Paracrine anti‐fibrotic effects of neonatal cells and living cell constructs on young and senescent human dermal fibroblasts

Senescent cells observed in the area of chronic wounds have been proposed to affect wound healing. Therapeutic approaches against chronic wounds include, among others, the local application of living cell constructs (LCCs), containing fibroblasts and/or keratinocytes. Accordingly, the aim of the present work was to examine the effects of factors secreted by early passage neonatal fibroblasts and LCCs—in the form of a conditioned medium (CM)—on senescent adult dermal fibroblasts regarding functions related to the healing process, i.e., cell proliferation, alpha‐smooth muscle actin and metalloproteinase expression, and collagen synthesis. Target cells were fibroblasts senescent either due to subsequent divisions (replicative senescence) or due to an exogenous stress (stress‐induced premature senescence). No effect on the proliferation of senescent fibroblasts was observed, as expected. All CMs were found to inhibit overall collagen synthesis both in early passage and in senescent fibroblasts. The LCC‐derived CM was found to be more potent than fibroblast‐derived CMs and, furthermore, to inhibit alpha‐smooth muscle actin expression. In conclusion, these results may indicate anti‐contractile and anti‐fibrotic activities of factor(s) secreted by neonatal skin fibroblasts, and more intensely by LCCs on adult donor‐derived fibroblasts. These activities seem to persist during senescence of the target cells.     

Chronic wounds – is cellular ‘reception’ at fault? Examining integrins and intracellular signalling

As with all physiologic processes, chronic wounds are associated with unique intracellular and cellular/extracellular matrix (ECM) receptor types and signalling messages. These cellular receptors mediate responses of the epidermis to provisional wound matrix and change in form and number in cases of impaired wound healing. Integrins are the major cell‐surface receptors for cell adhesion and migration and epidermal keratinocytes express several integrins that bind ECM ligands in provisional wound ECM. Integrin receptors and more particularly integrin clusters and focal adhesion points appear to influence epidermal and dermal cell matrix interactions, cell motility, cell phenotype and ultimate healing trajectory. In chronic wounds, a variety of changes in receptors have been identified: decreased integrin α5β1 receptors affect the integration of fibronectin and subsequent keratinocyte migration; integrin αvβ6 stimulate transforming growth factor (TGF)‐β and may increase the susceptibility to ulceration and fibrosis; however, TGF‐β signal receptors have been found to be dysfunctional in many chronic wounds; additionally receptor interactions result in increased senescent cells including fibroblasts, myofibroblasts and even keratinocytes – this produces a degradative ECM and wound bed and corrosive chronic wound fluid. The activation or inhibition of integrin receptors by various agents may provide an excellent means of influencing wound healing. This process offers an earlier intervention into the wound healing cascade promoting intrinsic healing and elaboration of growth factors and ECM proteins, which may be more cost effective than the traditional attempts at extrinsic addition of these agents.     

Different wound healing properties of dermis,adipose, and gingiva mesenchymal stromal cells

Oral wounds heal faster and with better scar quality than skin wounds. Deep skin wounds where adipose tissue is exposed, have a greater risk of forming hypertrophic scars. Differences in wound healing and final scar quality might be related to differences in mesenchymal stromal cells (MSC) and their ability to respond to intrinsic (autocrine) and extrinsic signals, such as human salivary histatin, epidermal growth factor, and transforming growth factor beta1. Dermis‐, adipose‐, and gingiva‐derived MSC were compared for their regenerative potential with regards to proliferation, migration, and matrix contraction. Proliferation was assessed by cell counting and migration using a scratch wound assay. Matrix contraction and alpha smooth muscle actin was assessed in MSC populated collagen gels, and also in skin and gingival full thickness tissue engineered equivalents (reconstructed epithelium on MSC populated matrix). Compared to skin‐derived MSC, gingiva MSC showed greater proliferation and migration capacity, and less matrix contraction in full thickness tissue equivalents, which may partly explain the superior oral wound healing. Epidermal keratinocytes were required for enhanced adipose MSC matrix contraction and alpha smooth muscle actin expression, and may therefore contribute to adverse scarring in deep cutaneous wounds. Histatin enhanced migration without influencing proliferation or matrix contraction in all three MSC, indicating that salivary peptides may have a beneficial effect on wound closure in general. Transforming growth factor beta1 enhanced contraction and alpha smooth muscle actin expression in all three MSC types when incorporated into collagen gels. Understanding the mechanisms responsible for the superior oral wound healing will aid us to develop advanced strategies for optimal skin regeneration, wound healing and scar formation.     

