Changes in cellular motility and cytoskeletal actin in fibroblasts from patients with chronic venous insufficiency and in neonatal fibroblasts in the presence of chronic wound fluid

Development of a Cellular Assay as a Personalized Model for Testing Chronic Wound Therapeutics

Exudates of nonhealing wounds contain drivers of pathogenicity. We utilized >800 exudates from nonhealing and healing wounds of diverse etiologies, collected by 3 different methods, to develop a wound-specific, cell-based functional biomarker assay. Human dermal fibroblast proliferation served as readout to (i) differentiate between healing and nonhealing wounds, (ii) follow the healing process of individual patients, and (iii) assess the effects of therapeutics for chronic wounds ex vivo. We observed a strong correlation between wound chronicity and inhibitory effects of individual exudates on fibroblast proliferation, with good diagnostic sensitivity (76-90%, depending on the sample collection method). Transition of a clinically nonhealing to a healing phenotype restored fibroblast proliferation and extracellular matrix formation while reducing inflammatory cytokine production. Transcriptional analysis of fibroblasts exposed to ex vivo nonhealing wound exudates revealed an induction of inflammatory cytokine and chemokine pathways and the unfolded protein response, indicating that these changes may contribute to the pathology of nonhealing wounds. Testing the wound therapeutics, PDGF and silver sulfadiazine, yielded responses in line with clinical experience and indicates the usefulness of the assay to search for and profile new therapeutics.

Review of optical methods for noninvasive imaging of skin fibroblasts-From in vitro to ex vivo and in vivo visualization

Fibroblasts are among the most common cell types in the stroma responsible for creating and maintaining the structural organization of the extracellular matrix in the dermis, skin regeneration, and a range of immune responses. Until now, the processes of fibroblast adaptation and functioning in a varying environment have not been fully understood. Modern laser microscopes are capable of studying fibroblasts in vitro and ex vivo. One-photon- and two-photon-excited fluorescence microscopy, Raman spectroscopy/microspectroscopy are well-suited noninvasive optical methods for fibroblast imaging in vitro and ex vivo. In vivo staining-free fibroblast imaging is not still implemented. The exception is fibroblast imaging in tattooed skin. Although in vivo noninvasive staining-free imaging of fibroblasts in the skin has not yet been implemented, it is expected in the future. This review summarizes the state-of-the-art in fibroblast visualization using optical methods and discusses the advantages, limitations, and prospects for future noninvasive imaging.

Changing the Wound: Covalent Immobilization of the Epidermal Growth Factor

Re-epithelialization of wounds is a critical element of wound closure. Growth factors have been used in combination with conventional wound management to promote closure, but the method of delivery has been limited to the topical application of ointment formulations. Cytoactive factors delivered in this way have short resident times in wounds and have met with limited success. Here, we demonstrate that methods used to covalently immobilize proteins on synthetic materials can be extended to immobilize cytoactive factors such as the epidermal growth factor (EGF) onto the wound beds of genetically diabetic mice that exhibit impaired healing. Full-thickness splinted excisional wounds were created in diabetic (db/db) mice with a well-defined silicone splint to limit wound contracture. Wound surfaces were treated with a reducing agent to expose sulfhydryl groups and subsequently treated with EGF modified with a heterobifunctional crosslinker. This allowed for the covalent immobilization of the EGF to the wound surface. The conjugation chemistry was validated in vitro and in vivo. In a separate group of mice, wounds were topically treated twice daily with soluble EGF. The mice were evaluated over 11 days for wound closure. This covalent immobilization strategy resulted in EGF being retained on the wound surface for 2 days and significantly increased epithelial wound closure by 20% compared to wounds treated with topical EGF or topical vehicle. Covalent immobilization was not only therapeutically effective but also delivered a markedly reduced load of growth factor to the wound surface compared to topical application (when only 180 ng of EGF was immobilized onto the wound surface in comparison with 7200 ng of topically applied EGF over a period of 11 days). No adverse effects were observed in treated wounds. Results obtained provide proof of concept for the effectiveness of covalent immobilization in the treatment of dysregulated wounds. The covalent immobilization of cytoactive factors represents a potentially transformative approach to the management of difficult chronic wounds.

Novel leukocyte-depleted platelet-rich plasma-based skin equivalent as an in vitro model of chronic wounds: a preliminary study

BACKGROUND

Chronic leg ulcerations are associated with Haemoglobin disorders, Type2 Diabetes Mellitus, and long-term venous insufficiency, where poor perfusion and altered metabolism develop into a chronic inflammation that impairs wound closure. Skin equivalent organotypic cultures can be engineered in vitro to study skin biology and wound closure by modelling the specific cellular components of the skin. This study aimed to develop a novel bioactive platelet-rich plasma (PRP) leukocyte depleted scaffold to facilitate the study of common clinical skin wounds in patients with poor chronic skin perfusion and low leukocyte infiltration. A scratch assay was performed on the skin model to mimic two skin wound conditions, an untreated condition and a condition treated with recombinant tumour necrotic factor (rTNF) to imitate the stimulation of an inflammatory state. Gene expression of IL8 and TGFA was analysed in both conditions. Statistical analysis was done through ANOVA and paired student t-test. P < 0.05 was considered significant.

