a thin porous silicone membrane; applied as a temporary dressing to superficial burn and donor site wounds	¹³⁹
Integra^® Omnigraft™	A bilayer skin substitute composed of cross-linked bovine collagen and chondroitin-6-sulfate coated onto a silicone membrane to prevent fluid loss; first approved by the FDA for life-threatening burn injuries in 1996; approved by the FDA in 2012 for reconstruction of burn scars; approved by the FDA in 2016 for treating diabetic foot ulcers	^140,141
Alloderm^®	Human cadaveric skin processed to remove the epithelial layer and cells in the dermal layer without changing the matrix and basement membrane structure, and freeze-dried; approved by the FDA for burns; also used for abdominal wall and breast reconstruction	^142–144
Hyalomatrix	Composed of a benzyl ester of hyaluronic acid (HYAFF) coated with a semi-permeable silicone membrane; HA provided by bacterial fermentation; approved by the FDA for partial- and full-thickness wounds.	¹⁴⁵
Oasis^® Wound Matrix	Derived from porcine acellular small intestinal mucosa; approved by the FDA for management of partial- and full-thickness wounds including pressure venous ulcers, diabetic ulcers, and traumatic and surgical wounds	¹⁴⁶
PriMatrix	Derived from fetal bovine dermis; the only substitute with high level of collagen type III; approved by the FDA for the management of partial- and full-thickness wounds	^147–149

Hyaluronan

HA is synthesized in the plasma membrane by the action of three enzymes, namely hyaluronan synthase-1 (HAS-1), HAS-2, and HAS-3 with nucleotide sugars uridine diphosphate (UDP) glucuronic acid and UDP-N-acetyl-glucosamine as the substrate. HAS-1 and HAS-2 take part in the synthesis of HMW-HA, whereas HAS-3 is involved in the synthesis of LMW-HA.¹³⁷ Secondary hydrogen bonding in the HA backbone creates hydrophobic patches, which form random coils or twists in the structure for interconnection with other HA chains to generate a network. HA interacts with cells through two surface receptors, namely CD44 and the receptor for HA-mediated motility (RHAMM).¹³⁸ HA plays a crucial role in different stages of wound healing, but its biological function is dependent on it molecular weight. HMW-HA (>500 kDa) is present in normal skin to maintain moisture content. HMW-HA is associated with low inflammation, high Col III expression, and high TGF-β3 activity, whereas LMW-HA is associated with high inflammation, high Col I expression, and increased differentiation to myofibroblasts.¹³ Rayahin et al. reported that LMW-HA polarized macrophages to the proinflammatory phenotype, whereas HMW-HA induced the anti-inflammatory phenotype.¹³⁹ Treatment of epidural fibrosis scars in a rat model of laminectomy and discectomy with HMW-HA reduced fibrosis and granulation tissue compared with the control group with no treatment.¹⁴⁰ It has been shown that HMW-HA is fragmented to intermediate- and LMW-HA by the action of hyaluronidase and oxygen/nitrogen free radicals in the wound bed.¹⁴¹ RHAMM has a higher affinity for binding to LMW-HA compared with HWM-HA, and the disruption of this interaction by the application of topical RHAMM-mimetic peptides to a rat model of excisional wound decreased the number of macrophages, fibroblasts, and the expression levels of TGF-β1, α-SMA, and Col I through inhibition of the FAK pathway.¹⁴² As discussed in previous sections, the FAK pathway is associated with induction of fibrosis by the upregulation of MCP-1 and subsequent increase in inflammation.⁵⁶ Scheibner et al. reported that LMW-HA stimulated the innate immune response via toll-like receptor-2 (TLR-2) activation, whereas HMW-HA inhibited TLR-2 signaling mediated inflammation.¹⁴³

It is well established that HA plays a regenerative role in scarless fetal wound healing. The presence of HA in early blastoma of Xenopus tadpoles and zebrafish is indispensable for tail regeneration, and the inhibition of HA synthesis leads to impaired tail regeneration.^62,144