Mesenchymal stem cell‐conditioned medium accelerates wound healing with fewer scars

Mesenchymal stem cells (MSCs) derived from umbilical cord s (UC‐MSCs) have been shown to enhance cutaneous wound healing by means of the paracrine activity. Fibroblasts are the primary cells involved in wound repair. The paracrine effects of UC‐MSCs on dermal fibroblasts have not been fully explored in vitro or in vivo. Dermal fibroblasts were treated with conditioned media from UC‐MSCs (UC‐MSC‐CM). In this model, UC‐MSC‐CM increased the proliferation and migration of dermal fibroblasts. Moreover, adult dermal fibroblasts transitioned into a phenotype with a low myofibroblast formation capacity, a decreased ratio of transforming growth factor‐β1,3 (TGF‐β1/3) and an increased ratio of matrix metalloproteinase/tissue inhibitor of metalloproteinases (MMP/TIMP). Additionally, UC‐MSC‐CM‐treated wounds showed accelerated healing with fewer scars compared with control groups. These observations suggest that UC‐MSC‐CM may be a feasible strategy to promote cutaneous repair and a potential means to realise scarless healing.     

Detrimental dermal wound healing: What can we learn from the oral mucosa?

Wounds in adults are frequently accompanied by scar formation. This scar can become fibrotic due to an imbalance between extracellular matrix (ECM) synthesis and ECM degradation. Oral mucosal wounds, however, heal in an accelerated fashion, displaying minimal scar formation. The exact mechanisms of scarless oral healing are yet to be revealed. This review highlights possible mechanisms involved in the difference between scar‐forming dermal vs. scarless oral mucosal wound healing. Differences were found in expression of ECM components, such as procollagen I and tenascin‐C. Oral wounds contained fewer immune mediators, blood vessels, and profibrotic mediators but had more bone marrow–derived cells, a higher reepithelialization rate, and faster proliferation of fibroblasts compared with dermal wounds. These results form a basis for further research that should be focused on the relations among ECM, immune cells, growth factors, and fibroblast phenotypes, as understanding scarless oral mucosal healing may ultimately lead to novel therapeutic strategies to prevent fibrotic scars.     

Mesenchymal stem cells' interaction with skin: Wound‐healing effect on fibroblast cells and skin tissue

Mesenchymal stem cells (MSCs) are multipotent progenitor cells with the ability to secrete growth factors. Because wound healing is associated with fibroblast cells and extracellular matrix (ECM) in the dermis and epidermis, we used fibroblast cells to resolve the question of whether or not MSCs regulate wound healing in vitro via a regenerative function. Using a cell proliferation assay, we demonstrated that conditioned media (CM) obtained from MSCs significantly enhanced the cell survival ability of fibroblast cells. Moreover, by measurement of mRNA and protein, we observed that CM also promoted the production or secretion of collagen, elastin, and fibronectin. To better understand the effects of ECM‐related wound healing, we measured the level of collagen‐degradative enzyme (matrix metalloprotease‐1), and observed that CM suppressed matrix metalloprotease‐1 expression. For the determination of oxidative stress, which has an influence on wound healing, we performed the superoxide dismutase and glutathione peroxidase assays; our results suggested that CM inhibited the oxidative stress of fibroblast cells. In order to widely investigate the wound‐healing effects of MSCs, we performed in vivo experiments, and observed that MSCs stimulated wound healing. In summary, the results of this study suggest that MSCs inhibit the loss of fibroblast cells and ECM, and accumulation of oxidative stress. We found that MSCs stimulate wound healing in vitro and in vivo, suggesting that MSCs have the potential to enhance wound healing.     