RESULTS

A skin model that consisted of a leukocyte-depleted, platelet-rich plasma scaffold was setup with embedded fibroblasts as dermal equivalents and seeded keratinocytes as multi-layered epidermis. Gene expression levels of IL8 and TGFA were significantly different between the control and scratched conditions (p < 0.001 and p < 0.01 respectively), as well as between the control and treated conditions (p < 0.01 and p < 0.001 respectively). The scratch assay induced IL8 upregulation after 3 h (p < 0.05) which continued to increase up to day 1 (p < 0.05). On the other hand, the administration of TNF led to the downregulation of IL8 (p < 0.01), followed by an upregulation on day 2. IL8 gene expression decreased in the scratched condition after day 1 as the natural healing process took place and was lower than in the treated condition on day 8 (p < 0.05). Both untreated and treated conditions showed a downregulation of TGFA 3 h after scratch when compared with the control condition (p < 0.01). Administration of rTNF showed significant downregulation of TGFA after 24 h when compared with the control (p < 0.01) and treated conditions (p < 0.05).

CONCLUSION

This study suggests that a leukocyte-depleted PRP-based skin equivalent can be a useful model for the in vitro study of chronic skin wounds related to poor skin perfusion.

Evaluation of the Effect of Plasma from Patients with Trophic Ulcers on the Function of Dermal Fibroblasts, Mesenchymal Stem Cells, and Endothelial Cells

We studied the effect of platelet lysate and platelet-poor plasma from patients with trophic ulcers with and without type 2 diabetes mellitus on proliferation, migration, and apoptosis of human dermal fibroblast, mesenchymal stem cells, and endothelial cells. It is shown that plasma obtained from patients with type 2 diabetes mellitus produced inhibitory effects.

[Granulocytes function in patients with chronic venous insufficiency followed by chronic wounds]

AIM

To analyze efficiency of ozone therapy, ultrasound and cryotherapy for infected and purulent wounds due to chronic venous insufficiency.

MATERIAL AND METHODS

There were 127 patients with chronic venous insufficiency followed by chronic wounds. Efficacy of systemic and local ozone therapy was assessed. De Sole method was used to analyze chemiluminescent and spontaneous activity of neutrophils of peripheral blood.

RESULTS

Advanced generation of active forms of oxygen was revealed in patients with chronic wounds and chronic venous insufficiency. Complex ozone therapy including intravenous administration of ozonized autologous blood, oxygen-ozone and ultrasonic exposure of the wound and cryogenic stimulation reduce painful period up to 3.1±0.6 days, accelerate epithelialization of the wound and normalize release of active forms of oxygen.

MicroRNA as Therapeutic Targets for Chronic Wound Healing

Wound healing is a highly complex biological process composed of three overlapping phases: inflammation, proliferation, and remodeling. Impairments at any one or more of these stages can lead to compromised healing. MicroRNAs (miRs) are non-coding RNAs that act as post-transcriptional regulators of multiple proteins and associated pathways. Thus, identification of the appropriate miR involved in the different phases of wound healing could reveal an effective third-generation genetic therapy in chronic wound care. Several miRs have been shown to be upregulated or downregulated during the wound healing process. This article examines the biological processes involved in wound healing, the miR involved at each stage, and how expression levels are modulated in the chronic wound environment. Key miRs are highlighted as possible therapeutic targets, either through underexpression or overexpression, and the healing benefits are interrogated. These are prime miR candidates that could be considered as a gene therapy option for patients suffering from chronic wounds. The success of miR as a gene therapy, however, is reliant on the development of an appropriate delivery system that must be designed to overcome both extracellular and intracellular barriers.

Factor XIII Contrasts the Effects of Metalloproteinases in Human Dermal Fibroblast Cultured Cells

Matrix metalloproteinases (MMPs) are overexpressed in venous leg ulcers, determining a breakdown of the main extracellular matrix (ECM) components owing mainly to collagenase activities, and so playing a crucial role in ulcer pathogenesis. The authors studied the effects of coagulation factor XIII (FXIII), which cross-links collagen and other ECM components, in human fibroblast cultured cells in the presence and in the absence of matrix metalloproteinases from Clostridium histolyticum collagenase. Clostridium collagenase at concentrations of 2.0, 1.0, and 0.5 mg/mL was added to normal human dermal fibroblasts cultured in the presence of 0.0, 1.0, and 5.0 U/mL of FXIII concentrate (Fibrogammin P, Aventis Behring). Cell counting and metabolically active fibroblast evaluation in the cultures were monitored for 72 hours, by means of trypan-blue dye and MTT test, respectively. The MTT test showed that at the highest collagenase concentration (2.0 mg/mL), the cell number decreased more than 95% in 72 hours of treatment and no significant differences were observed regardless of the FXIII concentrations utilized. At lower collagenase concentration (1.0 mg/mL), in absence or in presence of FXIII (1.0 U/mL), the cell number decreased by about 80% in 72 hours. In contrast, in the presence of higher FXIII levels (5.0 U/mL), cells suffered globally significantly less collagenase effects (p=0.011) and the gain was appreciable at each time tested. Finally, at 0.5 mg/mL of collagenase concentration, in the absence of FXIII, the cell number decreased by about 60% in 72 hours, whereas in presence of FXIII 1.0 U/mL and 5.0 U/mL, cells decreased significantly less, by about 35% and 20%, respectively (p<0.025 and p<0.01, respectively). These data were also confirmed by direct cell counting utilizing the trypan-blue test. Factor XIII contrasts effectively the detrimental action of Clostridium collagenases in human fibroblast cultured cells. These results support several in vivo reports about the effectiveness of its topical application in order to enhance the venous ulcer healing processes.

