Retrospective analysis of 56 soft tissue defects treated with one-stage reconstruction using dermal skin substitutes

Management of Hardware-Exposed Soft Tissue Defects Using Dermal Substitutes and Negative Pressure Wound Therapy

INTRODUCTION

Reconstruction of complex injuries of the extremities with full-thickness wounds is a challenging but important task. If primary closure is not feasible, more complex procedures are required, such as split-thickness skin graft or flap surgery. Recently, several studies have shown good results when combined with negative pressure wound therapy (NPWT) and artificial dermal replacement therapy after extensive surgical debridement and NPWT administration for severe complex wounds accompanied by tendon or bone exposure. However, flap surgery remains the only treatment for wounds in which the hardware is exposed after fracture fixation. Therefore, in this study, we attempted to prove the usefulness of the combined treatment using artificial dermal substitutes (MatriDerm) and NPWT by focusing on hardware-exposed wounds, which have not been studied before.

METHODS

From 2019 to 2021, we treated with our wound management procedure 14 patients with hardware-exposing wounds after internal fixation using plates, out of 48 patients with full-thickness posttraumatic skin defect. Before skin grafting, after surgical debridement and thorough washouts, MatriDerm was placed and NPWT was applied over it. This staged approach aimed at conditioning even the most complex wounds so that closure with MatriDerm-augmented skin grafting would become possible in a one-step approach.

RESULTS

We stratified the duration of treatment and number of replacements in NPWT according to the type of injury. Cases with open fractures required significantly longer NPWT than those with closed fractures (P = 0.01); however, there was no significant difference between the Gustilo-Anderson classification within open fractures (P > 0.05). Patients with open fractures underwent a mean of 6.6 changes while those with closed fractures underwent 2.5 (P = 0.002) until the final wound closure with MatriDerm-augmented skin grafting was performed. There was no significant difference in the treatment period based on the location and size of the wound, and there was no significant difference in the number of NPWT replacements. Skin grafting was successful in all 14 patients.

CONCLUSIONS

This study revealed that NPWT and artificial dermis-augmented skin grafting after combined treatment with NPWT and artificial dermis were sufficiently useful for hardware-exposed wounds, where flap surgery has been considered the only treatment to date.

The LipoDerm Method for Regeneration and Reconstruction in Plastic Surgery: A Technical Experimental Ex Vivo Note

The combination of adipose-derived stem cells (ASCs) and dermal scaffolds has been shown to be an approach with high potential in soft tissue reconstruction. The addition of dermal templates to skin grafts can increase graft survival through angiogenesis, improve regeneration and healing time, and enhance the overall appearance. However, it remains unknown whether the addition of nanofat-containing ASCs to this construct could effectively facilitate the creation of a multi-layer biological regenerative graft, which could possibly be used for soft tissue reconstruction in the future in a single operation. Initially, microfat was harvested using Coleman's technique, then isolated through the strict protocol using Tonnard's technique. Finally, centrifugation, emulsification, and filtration were conducted to seed the filtered nanofat-containing ASCs onto Matriderm for sterile ex vivo cellular enrichment. After seeding, a resazurin-based reagent was added, and the construct was visualized using two-photon microscopy. Within 1 h of incubation, viable ASCs were detected and attached to the top layer of the scaffold. This experimental ex vivo note opens more dimensions and horizons towards the combination of ASCs and collagen-elastin matrices (i.e., dermal scaffolds) as an effective approach in soft tissue regeneration. The proposed multi-layered structure containing nanofat and dermal template (Lipoderm) may be used, in the future, as a biological regenerative graft for wound defect reconstruction and regeneration in a single operation and can also be combined with skin grafts. Such protocols may optimize the skin graft results by creating a multi-layer soft tissue reconstruction template, leading to more optimal regeneration and aesthetic outcomes.

Long-term results of split-thickness skin grafting with and without additional dermal matrix in severe traumatic soft tissue defects of the lower limb

PURPOSE

Aim of this study was to compare the use of split-thickness skin graft (STSG) with and without additional MatriDerm^® application in a predominantly one-step procedure for the treatment of severe traumatic soft tissue defects of the lower limb.

METHODS

This retrospective study included patients treated in a European level I trauma center between June 2013 and July 2018 in terms of a severe traumatic soft tissue defect of the lower extremity using STSG alone or in combination with the acellular dermal substitute MatriDerm^®. The healing of the soft tissue defect was measured by assessment of the take rate. Outcome quality of the scar tissue was assessed using the Vancouver Scar Scale.

RESULTS

A total of 147 cases were included in this study. The overall healing rate (number of patients with take rate ≥ 75%) was 88/147 (60%) and did not demonstrate significant differences between the treatment groups (p = 0.15). Despite the difference in wound complexity between the treatment groups, there was no difference regarding the scar tissue quality 12 months postoperatively. In about 25% of all cases, a post-operative event was mentioned that had to be revised surgically.

CONCLUSION

Surgical treatment with STSG and additional MatriDerm^® application can be recommended as satisfactory alternative for dermis replacement in patients with severe skin defects, independent of age. The additional MatriDerm^® use allows for bridging of exposed ligaments, tendons, vessels or bones without relevant differences in cosmetical outcome.