Altered ECM deposition by diabetic foot ulcer‐derived fibroblasts implicates fibronectin in chronic wound repair

Current chronic wound treatments often fail to promote healing of diabetic foot ulcers (DFU), leading to amputation and increased patient morbidity. A critical mediator of proper wound healing is the production, assembly, and remodeling of the extracellular matrix (ECM) by fibroblasts. However, little is known about how these processes are altered in fibroblasts within the DFU microenvironment. Thus, we investigated the capacity of multiple, primary DFU‐derived fibroblast strains to express, produce, and assemble ECM proteins compared to diabetic patient‐derived fibroblasts and healthy donor‐derived fibroblasts. Gene expression microarray analysis showed differential expression of ECM and ECM‐regulatory genes by DFU‐derived fibroblasts which translated to functional differences in a 3D in vitro ECM tissue model. DFU‐derived fibroblasts produced thin, fibronectin‐rich matrices, and responded abnormally when challenged with transforming growth factor‐beta, a key regulator of matrix production during healing. These results provide novel evidence that DFU‐derived fibroblasts contribute to the defective matrices of DFUs and chronic wound pathogenesis.     

Wound‐healing effect of adipose stem cell‐derived extracellular matrix sheet on full‐thickness skin defect rat model: Histological and immunohistochemical study

The potential use of extracellular matrix (ECM) as a source of wound dressing material has recently received much attention. The ECM is an intricate network of various combinations of elastin, collagens, laminin, fibronectin, and proteoglycans that play a key role in stimulating cell proliferation and differentiation. We evaluated the efficacy of an ECM sheet derived from human adipose tissue as a wound dressing material to enhance healing. We prepared a novel porous ECM sheet dressing scaffold from human adipose tissue. in vitro analysis of the ECM sheets showed efficient decellularisation; absence of immunostimulatory components; and the presence of a wide number of angiogenic and bioactive factors, including collagen, elastin, and proteoglycans. To evaluate in vivo efficacy, full‐thickness excisional wounds were created on the dorsal skin of a rat, and the ECM sheets; secondary healing foam wound dressing, Healoderm; or a conventional dressing were applied to each wound site. Photographs were taken every other day, and the degree of reepithelialisation of the wounds was determined. Application of an ECM sheet dressing enhanced the macroscopic wound‐healing rate on days 4, 7, and 10 compared with that in the control group. Microscopic analysis indicated that the reepithelialisation rate of the wound was higher in the ECM group compared with that in the control group; the reepithelialisation rate was better than that of the secondary healing foam wound dressing. Moreover, a denser and more organised granulation tissue was formed in the ECM sheet group compared with that in the secondary healing foam wound dressing and control groups. The ECM sheet also showed the highest microvessel density compared with the secondary healing foam wound dressing and control groups. Based on these data, we suggest that a bioactive ECM sheet dressing derived from human adipose can provide therapeutic proteins for wound healing.     

Adipose‐Derived Stromal Vascular Fraction and Cultured Stromal Cells as Trophic Mediators for Tendon Healing