Mitogen-Activated Protein Kinase Pathway Regulates Cell Proliferation in Venous Ulcer Fibroblasts

Venous ulcer fibroblasts have been demonstrated to have low growth rates in response to platelet-derived growth factor (PDGF). Mitogen-activated protein kinase (MAPK) is an important signal transduction mechanism that regulates growth, differentiation, and apoptosis in eukaryotic cells. PDGF binds PDGF receptors that activate a multitiered signaling cascade involving MAPK. We hypothesize that the growth regulation in venous ulcer fibroblasts is dependent on the MAPK extracellular signal-regulated kinase (ERK) pathway in the presence of PDGF. Fibroblasts (fb) were isolated from 8 patients with venous ulcers (w-fb) and the normal skin (n-fb) of the ipsilateral thigh via punch biopsies. Fb were plated at 1,500 cells/dish and treated with PDGF-AB (10 ng/mL) for 15 days. Growth rates were determined. Immunoblot analysis of MAPK ERK for n-fb and w-fb were analyzed. To determine if PDGF-stimulated w-fb and n-fb utilized the MAPK ERK pathway in a dependent manner, the upstream kinase MAPK kinase 1 (MEK 1) was inhibited by PD 98059. In addition, fb were treated with chronic venous ulcer wound fluid (WF) to study its effect on MAPK ERK. In the presence of PDGF, growth rates were substantially lower in w-fb than in n-fb, and MAPK was activated in 6/8 w-fb and in only 2/8 n-fb. Fibroblasts expressing MAPK had significantly reduced cell proliferation compared to fibroblasts not expressing MAPK (p = 0.023). PD 98059 significantly inhibited wfb and n-fb cell proliferation from basal level, which was reversible with addition of PDGF. In neonatal fibroblasts WF demonstrated inhibition of MAPK ERK over time and addition of PD98059 was not additive. This study suggests that the MAPK ERK pathway is important for cell proliferation in venous ulcer fibroblasts. In the presence of PDGF, fibroblasts with decreased growth rate express MAPK, and proliferation is further abrogated with addition of MEK 1 inhibitor, suggesting the importance of the MAPK ERK pathway regulating w-fb and nfb proliferation. Although the majority of w-fb activated the MAPK ERK pathway in the presence of PDGF, proliferation was significantly attenuated, indicating that other MAPK inhibitory pathways are competing. Venous ulcer wound fluid directly inhibits the MAPK ERK pathway, suggesting that the venous ulcer wound environment has negative trophic factors that effect fibroblasts proliferation and ulcer healing.

Autologous adipose-derived stem cells: Basic science, technique, and rationale for application in ulcer and wound healing

Objectives The present review represents a translational boundary between basic research and surgery, particularly focusing on the promising application of adipose-derived stem cells harvested intra-operatively during debridement of venous leg ulcers. Methods We reviewed 830 out of 5578 articles on MEDLINE starting from 1997 and sorted by the relevance option. Results The technique currently used for adipose-derived stem cells intra-operative harvesting is presented, including a safety evaluation on a cohort of 5089 revised patients who underwent plastic surgery and maxillo-facial surgical procedures. Complications were reported in 169 cases (3.3%). One hundred and forty-one (2.77%) patients were classified as having minor complications, specifically: nodularity/induration 93 (1.83%), dysesthesia 14 (0.26%), hematoma 12 (0.23%), superficial infection 11 (0.21%), pain 7 (0.13%), poor cosmesis 3 (0.06%), and abnormal breast secretion 1 (0.02%), while 28 patients (0.55%) were classified as having major complications, specifically: deep infection 22 (0.43%), sepsis 3 (0.06%), abdominal hematoma 2 (0.04%), and pneumothorax 1 (0.02%). Application of cell therapy in venous leg ulcer is currently used only for patients not responding to the standard treatment. The review shows the lack of randomized clinical trials for application of adipose-derived stem cells among treatments for venous leg ulcer. Finally, adipose-derived stem cells implantation at the wound site promotes a new tissue formation rich in vascular structures and remodeling collagen. Conclusion Adipose-derived stem cells strategy represents a great opportunity for the treatment of chronic wounds, due to the simplicity of the technique and the application of cell treatment in the operating room immediately following debridement. However, clinical studies and data from randomized trials are currently lacking.

Master regulators in primary skin fibroblast fate reprogramming in a human ex vivo model of chronic wounds

Fibroblasts are important players in regulating tissue homeostasis. In the dermis, they are involved in wound healing where they differentiate into contractile myofibroblasts leading to wound closure. In nonhealing chronic wounds, fibroblasts fail to undertake differentiation. We established and used a human ex vivo model of chronic wounds where fibroblasts can undergo normal myofibroblast differentiation, or take on a nondifferentiable pathological state. At the whole genome scale, we identified the genes that are differentially regulated in these two cell fates. By coupling the search of evolutionary conserved regulatory elements with global gene network expression changes, we identified transcription factors (TF) potentially involved in myofibroblast differentiation, and constructed a network of relationship between these key factors. Among these, we found that TCF4, SOX9, EGR2, and FOXS1 are major regulators of fibroblast to myofibroblast differentiation. Conversely, down-regulation of MEOX2, SIX2, and MAF causes reprogramming of fibroblasts to myofibroblasts even in absence of TGF-β, the natural inducer of myofibroblast differentiation. These results provide insight into the fibroblast differentiation program and reveal a TF network essential for cellular reprogramming. They could lead to the development of new therapeutics to treat fibroblast-related human pathologies.