HA used in biomedical applications is obtained from rooster combs or by bacterial fermentation.¹⁴⁵ Hyalomatrix is a FDA-approved HA-based biomaterial for wound healing applications.¹⁴⁶ Hyalomatrix is composed of two layers, a thin semi-permeable silicone membrane on the top that covers the skin and controls skin moisture and a matrix based on benzyl ester of HA, which is in direct contact with the wound bed. Hyalomatrix can be used in partial- or full-thickness wounds as a temporary dressing for wound healing before skin grafting.¹³² Voigt and Driver showed in a systematic review and meta-analysis of randomized clinical trials that HA and its derivatives have a positive effect on healing of burns, chronic and epithelial surgical wounds.¹⁴⁷ Five dermal substitutes including Hyalomatrix were compared for scarring in a porcine model of full-thickness wound healing with no dermal substitute as the control group.¹⁴⁸ No significant difference in scar formation was observed between the dermal substitutes and the control group. Hyalograft 3D is a cellular skin substitute in which autologous fibroblasts are seeded onto a benzylic ester of HA scaffold. Hyalograft 3D in combination with autologous keratinocytes were evaluated for wound healing in a randomized clinical trial for diabetic foot ulcers.¹²³ According to the results, dorsal foot ulcers treated with Hyalograft 3D showed improved wound healing compared with the standard treatment while no improvement was observed in plantar ulcers. However, the extent of scarring was not reported in the clinical study. Hu et al. reported that strands of HA grafted to the wound bed improved healing in a rat model of full-thickness skin wound, suppressed TGF-β1 expression, and reduced scarring.¹⁴⁹

Decorin

DCN, the most abundant PG in the adult human skin, is a member of the small leucine-rich proteoglycan (SLRP) family. DCN decorates collagen fibrils.¹³ DCN is composed of a protein core containing 12 leucine-rich repeats (LRRs) with a GAG chain (dermatan or chondroitin sulfate [CSCL]) attached to the N-terminus. DCN is believed to play a crucial role in collagen fibrillogenesis via LRR 4–6/Col I interaction.^13,150,151 Furthermore, DCN protein core serves as a natural inhibitor of TGF-β1 interaction with cell surface receptors,^13,150 leading to reduced fibrosis and scar formation.¹⁵² DCN is found in different layers of dermis, but its expression is highest in the papillary (superficial) layer, as papillary fibroblasts produce more DCN in vitro than fibroblasts isolated from the reticular dermis.⁶³ Seidler et al. reported that intraperitoneal injection of DCN protein core in immune-deficient mouse with squamous carcinoma xenografts attenuated tumor growth with downregulation of epidermal growth factor receptor (EGFR) and increased tumor cell apoptosis.¹⁵³ Furthermore, they demonstrated that DCN blocked the EGFR pathway and induced caspase-3 activity, a mediator of apoptosis, which eventually led to programmed cell death in tumor cells.

Persistence of fibroblasts in granulation tissue leads to scar formation, which is attributed to resistance of reticular fibroblasts to apoptotic effects of DCN. Honardoust et al. reported that DCN-treated superficial fibroblasts expressed higher levels of proapoptotic factors, including histone-1, caspase-1, caspase-8, and p53, and consequently experienced more apoptosis than deep dermal fibroblasts.¹⁵⁴ The level of DCN produced by fibroblasts derived from HTSs in patients with grade II and III burns was lower than that of normal skin.¹⁵⁵ Kwan et al. reported that deep dermal fibroblasts had higher expression of microRNA-181b than the superficial fibroblasts, and blocking the expression of this microRNA increased DCN expression.¹⁵⁶ Taken together, these results explain why deep dermal injuries are more prone to fibrosis compared with superficial skin lesions.