Adipose‐derived stromal vascular fraction (SVF) is a heterogeneous population of cells that yields a homogeneous population of plastic‐adherent adipose tissue‐derived stromal cells (ASC) when culture‐expanded. SVF and ASC have been used clinically to improve tendon healing, yet their mechanism of action is not fully elucidated. The objective of this study was to investigate the potential for ASC to act as trophic mediators for tendon healing. Flexor digitorum superficialis tendons and adipose tissue were harvested from adult horses to obtain SVF, ASC, and tenocytes. Growth factor gene expression was quantified in SVF and ASC in serial passages and growth factors were quantified in ASC‐conditioned medium (CM). Microchemotaxis assays were performed using ASC‐CM. Tenocytes were grown in co‐culture with autologous ASC or allogeneic SVF. Gene expression for insulin‐like growth factor 1 (IGF‐1), stromal cell‐derived factor‐1α (SDF‐1α), transforming growth factor‐β1 (TGF‐β1) and TGF‐β3 was significantly higher in SVF compared to ASC. Concentrations were significantly increased in ASC‐CM compared to controls for IGF‐1 (4‐fold) and SDF‐1α (6‐fold). Medium conditioned by ASC induced significant cell migration in a dose‐dependent manner. Gene expression for collagen types I and III, decorin, and cartilage oligomeric matrix protein was modestly, but significantly increased following co‐culture of tenocytes with autologous ASC. Our findings support the ability of SVF and ASC to act as trophic mediators in tendon healing, particularly through chemotaxis, which stands to critically impact the intrinsic healing response. In vivo studies to further delineate the potential for SVF and/or ASC to improve tendon healing are warranted. © 2019 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res 37:1429–1439, 2019.     

Coacervate delivery of HB‐EGF accelerates healing of type 2 diabetic wounds

Chronic wounds such as diabetic ulcers pose a significant challenge as a number of underlying deficiencies prevent natural healing. In pursuit of a regenerative wound therapy, we developed a heparin‐based coacervate delivery system that provides controlled release of heparin‐binding epidermal growth factor (EGF)‐like growth factor (HB‐EGF) within the wound bed. In this study, we used a polygenic type 2 diabetic mouse model to evaluate the capacity of HB‐EGF coacervate to overcome the deficiencies of diabetic wound healing. In full‐thickness excisional wounds on NONcNZO10 diabetic mice, HB‐EGF coacervate enhanced the proliferation and migration of epidermal keratinocytes, leading to accelerated epithelialization. Furthermore, increased collagen deposition within the wound bed led to faster wound contraction and greater wound vascularization. Additionally, in vitro assays demonstrated that HB‐EGF released from the coacervate successfully increased migration of diabetic human keratinocytes. The multifunctional role of HB‐EGF in the healing process and its enhanced efficacy when delivered by the coacervate make it a promising therapy for diabetic wounds.     

Persistent Ischemia Impairs Myofibroblast Development in Wound Granulation Tissue a New Model of Delayed Wound Healing

Skin substitutes are slowly finding a position in the treatment of burns, scar reconstructions and chronic wounds. Some of the substitutes consist of extracellular matrix replacement material only, such as Integra and Alloderm; some include allogeneic cells (Dermagraft, Appligraf). The ideal skin substitute has not been developed yet, since none of the presently available products can ultimately prevent scar formation.
Study of the role of autologous fibroblasts in the healing process might give further insight into the scarring process and eventually lead to improved skin substitutes.
We compared wound reepithelialization of experimental wounds treated with proliferating keratinocytes and a dermal substitute with either dermal fibroblasts, adipose tissue derived fibroblasts or no fibroblasts. We also investigated the rate of keratinocyte migration of human skin equivalents cultured in vitro in the presence of dermal or adipose tissue derived fibroblasts.
We reached successful wound closure in 8 days with transfer of proliferating keratinocytes on a dermal substitute seeded with dermal fibroblasts. However, the wounds treated with substitutes which contained adipose tissue derived fibroblasts or no fibroblasts at all were not closed even after 21 days.
Keratinocytes seeded onto collagen lattices populated with either dermal or fat‐derived fibroblasts showed similar findings: a retarded migration and/or proliferation of keratinocytes on the collagen lattices with fat‐derived fibroblasts. The collagen lattices populated with fat‐derived fibroblasts also showed a marked contraction, up till 50% of the original area.
In both models, more alpha‐smooth muscle actin positive cells were found in the fibroblast population from adipose origin.
We conclude that epidermal regeneration is negatively influenced by the presence of fat‐derived fibroblasts in a dermal matrix; possibly, myofibroblasts play a role in this.     