Chemokines as Therapeutic Targets to Improve Healing Efficiency of Chronic Wounds

Significance: Impaired wound healing leading to chronic wounds is an important clinical problem that needs immediate attention to develop new effective therapies. Members of the chemokine family seem to be attractive and amenable to stimulate the healing process in chronic wounds. Targeting specific chemokines and/or their receptors has the potential to modify chronic inflammation to acute inflammation, which will hasten the healing process. Recent Advances: Over the years, expression levels of various chemokines and their receptors have been identified as key players in the inflammatory phase of wound healing. In addition, they contribute to regulating other phases of wound healing making them key targets for novel therapies. Understanding the signaling pathways of these chemokines will provide valuable clues for modulating their function to enhance the wound healing process. Critical Issues: Inflammation, an important first-stage process in wound healing, is dysregulated in chronic wounds; emerging studies show that chemokines play a crucial role in regulating inflammation. The knowledge gained so far is still limited in understanding the enormous complexity of the chemokine network during inflammation not just in chronic wounds but also in acute (normal) wounds. A much better understanding of the individual chemokines will pave the way for better targets and therapies to improve the healing efficiency of chronic wounds. Future Directions: Effective understanding of the interaction of chemokines and their receptors during chronic wound healing would facilitate the design of novel therapeutic drugs. Development of chemokine-based drugs targeting specific inflammatory cells will be invaluable in the treatment of chronic wounds, in which inflammation plays a major role.

The role of adult tissue-derived stem cells in chronic leg ulcers: a systematic review focused on tissue regeneration medicine

Wound healing is an articulated process that can be impaired in different steps in chronic wounds. Chronic leg ulcers are a special type of non-healing wounds that represent an important cause of morbidity and public cost in western countries. Because of their common recurrence after conventional managements and increasing prevalence due to an ageing population, newer approaches are needed. Over the last decade, the research has been focused on innovative treatment strategies, including stem-cell-based therapies. After the initial interest in embryonic pluripotent cells, several different types of adult stem cells have been studied because of ethical issues. Specific types of adult stem cells have shown a high potentiality in tissue healing, in both in vitro and in vivo studies. Aim of this review is to clearly report the newest insights on tissue regeneration medicine, with particular regard for chronic leg ulcers.

The efficacy of negative pressure wound therapy on chemotherapeutic extravasation ulcers: An experimental study

Context:

The extravasation of the chemotherapeutic agents is not an unusual phenomenon. Necrosis of the skin and underlying structures has been reported, depending on the cytotoxicity of the extravasating drug. Despite the presence of some antidotes, such wounds tend to enlarge with time and are likely to resist the treatment.

Aims:

The objective of this study was to investigate the efficacy of negative pressure wound therapy (NPWT) on extravasation ulcers.

Settings and Design:

Animals were separated into two groups; conventional dressing group and NPWT group.

Materials and Methods:

Extravasation necrosis was established by intradermal doxorubicin injection. Following the debridement of the necrotic areas, one group of animals was treated with the conventional dressing while NPWT was applied to the other group. The wound areas were measured, and then biopsies were taken on the 3^rd, 7^th and 14^th days after the debridement.

Statistical Analysis Used:

SPSS 11.5 for Windows was used. Two-way ANOVA test was used to compare wound areas between groups. Willcoxon sign test with Bonferroni correction was used to compare histological scores between groups. Chi-square test with Bonferroni correction was used to compare histological scores within the group between the days.

Results:

There is no significant difference in terms of inflammatory cell count, neovascularisation, granulation tissue formation between the groups. Contrary to these results wound areas at the end of the treatment were smaller in the NPWT group compared with the dressing group.

Conclusion:

There is the superiority of NPWT over conventional dressing in chemotherapeutic extravasation wounds as well as the wound area is concerned, but it is not proven histologically.

In vitro study of the impact of mechanical tension on the dermal fibroblast phenotype in the context of skin wound healing

Skin wound healing is finely regulated by both matrix synthesis and degradation which are governed by dermal fibroblast activity. Actually, fibroblasts synthesize numerous extracellular matrix proteins (i.e., collagens), remodeling enzymes and their inhibitors. Moreover, they differentiate into myofibroblasts and are able to develop endogenous forces at the wound site. Such forces are crucial during skin wound healing and have been widely investigated. However, few studies have focused on the effect of exogenous mechanical tension on the dermal fibroblast phenotype, which is the objective of the present paper. To this end, an exogenous, defined, cyclic and uniaxial mechanical strain was applied to fibroblasts cultured as scratch-wounded monolayers. Results showed that fibroblasts' response was characterized by both an increase in procollagen type-I and TIMP-1 synthesis, and a decrease in MMP-1 synthesis. The monitoring of scratch-wounded monolayers did not show any decrease in kinetics of the filling up when mechanical tension was applied. Additional results obtained with proliferating fibroblasts and confluent monolayer indicated that mechanical tension-induced response of fibroblasts depends on their culture conditions. In conclusion, mechanical tension leads to the differentiation of dermal fibroblasts and may increase their wound-healing capacities. So, the exogenous uniaxial and cyclic mechanical tension reported in the present study may be considered in order to improve skin wound healing.

Diabetic foot wounds: the value of negative pressure wound therapy with instillation

Chronic wounds such as diabetic foot wounds are a tremendous burden to the health care system and often require a multidisciplinary approach to prevent amputations. Advanced technologies such as negative pressure wound therapy (NPWT) and bioengineered tissues have been successfully used in the treatment of these types of complex wounds. However, the introduction of NPWT with instillation (NPWTi) has provided an alternative treatment for treating complex and difficult-to-heal wounds. This article provides an overview of NPWT and the new NPWTi system and describes preliminary experience using NPWTi on patients with complicated infected diabetic foot wounds after surgical debridement and in a multidisciplinary setting.