DCN is known to suppress intracellular expression of β-catenin via interaction with MET receptor in cancer cells.¹⁵⁷ As we previously discussed, the accumulation of β-catenin in fibroblasts is associated with fibrosis. Hence, the inhibition of fibrosis by DCN can be attributed to its interaction with the Wnt/β-catenin signaling pathway.

The antifibrotic effect of DCN in wound healing should be considered in designing biomaterials for skin tissue engineering. LRRs in the protein core of DCN interact with many growth factors and cell surface receptors.¹⁵⁰ Therefore, biological function of DCN in the process of wound healing can be simulated with peptides that mimic specific amino acid sequences of the protein core in DCN. Jeon et al. demonstrated that a surgical glue based on fusion of the mussel adhesive protein and DCN-derived collagen binding peptides inhibited scar formation in a rat model of wound healing.¹⁵⁸

Fibromodulin

FMOD, another member of the SLRP family, is isolated from bovine articular cartilage.¹⁵⁹ FMOD structure is composed of a protein core containing 11–12 LRRs as binding sites for other proteins and GAG chains (keratin sulfate).¹⁶⁰ FMOD binds to collagen through LRR11 site with high affinity or LRR7 site with low affinity and its role in collagen fibril assembly along with other SLRPs is well established. It has been shown that FMOD binding to collagen is essential in later stages of fibrillogenesis in the mouse tendon by acting as a cofactor for lysyl oxidase to regulate fiber thickness.¹⁶¹ FMOD as well as DCN have binding sites for TGF-β to sequester or modulate its function.¹⁶² The differential expression of FMOD in fetal and adult wounds is indicative of its role in scarless wound healing.⁶⁴ Zheng et al. reported retarded wound closure and significant scarring in FMOD-deficient mouse.⁶⁷ It was also reported that high expression of FMOD in mouse model of wound healing is associated with low levels of TGF-β1 and vice versa.⁶⁵ Furthermore, Zheng et al. reported that FMOD enhanced migratory and contractile phenotype of fibroblasts by increasing the expression of CTGF through SMAD2/3 phosphorylation. FMOD also decreased scarring-associated factors by inhibition of noncanonical TGF-β1 signaling.

These results indicate that FMOD enhances wound closure and attenuates scar formation by regulating the activity of TGF-β1.⁶⁶ In that regard, FMOD or FMOD-mimetic peptides with binding sites for TGF-β1 could be beneficial to skin tissue engineering and wound healing. It has been demonstrated that the application of peptides with binding sites for TGF-β1 to skin wounds in animal models recapitulated ECM architecture and regeneration of the normal skin.¹⁶³

Collagen type III

Among the 28 types of collagen in mammalian tissues, Col I and Col III are the most abundant in the skin tissue.¹⁶⁴ Col III, which is a fibrillar collagen composed of three α1(III) chains, is present during embryonic development and wound healing, but it is replaced by Col I in the later stages of fetal development.¹⁶⁵ Fleischmajer et al. demonstrated that Col I serves as the fibril building block and Col III serves as the regulator of fibril diameter and growth during fibrillogenesis in adult human skin.¹⁶⁶ Liu et al. observed reduced number and increased size variability of collagen fibrils in Col III mutant mouse model of wound healing. They also observed that ∼60% of Col III-mutant mice developed spontaneous skin lesions.¹⁶⁷ In humans, mutations in pro-collagen III gene leads to Ehlers–Danlos syndrome IV in which skin wounds heal but with higher scarring.¹⁶⁸ Volk et al. reported higher number of myofibroblasts in granulation tissue of heterozygous Col III-deficient mouse after 7 days of wound healing compared with normal mouse, indicating a link between Col III and differentiation of myofibroblasts.¹⁶⁹ It has been shown that the ratio of Col III to Col I is higher in the absence of myofibroblasts in scarless fetal wounds.¹⁷⁰ Furthermore, the level of Col III increased in the mouse model of digit tip regeneration.^57,171 Papillary dermis or the superficial layer of skin also contains elevated ratios of Col III to Col I compared with the deep reticular layer,¹⁷² which explains the scar-free or low-scar healing of superficial wounds. Taken together, it can be concluded that Col III plays a beneficial role in scar-free skin regeneration and as a skin substitute. Currently, the only commercially available skin substitute containing significant amounts of Col III (30%) is PriMatrix, which is derived from fetal bovine dermis. PriMatrix is shown to stimulate the formation of vascular granulation tissue in full-thickness wounds,^134–136 and macrophages seeded on PriMatrix polarized to M2c phenotype, which is associated with less fibrosis.¹⁷³ The application of PriMatrix to severely traumatic skin injuries resulted in complete re-epithelialization with minimal scarring.¹⁷⁴