Cellular events and biomarkers of wound healing

Researchers have identified several of the cellular events associated with wound healing. Platelets, neutrophils, macrophages, and fibroblasts primarily contribute to the process. They release cytokines including interleukins (ILs) and TNF-α, and growth factors, of which platelet-derived growth factor (PDGF) is perhaps the most important. The cytokines and growth factors manipulate the inflammatory phase of healing. Cytokines are chemotactic for white cells and fibroblasts, while the growth factors initiate fibroblast and keratinocyte proliferation. Inflammation is followed by the proliferation of fibroblasts, which lay down the extracellular matrix. Simultaneously, various white cells and other connective tissue cells release both the matrix metalloproteinases (MMPs) and the tissue inhibitors of these metalloproteinases (TIMPs). MMPs remove damaged structural proteins such as collagen, while the fibroblasts lay down fresh extracellular matrix proteins. Fluid collected from acute, healing wounds contains growth factors, and stimulates fibroblast proliferation, but fluid collected from chronic, nonhealing wounds does not. Fibroblasts from chronic wounds do not respond to chronic wound fluid, probably because the fibroblasts of these wounds have lost the receptors that respond to cytokines and growth factors. Nonhealing wounds contain high levels of IL1, IL6, and MMPs, and an abnormally high MMP/TIMP ratio. Clinical examination of wounds inconsistently predicts which wounds will heal when procedures like secondary closure are planned. Surgeons therefore hope that these chemicals can be used as biomarkers of wounds which have impaired ability to heal. There is also evidence that the application of growth factors like PDGF will help the healing of chronic, nonhealing wounds.KEY WORDS: Cytokines, growth factors, matrix metalloproteinases, platelet-derived growth factor, wound healingIn the last 30 or so years, researchers have identified several of the cellular and biochemical events associated with wound healing. The process is becoming clearer, with the understanding of the cells and chemicals that help wounds to heal, and of those that inhibit healing. Investigators are trying to analyze the chemicals in chronic wounds in order to determine their condition and fitness for closure. A major advance is the clinical application of some of these chemicals to improve outcomes in wound healing.In this paper we look at the biology of normal and abnormal healing, see if wounds analysis can predict poor healing, and review some literature on the clinical applications of this knowledge.     

Chemokines and diabetic wound healing

Chemokines are critical for white blood cell recruitment to injured tissues and play an important role in normal wound healing processes. In contrast, impaired wound healing in diabetic patients is accompanied by decreased early inflammatory cell infiltration but persistence of neutrophils and macrophages in the chronic, nonhealing wounds. These changes in inflammatory cell recruitment occur in conjunction with alterations in chemokine and growth factor expression. In addition to leukocyte trafficking, many different cell types, including endothelial cells, fibroblasts, and keratinocytes, produce and respond to chemokines, and these interactions are altered in diabetic wounds. Thus, the chemokine system may have both direct and inflammatory-mediated effects on many different aspects of diabetic wound healing. The potential roles of chemokines and inflammatory or immune cells in nonhealing diabetic wounds, including impairments in growth factor expression, angiogenesis, extracellular matrix formation, and reepithelialization, are examined.     

Diabetes impairs adipose tissue–derived stem cell function and efficiency in promoting wound healing

Adipose tissue–derived stem cells (ASCs) are gaining increasing consideration in tissue repair therapeutic application. Recent evidence indicates that ASCs enhance skin repair in animal models of impaired wound healing. To assess the therapeutic activity of autologous vs. allogeneic ASCs in the treatment of diabetic ulcers, we functionally characterized diabetic ASCs and investigated their potential to promote wound healing with respect to nondiabetic ones. Adipose tissue–derived cells from streptozotocin‐induced type 1 diabetic mice were analyzed either freshly isolated as stromal vascular fraction (SVF), or following a single passage of culture (ASCs). Diabetic ASCs showed decreased proliferative potential and migration. Expression of surface markers was altered in diabetic SVF and cultured ASCs, with a reduction in stem cell marker‐positive cells. ASCs from diabetic mice released lower amounts of hepatocyte growth factor, vascular endothelial growth factor (VEGF)‐A, and insulin‐like growth factor‐1, growth factors playing important roles in skin repair. Accordingly, the supernatant of diabetic ASCs manifested reduced capability to promote keratinocyte and fibroblast proliferation and migration. Therapeutic potential of diabetic SVF administered to wounds of diabetic mice was blunted as compared with cells isolated from nondiabetic mice. Our data indicate that diabetes alters ASC intrinsic properties and impairs their function, thus affecting therapeutic potential in the autologous treatment for diabetic ulcers.     