Acute and impaired wound healing: pathophysiology and current methods for drug delivery, part 1: normal and chronic wounds: biology, causes, and approaches to care

This is the first installment of 2 articles that discuss the biology and pathophysiology of wound healing, review the role that growth factors play in this process, and describe current ways of growth factor delivery into the wound bed. Part 1 discusses the latest advances in clinicians' understanding of the control points that regulate wound healing. Importantly, biological similarities and differences between acute and chronic wounds are considered, including the signaling pathways that initiate cellular and tissue responses after injury, which may be impeded during chronic wound healing.

Matrix metalloproteinase inhibitors as investigative tools in the pathogenesis and management of vascular disease

Matrix metalloproteinases (MMPs) are proteolytic enzymes that degrade various components of the extracellular matrix (ECM). MMPs could also regulate the activity of several non-ECM bioactive substrates and consequently affect different cellular functions. Members of the MMPs family include collagenases, gelatinases, stromelysins, matrilysins, membrane-type MMPs, and others. Pro-MMPs are cleaved into active MMPs, which in turn act on various substrates in the ECM and on the cell surface. MMPs play an important role in the regulation of numerous physiological processes including vascular remodeling and angiogenesis. MMPs may also be involved in vascular diseases such as hypertension, atherosclerosis, aortic aneurysm, and varicose veins. MMPs also play a role in the hemodynamic and vascular changes associated with pregnancy and preeclampsia. The role of MMPs is commonly assessed by measuring their gene expression, protein amount, and proteolytic activity using gel zymography. Because there are no specific activators of MMPs, MMP inhibitors are often used to investigate the role of MMPs in different physiologic processes and in the pathogenesis of specific diseases. MMP inhibitors include endogenous tissue inhibitors (TIMPs) and pharmacological inhibitors such as zinc chelators, doxycycline, and marimastat. MMP inhibitors have been evaluated as diagnostic and therapeutic tools in cancer, autoimmune disease, and cardiovascular disease. Although several MMP inhibitors have been synthesized and tested both experimentally and clinically, only one MMP inhibitor, i.e., doxycycline, is currently approved by the Food and Drug Administration. This is mainly due to the undesirable side effects of MMP inhibitors especially on the musculoskeletal system. While most experimental and clinical trials of MMP inhibitors have not demonstrated significant benefits, some trials still showed promising results. With the advent of new genetic and pharmacological tools, disease-specific MMP inhibitors with fewer undesirable effects are being developed and could be useful in the management of vascular disease.

Evaluation of a near-senescent human dermal fibroblast cell line and effect of amelogenin

BACKGROUND

Fibroblast senescence may delay healing of chronic wounds.

OBJECTIVES

To characterize a chronic human dermal fibroblast cell line (CRL-7815) with near-senescent properties, cell proliferation and production of wound-healing modulating cytokines, and biosynthesis and remodelling of collagen were compared with normal human dermal fibroblasts. Also, the response of CRL-7815 fibroblasts to the extracellular matrix protein amelogenin that is beneficial in the treatment of stalled chronic wounds was studied.

METHODS

Fibroblast proliferation was monitored by time-resolved growth curves and factors secreted into the culture medium containing 10% fetal bovine serum were measured by enzyme-linked immunosorbent assays. Fibroblast-mediated reorganization was examined in three-dimensional type I collagen matrices.

RESULTS

Cell proliferation over 9 days was significantly (P < 0.01) slower for CRL-7815 than for normal fibroblasts. Amelogenin at 1 mg mL(-1) increased (P < 0.01) CRL-7815 proliferation to the level of the normal fibroblasts. The neutrophil chemoattractant interleukin (IL)-8 was low while the constitutive production of monocyte chemoattractant protein (MCP)-1 was highly elevated in medium from cultured CRL-7815 fibroblasts. Amelogenin augmented IL-8 but attenuated MCP-1 secretion in CRL-7815 fibroblasts. The elevated vascular endothelial growth factor production in CRL-7815 fibroblasts was further increased with amelogenin while increased type I collagen synthesis by CRL-7815 was reduced with 0.1 mg mL(-1) amelogenin. The dramatically impaired collagen matrix remodelling with CRL-7815 fibroblasts (P < 0.001) was slightly improved with amelogenin (P = 0.0011).

CONCLUSIONS

The near-senescent cell line CRL-7815 shares functional anomalies with fibroblasts isolated from nonhealing chronic cutaneous wounds. Amelogenin has the capacity to switch chronic fibroblasts into an acute-like phenotype.

Mechanisms of delayed wound healing by commonly used antiseptics

BACKGROUND

The cytotoxic effects of antiseptics on pivotal cell types of the healing process have been well documented. The purpose of our investigation was to explore the ability of subcytotoxic levels of antiseptics to interfere with fibroblast function.

METHODS

Cell proliferation assays were performed by culturing fibroblasts in the presence of commonly used antiseptics. Migration was evaluated using scratch assays in which monolayers were "wounded" and cellular movement was monitored by digital photography. Matrix metalloproteinase (MMP) release was analyzed by zymography.

RESULTS

H2O2 and povidone-iodine reduced both migration and proliferation of fibroblasts in a dose-dependent fashion. Treatment with silver-containing antiseptics and chlorhexidine exhibited reductions in proliferation at high concentrations, but enhanced growth at lower doses. Silver-containing compounds and chlorhexidine also proved to be the least detrimental to migration in these assays. metalloproteinase release from the cells was differently affected depending on the dosage and class of antiseptic applied.