Steering Macrophages Toward Regeneration

Macrophages are the key mediators of inflammatory response after tissue injury. Macrophages can take a proinflammatory M1 phenotype or an anti-inflammatory M2. M1 phenotype in macrophages is induced by interferon-γ (IFNγ), lipopolysaccharides (LPS), TNF, and granulocyte–macrophage colony-stimulating factor. M1 macrophages secrete IL-1B, IL-6, and TNF-α, and they are identified by increased expression of IL-12, IL-23, CD80, and CD86. M2 phenotype in macrophages is induced by IL-4, IL-13 (M2a phenotype), immune complexes (M2b phenotype) and IL-10, and glucocorticoids (M2c phenotype). M2 macrophages are characterized by elevated expression of IL-10, CD163, CD204, and CD206. Each M2 subtype (M2a, M2b, and M2c) plays a unique role in resolution of inflammation, tissue remodeling, regeneration, fibrosis, angiogenesis, and promotion of wound healing.^175–177 M1 macrophages are present in the early phase of inflammation to remove the microbial and tissue debris from the wound bed. M2 macrophages, which are present in the late phase of inflammation and referred to as “wound healing macrophages,” are involved in the formation of granulation tissue, remodeling, and termination of inflammation. Persistence of M1 macrophages in the wound bed leads to chronic inflammation and nonhealing wounds like chronic venous and diabetic ulcers. Macrophages are known to contribute to tissue regeneration after injury like limb regeneration in axolotl.¹⁷⁸

Macrophages in wound healing can be classified, based on their function in scar formation or resolution, into profibrotic and antifibrotic phenotypes. Profibrotic phenotypes like M2a secrete anti-inflammatory and fibrotic factors such as IL-10 and TGF-β. Conversely, antifibrotic phenotypes secrete IL-10, MMPs, and tissue inhibitor of matrix metalloproteinases (TIMPs) that degrade the ECM.^179–181 Fallowfield et al. showed in a mouse model of fibrotic liver that scar-associated macrophages (SAM) secrete MMP13 to resolve the fibrotic tissue.¹⁸² Furthermore, they observed that SAM-depleted mice had decreased MMP expression, which delayed resolution of the fibrosis.¹⁸² Ramachandran et al. identified a population of macrophages outside the M1/M2 classification with the ability to resolve hepatic fibrosis in a mouse model of the disease.¹⁸³ This subpopulation, derived from LY-6C^high circulatory monocytes, was characterized by CD11B^high/F4/80^intermediate/LY-6C^low compared with the CD11B^intermediate/F4/80^high resident hepatic macrophages in an uninjured control. It was shown that this macrophage subpopulation, which was involved in tissue remodeling and resolution of fibrosis, secreted high levels of MMP9, MMP12, IGF-1, and glycoprotein Nmb.