Use of a cell-based interactive wound dressing to enhance healing of excisional wounds in nude mice

The need to have viable, metabolically active cells to heal wounds is well recognized, because there is clear evidence that cellular dysfunction delays healing. This suggests that addition of metabolically active cells to a delayed healing tissue could enhance the healing of the tissue. Therefore, we examined the ability of an interactive wound dressing composed of human keratinocytes or fibroblasts grown on microporous bio-reactor beads and placed into a polyethylene bag to facilitate the delayed healing of wounds in nude mice. A 1 x 1 cm wound was made on the backs of nude mice, and the dressing with or without viable cells was placed on the wound for 8 to 24 days, with dressing changes every other day. Wound area and time to heal measurements were compared after various interventions including freeze-thawing. The data shows that the interactive wound dressing was more effective than the control dressings (p<0.05) and that keratinocytes were more effective than fibroblasts in wound healing (p<0.05). Freezing-thawing of the interactive wound dressings destroyed the activity of the dressing. Studies examining cells using a live/dead viability assay showed that both keratinocytes and fibroblasts were alive after 2 days on the mice. Surprisingly, human fibroblasts appeared to exhibit bridging behavior that is indicative of fibroblast proliferation. We conclude that a simple interactive wound dressing using either keratinocytes or fibroblasts can enhance the healing of wounds in nude mice.     

The altered mechanical phenotype of fetal fibroblasts hinders myofibroblast differentiation

During the dermal wound healing process, the mechanical rigidity of the newly deposited extracellular matrix and transforming growth factor‐β1 promote the transition of fibroblasts into myofibroblasts. Myofibroblasts generate large cellular forces that contract and remodel the extracellular matrix leading to scar formation. In contrast, myofibroblasts are not detected in fetal dermal wounds which are more compliant and contain less transforming growth factor‐β1 than adult wounds. Instead, fetal fibroblasts orchestrate scarless healing of dermal wounds resulting in healed tissues that resemble uninjured dermis. While these biomechanical differences suggest that the fetal wound environment promotes smaller cellular forces which enable regeneration, previous studies indicate that fetal fibroblasts have unique contractile properties that may facilitate scarless dermal repair. Therefore, we tested whether physiologic wound rigidities and transforming growth factor‐β1 induce contractile forces and myofibroblast differentiation of fetal dermal fibroblasts. In comparison to their adult dermal counterparts, we found that fetal fibroblasts exhibit a deficient contractile response to rigid extracellular matrix and transforming growth factor‐β1. Our data suggest that the contractile phenotype of fetal dermal fibroblasts limits their cellular force production and prevents their ability to differentiate into myofibroblasts.     

071TGF‐ß‐Mediated Paracrine Regulation of Keratinocyte Wound Closure

The importance of stromal‐epithelial interactions in wound healing is well established. These interactions likely involve autocrine and paracrine action of multiple growth factors, including members of the TGF‐ß family. TGF‐ß1, ß2 and ß3 isoforms signal by sequentially binding to the TGF‐ß type II and type I receptors, respectively. We address the role of TGF‐ß signaling in dermal fibroblasts using a conditional fibroblastic TGF‐ß type II receptor knockout mouse model (termed FßKO). We found that the loss of TGF‐ß signaling in the dermal fibroblasts results in accelerated excision‐wound closure compared with similar wounds in wild type mice. The mechanism of the altered rate of re‐epitheliaization in the FßKO mice was examined with regard to keratiocyte motility and proliferation. The migration of keratinocytes through collagen I coated 8 μm pore filters in the presence or absence of fibroblast‐conditioned media was tested. These experiments showed increased keratinocyte migration when incubated with FßKO dermal fibroblast conditioned media compared to media conditioned in wild type fibroblasts. Immuno‐histochemical staining of paraffin embedded intact skin indicated both wild type and FßKO mice had similar low levels of keratinocyte proliferation, based on Ki67 staining. In healing wounds, only the distal wound edges of wild type mice were proliferative. In contrast, the FßKO mice exhibited elevated proliferation across the length of the wound, including the leading edge of epithelial closure. Together our results suggest TGF‐ß signaling by the dermal fibroblasts suppresses re‐epithelialization of excision wounds by regulating keratinocyte motility and proliferation through paracrine mechanisms.
Funding: DOD BC99184 and NIH CA85492.     