CONCLUSIONS

When debridement of the wound bed is not sufficient to reduce bacterial loads, the application of broad-spectrum antiseptics maybe indicated. Our data would suggest that H2O2 and iodine are poor choices, potentially retarding the contribution of fibroblasts to the healing process. Silver sulfadiazine and chlorhexidine, at levels still proven to be bactericidal, had fewer detrimental effects on fibroblast activity in these assays. The silver-containing antiseptics may even increase the proliferative potential of these cells in culture.

Fibroblast dysfunction is a key factor in the non-healing of chronic venous leg ulcers

Chronic age-related degenerative disorders, including the formation of chronic leg wounds, may occur due to aging of the stromal tissues and ensuing dysfunctional cellular responses. This study investigated the impact of environmental-driven cellular aging on wound healing by conducting a comprehensive analysis of chronic wound fibroblast (CWF) behavior in comparison with patient-matched healthy skin normal fibroblasts (NF). The dysfunctional wound healing abilities of CWF correlated with a significantly reduced proliferative life span and early onset of senescence compared with NF. However, pair-wise comparisons of telomere dynamics between NF and CWF indicated that the induction of senescence in CWF was telomere-independent. Microarray and functional analysis suggested that CWFs have a decreased ability to withstand oxidative stress, which may explain why these cells prematurely senescence. Microarray analysis revealed lower expression levels of several CXC chemokine genes (CXCL-1, -2, -3, -5, -6, -12) in CWF compared with NF (confirmed by ELISA). Functionally, this was related to impaired neutrophil chemotaxis in response to CWF-conditioned medium. Although the persistence of non-healing wounds is, in part, due to prolonged chronic inflammation and bacterial infection, our investigations show that premature fibroblast aging and an inability to correctly express a stromal address code are also implicated in the disease chronicity.

A CXCL5- and bFGF-dependent effect of PDGF-B-activated fibroblasts in promoting trafficking and differentiation of bone marrow-derived mesenchymal stem cells

Adult bone marrow-derived mesenchymal stem cells (MSCs) are able to differentiate into myofibroblasts and be recruited into wound lesions and contribute to wound healing. The cellular and molecular mechanisms responsible for MSC trafficking and differentiation, however, are poorly understood. Local resting resident fibroblasts are activated after injury and play a critical role in recruiting MSCs. We investigated the role of platelet-derived growth factor-B-activated fibroblasts (PDGF-B-aFBs) in regulating recruitment, migration and differentiation of MSCs from GFP transgenic mice in an in vitro wound healing assay and a novel three-dimensional (3D) model. PDGF-B-aFBs caused significant increases in MSC migration velocity compared to control as demonstrated by time-lapse photography in an in vitro wound healing assay. Consistently, invasion/migration of MSCs into 3D collagen gels was enhanced in the presence of PDGF-B-aFBs. In addition, PDGF-B-aFBs induced differentiation of MSCs into myofibroblast. The regulatory effects of PDGF-B-aFBs are likely to be mediated by basic fibroblast growth factor (bFGF) and epithelial neutrophil activating peptide-78 (ENA-78 or CXCL5) as protein array analysis indicated elevated levels of these two soluble factors in culture supernatant of PDGF-B-aFBs. Blocking antibodies against bFGF and CXCL5 were able to inhibit both trafficking and differentiation of MSCs into 3D collagen gels while supplement of exogenous bFGF and/or CXCL5 promoted invasion/migration of MSCs into 3D collagen gels. Our results reveal that PDGF-B-aFBs play a key role in the recruitment/migration and differentiation of MSCs and implicate a bFGF- and CXCL5-dependent mechanism in mediating these effects.

Time- and dose-dependent effects of chronic wound fluid on human adult dermal fibroblasts

BACKGROUND

Wound healing is a biologic process that is altered in patients affected by chronic venous ulcers. The wound microenvironment is reflected in the chronic wound fluid (CWF), an exudate containing serum components and tissue-derived proteins.

OBJECTIVES

We investigated the effects of increasing doses of CWF collected from patients suffering from chronic venous ulcers on human adult dermal fibroblasts cultured in vitro and the relationship among CWF effects and treatment length.

METHODS

Fibroblasts were treated with 60, 240, and 720 microg/mL CWF for 3 and 7 days. We evaluated cell proliferation and viability by MTT and Trypan blue assay, cell morphology by light microscopy, F-actin microfilaments organization by tetramethylrhodamine B isothiocyanate-conjugated phalloidin, alpha-smooth muscle actin expression by immunofluorescence, and senescence-associated beta-galactosidase activity.

RESULTS

CWF induced an increase in cell proliferation in the first 3 days of treatment. In contrast, at 7 days, a strong decrease in cell viability was observed. These changes were related to a cytoskeletal F-actin reorganization and not to fibroblast-myofibroblast differentiation nor to changes in cellular senescence.

CONCLUSIONS

This study shows a dose-dependent and biphasic effect of CWF on dermal fibroblasts, suggesting that a continuous exposure to chronic wounds microenvironment may induce late cellular dysfunctions possibly involved in the delayed wound healing.

Recent insights into the causes of chronic leg ulceration in venous diseases and implications on other types of chronic wounds

Venous ulceration represents the most prevalent form of difficult-to-heal wounds and these problematic wounds require a significant amount of healthcare resources for their treatment. In order to develop effective treatment regimens a clearer understanding of the underlying pathological processes that lead to skin breakdown is required. However, to date, most of these studies have tended to focus on describing the pathology of already-established ulcers. By bringing together relevant aspects of diverse disciplines such as inflammation, cardiovascular, and connective tissue biology, we aim to provide an insight into how circulatory abnormalities that are caused by the underlying disease etiology can induce local tissue inflammation resulting in tissue breakdown. Initially this results in internal tissue damage but if the underlying disease is not treated, the internal tissue damage can worsen and lead to open ulceration. This article discusses the cause-and-effect relationships between chronic venous insufficiency and venous ulceration, focusing particularly on the biological processes that lead from the underlying disease condition to overt ulceration. Available evidence also suggests that formation of pressure, diabetic foot and arterial ulcers, and ulcers as results of blood disorders, is also likely to share some of the same biological processes as venous ulcers.