Lurier et al. analyzed different phenotypes of macrophages including M0, M1, M2a, and M2c by RNA sequencing and reported that M2c macrophages express higher levels of genes related to angiogenesis such as SERPINA1, SRPX2, MMP8, and VCAN.¹⁸⁴ They also reported that M2c macrophages secrete higher levels of enzymes for matrix remodeling such as MMP7, MMP8, and TIMP1. They concluded that M2c macrophages could potentially attenuate fibrosis.¹⁸⁴ M2c macrophages are considered as “deactivated” because they produce immunosuppressive factor IL-10 during wound healing.¹⁷⁵ Grinberg et al. proposed a new subtype of angiogenic M2d macrophage phenotype such that M1 macrophages can be converted to M2d by co-stimulation with TLR and adenosine A2a receptor agonists, leading to high expression and production of IL-10 and VEGF.^185,186

Material properties such as porosity and pore size, microstructure, hydrophobicity, surface chemistry, and mechanical properties affect polarization of macrophages.¹⁸⁷ For example, Blakney et al. showed that decreasing compressive modulus of polyethylene glycol hydrogels conjugated with cell-adhesive RGD peptide (PEG-RGD) reduced the activation of the seeded macrophages.¹⁸⁸ Cha et al. reported that encapsulation of human monocytes in gelatin methacryloyl (GelMA) hydrogels in the presence of IL-4 induced macrophage polarization to M2 phenotype, whereas encapsulation in polyethylene glycol diacrylate (PEGDA) hydrogel induced M1 polarization.¹⁸⁹ They also showed that this effect was mediated by integrin α2β1 cell surface receptors interacting with ligands present in GelMA but not PEGDA. Inhibition of integrin-ligand interactions in GelMA reversed the macrophage phenotype to that observed in PEGDA.

It is known that scaffolds with 30–40 μm pore size induce M2 macrophage polarization, which leads to higher extent of angiogenesis and less fibrosis.¹⁹⁰ This indicates the importance of scaffold porosity and pore size for induction of a regenerative response to wound healing. ECM-derived biomaterials are believed to polarize macrophages predominantly to M2 phenotype, although the method of processing and modification can mitigate this response.¹⁹⁰ Badylak et al. compared the response of macrophages with scaffolds derived from porcine small intestinal submucosa (SIS) with or without cross-linking with carbodiimide (CDI-SIS) in a rat model.¹⁹¹ They reported that SIS scaffolds without treatment polarized macrophages to M2 phenotype, which in turn induced tissue remodeling, whereas the CDI-treated scaffolds polarized macrophages to M1 phenotype, which led to chronic inflammation. They attributed the change in macrophage phenotype to changes in collagen microstructure in SIS scaffolds with CDI cross-linking.

In another study, murine bone marrow-derived macrophages were seeded on matrices derived from digested, decellularized porcine small intestinal submucosa (SIS), brain, urinary bladder, liver, skeletal muscle, esophagus, colon, and skin.¹⁹² The matrices derived from the brain, SIS, esophagus, urinary bladder, and colon polarized macrophages to the anti-inflammatory M2 phenotype, whereas the dermal matrix polarized the macrophages to the proinflammatory M1 phenotype. He et al. reported that acellular mouse dermal matrices increased M2 macrophage polarization with the upregulation of MMP3, MMP9, EGF, IGF, PDGF, TGF-β, and VEGF expression.¹⁹³ They further showed that the degradation of collagen in dermal matrices produced peptides that led to the activation of acid-sensing pathway-associated lysosomal adaptor protein (LAMTOR1), which in turn mediated a regenerative response during wound healing by M2 macrophage polarization in the presence of IL-4. Vasconcelos et al. observed different macrophage responses to chitosan in a mouse model of wound healing depending on the degree of acetylation (DA; 5% and 15%).¹⁹⁴ Based on their results, porous chitosan scaffolds with 5% DA polarized macrophages to M2 phenotype with low expression of proinflammatory cytokines such as IL-6 and TNF-α, whereas the opposite response was observed in 15% DA scaffolds (polarization to M1 phenotype). Furthermore, the macrophage phenotype in 15% DA chitosan scaffolds was switched to M2 by conjugation of the scaffolds with the anti-inflammatory or pro-resolution Resolvin D1 (RvD1) chemical mediator.¹⁹⁵ They concluded that immune response of biomaterials can be modulated toward regeneration by conjugation with pro-resolution agents.