Long-term experience with a collagen-elastin scaffold in combination with split-thickness skin grafts for the treatment of full-thickness soft tissue defects: improvements in outcome-a retrospective cohort study and case report

Purpose

The management of severe soft tissue injuries to the extremities with full-thickness wounds poses a challenge to the patient and surgeon. Dermal substitutes are used increasingly in these defects. The aim of this study was to investigate the impact of the type of injury on the success rate of Matriderm® (MD)-augmented split-thickness skin grafting, as well as the role of negative pressure wound therapy (NPWT) in preconditioning of the wounds, with a special focus on the reduction of the bioburden.

Methods

In this study, 45 wounds (44 affecting lower extremities (97.7%)), resulting from different types of injuries: soft tissue (ST), soft tissue complications from closed fracture (F), and open fracture (OF) in 43 patients (age 55.0 ± 18.2 years, 46.7% female), were treated with the simultaneous application of MD and split-thickness skin grafting. The study was designed as a retrospective cohort study from March 2013 to March 2020. Patients were stratified into three groups: ST, F, and OF. Outcome variables were defined as the recurrence of treated wound defects, which required revision surgery, and the reduction of bioburden in terms of reduction of number of different bacterial strains. For statistical analysis, Student’s t-test, analysis of variance (ANOVA), Mann–Whitney U test, and Pearson’s chi-squared test were used.

Results

There was no significant difference in the rate of recurrence in the different groups (F: 0%; OF: 11.1%; ST: 9.5%). The duration of VAC therapy significantly differed between the groups (F: 10.8 days; OF: 22.7 days; ST: 12.6 days (p < 0.05)). A clinically significant reduction of bioburden was achieved with NPWT (bacterial shift (mean (SD), F: − 2.25 (1.89); OF: − 1.9 (1.37); ST: − 2.6 (2.2)).

Conclusion

MD-augmented split-thickness skin grafting is an appropriate treatment option for full-thickness wounds with take rates of about 90%. The complexity of an injury significantly impacts the duration of the soft tissue treatment but does not have an influence on the take rate. NPWT leads to a relevant reduction of bioburden and is therefore an important part in the preconditioning of full-thickness wounds.

Salvage of a mangled limb with Matriderm® augmented split-skin grafting and maggot biodebridement

Salvage of a mangled limb can be a long and strenuous way, but it is feasible even with rather simple techniques such as augmented split-skin grafting and maggot biodebridement.

Matriderm dermal substitute in the treatment of post traumatic hand's fingertip tissue loss

INTRODUCTION

Treatment of fingers tissue loss is particularly challenging as it often necessitates advanced reconstructive techniques such as flaps or grafts, with esthetic and functional results that are not always as good as hoped for, with long healing times. Recently, along with tissue engineering development, numerous types of dermal substitute have been commercialized, with promising possibilities of treatment in finger tissue loss. In the author's unit, Matriderm^® is the most commonly used dermal substitute. As described by the manufacturer, this scaffold is designed to be covered with a split-thickness skin graft. In using a two-step procedure, the authors realized that in most cases of fingertips injuries, at three weeks follow-up, the wound appeared in an advanced state of healing, which permitted to avoid grafting.

MATERIAL AND METHODS

Between October 2017 and October 2018, 27 fingers have been included in this study. Patients have been divided in two groups: those treated with Matriderm^® alone (15 fingers) and those who had a skin graft three weeks after the first surgery (12 fingers). At the 6-month follow-up, authors evaluated the esthetic results with the Vancouver Scar Scale (VSS), the functional results with Quick Disability of the Arm, Shoulder and Hand (qDASH) score, and sensibility by the mean of two-point discrimination test (2-PD).

RESULTS

All outcomes were overlapping in patients treated with or without skin graft: mean VSS was 2.3, mean qDASH was 13.3, and mean 2-PD was 7.7 mm.

CONCLUSIONS

The results obtained allow to consider Matriderm^® , used also without skin graft coverage, as a valid solution for treatment of fingertip tissue loss.

Biological dermal templates with native collagen scaffolds provide guiding ridges for invading cells and may promote structured dermal wound healing

Dermal substitutes are of major importance in treating full thickness skin defects. They come in a variety of materials manufactured into various forms, such as films, hydrocolloids, hydrogels, sponges, membranes, and electrospun micro- and nanofibers. Bioactive dermal substitutes act in wound healing either by delivery of bioactive compounds or by being constructed from materials having endogenous activity. The healing success rate is highly determined by cellular and physiological processes at the host-biomaterial interface during crucial wound healing steps. Hence, it is important to design appropriate wound treatment strategies with the ability to work actively with tissues and cells to enhance healing. Therefore, in this study, we investigated biological dermal templates and their potential to stimulate natural cell adherence, guidance, and morphology. The most pronounced effect was observed in biomaterials with the highest content of native collagen networks. Cell attachment and proliferation were significantly enhanced on native collagen scaffolds. Cell morphology was more asymmetrical on such scaffolds, resembling native in vivo structures. Importantly, considerably lower expression of myofibroblast phenotype was observed on native collagen scaffolds. Our data suggest that this treatment strategy might be beneficial for the wound environment, with the potential to promote improved tissue regeneration and reduce abnormal scar formation.