Advances in wound dressings

Wound dressings have undergone an evolutionary process from natural materials that simply covered and concealed the wound, to materials that focused on moisture management, and more recently, to materials that either deliver active ingredients or interact directly with cells or specific chemicals in the local wound environment. Advances in dressings technology have led to a new proliferation of topical products that do more than just cover and conceal, but that also can facilitate the healing process as well as address specific issues in nonhealing wounds. Dressings may play an important adjunctive role in concert with overall efforts to manage the underlying causes of chronic nonhealing wounds.

Wound bed preparation and a brief history of TIME

Management of chronic wounds has progressed from merely assessing the status of a wound to understanding the underlying molecular and cellular abnormalities that prevent the wound from healing. The concept of wound bed preparation has simultaneously evolved to provide a systematic approach to removing these barriers to natural healing and enhancing the effects of advanced therapies. This brief review of wound bed preparation traces the development of these concepts and explains how to apply systematic wound management using the TIME acronym - tissue (non viable or deficient), infection/inflammation, moisture (imbalance) and edge (non advancing or undermined).

Maggots and wound healing: an investigation of the effects of secretions from Lucilia sericata larvae upon the migration of human dermal fibroblasts over a fibronectin-coated surface

Lucilia sericata larvae, or greenbottle fly maggots, placed within chronic wounds have been observed to remove necrotic tissue and infection. They are also believed to actively promote granulation tissue formation. Interactions between fibroblasts and the surrounding extracellular matrix play a crucial role in tissue formation, influencing fibroblast proliferation, migration, and tissue remodeling. For example, the strength of cell adhesion to surfaces coated with extracellular matrix influences cell motility. L. sericata larval excretory/secretory products having previously been shown to modify fibroblast adhesion to collagen and particularly fibronectin, it was hypothesized that these products would alter fibroblast migration. This was investigated using a two-dimensional in vitro wound assay, time-lapse digital photography, enzyme class-specific substrates and inhibitors, and gel electrophoresis. Results showed that L. sericata excretory/secretory products promoted fibroblast migration upon a fibronectin-coated surface. This was related to the degradation of fibronectin by serine proteinases within maggot excretion/secretions. The presence of a metalloproteinase activity may also have played a role. Thus, a possible mechanism by which maggots enhance tissue formation within wounds may be via the promotion of fibroblast motility, providing for a wider distribution of viable fibroblasts.

Pressure elevation slows the fibroblast response to wound healing

OBJECTIVE

Chronic venous insufficiency and venous ulceration are consequences of elevated pressure within affected limbs. We hypothesized that wounded cells maintained at different atmospheric pressures heal at different rates and that pressure would adversely affect the processes necessary for wound healing.

METHODS

We have developed an in vitro model that replicates venous hypertension in a unique pressurized incubator using neonatal fibroblasts. Neonatal fibroblasts grown to confluence were wounded with a standardized linear incision and then placed in a unique pressure incubator at atmospheric pressure, atmospheric pressure plus 30 mm Hg, atmospheric pressure plus 60 mm Hg, and atmospheric pressure plus 120 mm Hg. Cells were observed daily until complete healing of the wound occurred. Twelve to 18 hours after wounding, proliferating cell nuclear antigen analysis was done by immunocytochemistry.

RESULTS

Wounds at atmospheric pressure plus 30 mm Hg were healed by day 3, those at atmospheric pressure plus 60 mm Hg by day 4, and those grown at atmospheric pressure plus 120 mm Hg took > or =4 days for complete healing. Significantly less proliferating cell nuclear antigen activity was present in cells grown at atmospheric pressure plus 60 mm Hg (P < .0001) and atmospheric pressure plus 120 mm Hg (P < .02). Wound edge fluorescence analysis demonstrated less fluorescence in each group compared with atmospheric pressure.

CONCLUSIONS

In this model of wound healing under pressure, neonatal fibroblasts grown to confluence and given a standardized wound displayed characteristics consistent with delayed healing. Elevated pressure has a role in the delayed migration and proliferation seen in this model.

CLINICAL RELEVANCE

The elevated pressure in patients with venous insufficiency causes their wounds to heal less quickly. Understanding and quantifying the physiology and role of elevated tissue pressure due to venous hypertension will lead to a better understanding of wound healing in these patients.

Extracellular matrix metabolites as potential biomarkers of disease activity in wound fluid: lessons learned from other inflammatory diseases?

The new era of pharmacogenetics has identified a potential for individuals to receive customized treatments for a variety of disease states. For such individualized treatments to fulfil their potential, it will be essential for clinicians to be able to monitor disease activity, ideally in a rapid, noninvasive fashion. The accessibility of the skin offers much potential to develop noninvasive tests of metabolic and disease activity for clinical use. Impaired human wound healing in the skin is a chronic inflammatory disorder in which the development of such tests has considerable potential, aiding clinical decision making and monitoring responses to treatment. This review article discusses how studies in other human diseases have highlighted potential biochemical markers (biomarkers) of disease activity in secreted biofluids, as aids to determining disease and metabolic activity within tissues. Using, as examples, lessons learned in the study of disease activity and prognosis of other chronic inflammatory conditions, such as osteoarthritis and periodontal disease, this review highlights the potential of dermal extracellular matrix (ECM) components (collagens, proteoglycans, hyaluronan and glycoproteins) for such uses. The limitations of currently utilized techniques and the concept that analysis of ECM components in wound fluid may represent useful biomarkers of disease activity are also discussed.