Keratin is also shown to induce regeneration after injury with less scarring.¹⁹⁶ Fearing and Van Dyke compared macrophage polarization on chamber slides coated with keratin with those coated with collagen in vitro and reported that keratin induced M2 polarization with higher IL-10 and lower IL-6 and IL-1B expressions.¹⁹⁶ Taraballi et al. reported that macrophages seeded on collagen scaffolds functionalized with CSCL had higher expression of anti-inflammatory cytokines IL-10, mannose receptor-1, arginase-1, and TGF-β compared with the unmodified collagen scaffold.^197,198 Furthermore, they showed that the CSCL effect can be attributed to inhibition of the LPS/CD44/NF-κB signaling pathway. In the absence of CSCL, LPS bind to CD44 receptors on the surface of macrophages leading to phosphorylation of NF-κB and activation of proinflammatory genes. In CSCL scaffolds, CSCL competes with LPS and disrupts the signaling pathway for activation of proinflammatory genes.^197,198 Castellano et al. showed that electrospun polyhydroxybutyrate (PBH) scaffolds polarize macrophages to M2 phenotype in a rat model.¹⁹⁹ They also observed that M1 macrophages, initially present in the wound bed of PBH-implanted animals, were depleted after 3 days. However, M1 macrophage depletion did not happen in the control animals implanted with Matriderm scaffolds, which led to further scarring. They reported that combination of PBH scaffold and human dermoepidermal skin equivalent implanted in the wound resulted in higher neoangiogenesis and graft survival.

Prospect

The worldwide market for scar treatment has been predicted to reach $35 billion by 2023.²⁰⁰ The largest share of this market belongs to postsurgical scars and topical treatments.²⁰¹ Among topical products, silicone-based matrices are shown to have the fastest growth rate in the market.²⁰¹ Currently, the most common approaches to reduce scarring, based on scar management guidelines, are pressure therapy, silicone gels and sheets, intra-lesion corticosteroid injection, and surgical removal of the scar.²⁰² Approximately 32–72% of burn injuries in the United States lead to scarring.^2,4 The gold standard for treatment of full- and deep partial-thickness burn wounds is skin grafting.²⁰³ Lack of adequate skin grafts and donor site complications have increased the demand for tissue engineered skin substitutes.²⁰⁴

The role of skin substitutes in wound injuries is to accelerate healing while minimizing scar formation. Although commercially available skin substitutes protect the wound from infection and regulate moisture content, they lack optimization with respect to regeneration and scarring. The ideal construct for skin regeneration should be cellular to regenerate the lost cells and should contain growth factors encapsulated in a skin-mimetic matrix to minimize scaring and optimize mechanical and barrier properties (Fig. 4). Currently, autologous and neonatal foreskin-derived fibroblasts are being used as the cell source in skin tissue constructs.^205–207

FIG. 4.

Strategies for inducing regeneration rather than repair after skin injury. The combination of pro-regenerative materials with optimum mechanical properties along with the right cell types and soluble molecules paves the way toward regeneration. Color images are available online.

As discussed in previous sections, fibroblasts selected based on the expression of embryonic marker Engrailed-1 (En1) and characterized by CD26 surface marker are involved in deposition major connective tissue, scar formation, and transition from scar-free to scar-forming wound healing in murine fetal skin.^15,208 It is reported that the En1 fibroblasts increase from <1% in early gestation to ∼75% postnatally.¹⁵ In late gestation (transition time), ∼22% of the fibroblasts are En1 positive (Fig. 3),¹⁵ and majority of fibroblasts in the adult skin express CD26 surface marker.²⁰⁹