The importance of both fibroblasts and keratinocytes in a bilayered living cellular construct used in wound healing

Cross talk between fibroblasts and keratinocytes, which maintains skin homeostasis, is disrupted in chronic wounds. For venous leg ulcers and diabetic foot ulcers, a bilayered living cellular construct (BLCC), containing both fibroblasts and keratinocytes that participate in cross talk, is a safe and effective product in healing chronic wounds. To show the importance of both cell types in BLCC, constructs were generated containing only fibroblasts or only keratinocytes and compared directly to BLCC via histology, mechanical testing, gene/protein analysis, and angiogenesis assays. BLCC contained a fully differentiated epithelium and showed greater tensile strength compared with one‐cell‐type constructs, most likely due to formation of intact basement membrane and well‐established stratum corneum in BLCC. Furthermore, expression of important wound healing genes, cytokines, and growth factors was modulated by the cells in BLCC compared with constructs containing only one cell type. Finally, conditioned medium from BLCC promoted greater endothelial network formation compared with media from one‐cell‐type constructs. Overall, this study characterized a commercially available wound healing product and showed that the presence of both fibroblasts and keratinocytes in BLCC contributed to epithelial stratification, greater tensile strength, modulation of cytokine and growth factor expression, and increased angiogenic properties compared with constructs containing fibroblasts or keratinocytes alone.     

Transplanted fibroblasts prevents dysfunctional repair in a murine CXCR3-deficient scarring model

In skin, the regeneration of the ontogenically distinct mesenchymal and epithelial compartments must proceed in a coordinated manner orchestrated by extracellular signaling networks. We have recently found that the switch from regeneration to remodeling during repair is modulated by chemokines that bind CXCR3 receptor. If this signaling is disrupted wounds continue to be active, resulting in a chronic hypercellular and hypertrophic state characterized by an immature matrix composition. As healing is masterminded in large part by fibroblasts and their synthesis of the extracellular matrix, the question arose as to whether this ongoing scarring can be modulated by transplanted fibroblasts. We examined wounds in the CXCR3-/- mouse scarring model. These wounds exhibited a significant delay in healing in all areas compared to young and aged wild-type mice. Full-thickness wounds were transplanted with fibroblasts derived from newborn CXCR3-/- or wild-type mice. The transplanted fibroblasts were labeled with fluorescent dye (CM-DiI) and suspended in hyaluronic acid gel; by 30 days, these transplanted cells comprised some 30% of the dermal stromal cells regardless of the host or source of transplanted cells. Wild-type fibroblasts transplanted into CXCR3-/- mice wounds reversed the delay and dysfunction previously seen in CXCR3-/- wounds; this correction was not noted with transplanted CXCR3-/- fibroblasts. Additionally, transplant of CXCR3-/- cells into wounds in wild-type animals did not adversely affect those wounds. The transplanted fibroblasts exhibited strong survival and migration patterns and led to an increase in tensile strength. Expression of matrix proteins and collagen in CXCR3-/- wounds transplanted with wild-type fibroblasts resembled normal wild-type healing, and the wound matrix in wild-type mice transplanted with CXCR3-/- cells also presented a mature matrix. These suggest that the major determinant of healing versus scarring lies with the nature of the matrix. These findings have intriguing implications for rational cellular interventions aimed at promoting wound healing via cell therapy.