Maggots and wound healing: an investigation of the effects of secretions from Lucilia sericata larvae upon interactions between human dermal fibroblasts and extracellular matrix components

BACKGROUND

Through clinical observation, Lucilia sericata (greenbottle fly) larvae are credited with exerting the following beneficial effects upon a chronic nonhealing wound: removal of necrotic tissue ('debridement'), disinfection of the wound and active promotion of granulation tissue formation. As a major cellular component of granulation tissue, fibroblasts play an extensive role in healing. The composition of extracellular matrix (ECM) located in the wound is another important factor, partaking in a dynamic feedback loop with the fibroblasts that produce it. Fibroblast-ECM interactions therefore exert considerable influence upon new tissue formation.

OBJECTIVES

To investigate the effects of L. sericata larval excretory/secretory products (ES) upon the behaviour of fibroblasts, seeded upon ECM component surfaces.

METHODS

ES were collected by washing freshly hatched larvae in phosphate-buffered saline. Human dermal neonatal fibroblast cells were seeded upon fibronectin- or collagen-coated surfaces, together with untreated (or 'native') ES, heat-treated ES, or no ES (ES blank). Following incubation, fibroblast adhesion was determined using an adenosine triphosphate assay and, for confirmation, a total nucleic acid content assay. Cell spreading was observed using microscopy. The effect of ES upon fibronectin structure was observed using sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Peptide sequencing of suspected fibronectin fragments was performed using an 'electrospray' type time of flight mass spectrometer and 'Peptident' database search.

RESULTS

ES significantly reduced fibroblast adhesion to both fibronectin and, to a lesser extent, collagen. Cell spreading was also reduced, yet cells remained viable. For both spreading and adhesion, heat-treated ES exerted significantly less activity than native, untreated ES. However, they still exhibited significant activity when compared with the ES blank. ES appeared to modify fibroblast adhesion indirectly via proteolytic fragmentation of the fibronectin protein surface.

CONCLUSIONS

L. sericata larval secretions modify fibroblast adhesion and spreading across ECM protein surfaces, while keeping cells viable. Proteolytic activity of the ES played a significant role. If transferred to the wound situation, such alteration of fibroblast-ECM interactions may enhance new tissue formation.

An analysis of replicative senescence in dermal fibroblasts derived from chronic leg wounds predicts that telomerase therapy would fail to reverse their disease-specific cellular and proteolytic phenotype

The accumulation of senescent fibroblasts within tissues has been suggested to play an important role in mediating impaired dermal wound healing, which is a major clinical problem in the aged population. The concept that replicative senescence in wound fibroblasts results in reduced proliferation and the failure of refractory wounds to respond to treatment has therefore been proposed. However, in the chronic wounds of aged patients the precise relationship between the observed alteration in cellular responses with aging and replicative senescence remains to be determined. Using assays to assess cellular proliferation, senescence-associated staining beta-galactosidase, telomere length, and extracellular matrix reorganizational ability, chronic wound fibroblasts demonstrated no evidence of senescence. Furthermore, analysis of in vitro senesced fibroblasts demonstrated cellular responses that were distinct and, in many cases, diametrically opposed from those exhibited by chronic wound fibroblasts. Forced expression of telomerase within senescent fibroblasts reversed the senescent cellular phenotype, inhibiting extracellular matrix reorganizational ability, attachment, and matrix metalloproteinase production and thus produced cells with impaired key wound healing properties. It would appear therefore that the distinct phenotype of chronic wound fibroblasts is not simply due to the aging process, mediated through replicative senescence, but instead reflects disease-specific cellular alterations of the fibroblasts themselves.

Sustained ability for fibroblast outgrowth from stored neonatal foreskin: a model for studying mechanisms of fibroblast outgrowth

Fibroblast cultures derived from neonatal foreskin explants have been an important model for understanding the basic mechanisms of fibroblast function and activity. Neonatal foreskin has been routinely used for establishing such fibroblast cultures in vitro. In general, tissue explants and fibroblast cultures are established from freshly harvested neonatal foreskin tissue. It is unknown whether prolonged storage of tissue, even in optimal growth media and conditions would still result in successful explant outgrowth. Specifically, no studies have properly examined the maximal duration of foreskin storage that can produce viable fibroblasts with normal growth and synthetic characteristics. We, therefore, set out to isolate and propagate fibroblast cultures from neonatal foreskin tissue that had been kept in complete culture media at 4 degrees C for various periods of time. We found that outgrowth and propagation of viable fibroblasts in vitro occurred with foreskin samples obtained within 24 days after surgical harvesting. The morphology, cellular proliferative capacity (measured by [3H]-thymidine uptake), steady state levels of alpha1(I) procollagen mRNA, and collagenous protein synthesis were comparable among fibroblast cultures derived from foreskin explants established 3 days (control) and up to 24 days (but not 38 days) after tissue harvesting. These studies demonstrate that viable and functional fibroblasts, with apparently similar in vitro characteristics, can be isolated and propagated from explants of neonatal foreskin tissue that have undergone prolonged storage. Moreover, these findings may be useful in understanding the lack of fibroblast growth in such conditions as found in delayed wound healing and aging.