Considering these facts, a question that comes to mind is what is the role of CD26-negative fibroblasts in wound healing? Lichtenberger et al. showed by flow cytometry that CD26⁺/Sca1⁺ fibroblasts were the most abundant cells in the regression (telogen) phase of hair follicles and their population decreased in the growth (anagen) phase. Conversely, CD26⁻/Sca1⁻ fibroblasts were the most abundant cells in the anagen phase.²¹⁰ These findings indicate a possible role for CD26⁻/Sca1⁻ fibroblasts in wound healing and skin regeneration. Lineage tracing experiments have identified multiple subpopulation of MSCs that can function as progenitors for myofibroblasts.²¹¹ These include (a) CD26⁺ fibroblasts, (b) PDGFRα⁺/Sca1⁺/Dlk1⁺ fibroblasts, (c) PDGFRα⁺/Sca1⁺/ADAM12⁺ perivascular mesenchymal cells, and (d) adiponectin⁺ adipocytes. These findings suggest that the regenerative properties of skin substitutes can be improved by optimizing the ratio of different fibroblast subpopulations in the construct. For example, lower ratios of CD26⁺ fibroblasts in the skin substitute could lead to scar-free skin wound healing. Future studies should be focused on understanding of the effect of different subpopulations of fibroblasts on scarring and the fate of wound healing.

It has been reported that the number of stem cells in scar-free fetal wounds is higher than that in adult wounds. However, embryonic stem (ES) and induced pluripotent stem (iPS) cells are limited by teratoma formation in vivo and tumorigenesis.²¹² MSCs are known to increase angiogenesis and attenuate inflammation and scar formation in chronic wounds, but they are limited by their heterogeneity with variable proliferative rates and differentiation ability.²¹³ Kuroda et al. identified multipotent cells, called multilineage-differentiating stress enduring (MUSE) cells, from human MSCs including dermal fibroblasts, adipose derived MSCs, and bone marrow-derived MSCs, which are characterized by the expression of stage-specific embryonic antigen-3 marker. They reported that MUSE cells have the ability to differentiate into the three different germ layers, namely ectoderm, mesoderm, and endoderm, but they do not produce teratoma in mouse unlike ES and iPS cells.²¹⁴ It was shown that keratinocytes, fibroblasts, and melanocytes generated from differentiation of MUSE cells can be used to reconstitute a skin substitute.^215,216

In addition to optimizing cell types and their ratio, the matrix in a skin substitute for wound healing should be engineered for regeneration. A variety of natural materials like collagen, HA, fibrin, chitosan, and alginate as well as synthetic materials like polypyrrole, poly(ɛ-caprolactone), and polylactic-glycolic acid have been developed for generating a skin substitute for wound healing.^118,217 Among synthetic materials, silicone-based polymers have been used extensively in skin substitutes as a stand-alone matrix or as a part of the tissue construct. Silicone gel sheets are reported to reduce scarring in clinical applications.²¹⁸ As mentioned in previous sections, biomaterials affect the process of wound healing by altering the gene expression profile of the cells through stimulation or inhibition of cell surface receptors and control of specific intracellular pathways. Therefore, selection of optimum biomaterial composition like combination of HMW-HA, high ratio of Col III to Col I, and conjugation of fibromodulin- and DCN -mimetic peptides can significantly affect the resolution of wound healing. Mechanical off-loading devices are shown to be effective in minimizing scar formation. Mechanical properties of the matrix are important factors that should be considered in the selection of biomaterial for skin wound healing. Longaker et al. showed that the application of a stress-shielding silicone device on postsurgical wounds decreased scar formation in a controlled randomized clinical trial.²¹⁹

To summarize, pro-regenerative matrices combined with engineered cells with less intrinsic potential for fibrogenesis bring us one step closer to scar-free skin tissue regeneration.

Footnotes

Acknowledgments

This work was supported by research grants to E.J. from the National Science Foundation under Award Number CBET1403545 and the National Institute of Arthritis and Musculoskeletal and Skin Diseases of the National Institutes of Health under Award Number AR063745. The content is solely the responsibility of the authors and does not necessarily represent the official views of the National Institutes of Health.

Disclosure Statement

No competing financial interests exist.

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