KENT
Advanced Wound Healing

Bioabsorbable Temporizing Matrix (BTM): Not Just for Burns
Mark S. Granick, MD, Professor of Surgery, Ashley Ignatiuk, MD, Assistant Professor of Surgery, Edward S. Lee, MD, Associate Professor of Surgery, Rutgers New Jersey Medical School, Newark, NJ, James Yang, MD, St. Joseph’s Hospital, Paterson, NJ

1700

 

Abstract


A skin substitute developed in Australia 2 decades ago for use in acute burns was recently introduced into the United States for the treatment of open wounds. This product has been shown to be very efficacious for coverage of debrided burn wounds. It consists of an inorganic synthetic woven layer that induces cellular ingrowth and deposition of interstitial tissue. It is covered by an attached silicone layer that seals the wound. The product is placed with the woven side directly on the wound. It is fixed in place and optimally covered by a negative pressure dressing for the first 5-10 days. Due to its synthetic composition, it is highly resistant to infection and can stay on the wound for as long as needed. The authors have used this matrix in a wide variety of complex reconstructions in 27 patients, consisting of 10 females and 17 males. Eleven had traumatic wounds of various etiologies (deep burns, crush injuries, Morell-Lavallee lesion, hand injuries, multiple trauma, open fractures, compartment syndromes and soft tissue avulsions). The following wounds were also treated with BTM: pressure ulcers, axillary hidradenitis, scalp wounds, severe facial acne keloidalis, Fournier’s gangrene, a diabetic foot ulcer, a chronic venous ulcer, a cutaneous pyoderma gangrenosum, a radiation ulcer with exposed Achilles tendon, a disfiguring scar from an old Dupytrens excision and a non-healing chemotherapy extravasation ulcer. Hand and leg wounds with exposed tendon achieved coverage without tethering. The scalp wounds developed a neodermis and were skin-grafted. A pyoderma gangrenosum patient with excessive slough and uncontrolled bleeding was temporarily immunosuppressed, aggressively debrided and covered with the matrix. Her bleeding resolved. She developed a neodermis, and had reduced symptoms. The Fournier’s patient had immediate skin-grafting of his penis and testicles, but the remaining extensive perineal and upper thigh wounds were treated with the matrix and healed without additional skin grafting. A hand patient with a forearm fasciotomy wound was covered with the matrix. As the swelling resolved the size of the defect decreased to the point that the wound was delaminated. The adjacent skin was elevated and used to cover the open area, achieving full closure. There were no complications attributed to the use of the matrix. Several patients healed secondarily with the silicone sheeting gradually peeling off. Seven patients have received or are awaiting skin grafts to be placed over the neodermis. Although this is an early review of the use of this synthetic matrix in the US, it comes with a positive legacy from Australia. The findings thus far indicate that there is a wide range of applications for this product well beyond burn care. Its safety record, resistance to infection and ease of use facilitate surgery.

 

 

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Use of Topical Gaseous Nitric Oxide/Plasma Energy in the Treatment of Recalcitrant Wounds

Terry Treadwell, MD, FACS, FAAWC, Wound Care Solutions, LLC, Montgomery, AL

1707

 

Abstract


Nitric oxide (NO) is involved in many biological functions and has been demonstrated to be important in wound healing. When delivered to a wound in its gaseous state, NO stimulates vasodilatation and angiogenesis, inhibits platelet and erythrocyte aggregation, reduces leukocyte adhesion, and is an important anti-inflammatory and antimicrobial agent.
Many patients with chronic and hard-to-heal wounds have a deficiency of NO in their tissues ,which may contribute to slow and even arrested healing. However, it has been difficult to use NO for treatment because of its short half-life, which is measured in seconds.
A recently developed device provides a way to generate NO and combine it with a stream of plasma energy, which extends its half-life to the point that it can provide a clinical effect. This device creates NO from the ambient air, and no other gases are needed. The combination of atmospheric oxygen and nitrogen at a high temperature generated by an electric arc results in NO and plasma energy (N2 + O2 = 2NO + 181 KJ energy). After generation, the NO/plasma energy-containing gas flow is cooled to 18–20°C, and NO is delivered to the tissues in a “dose” between 800 and 1000 ppm. When NO gas was combined with the plasma energy stream, the NO was found to penetrate intact skin or tissue up to 3cm to treat an underlying problem.
Studies have shown that NO/plasma energy therapy promotes healing. This report summarizes current applications of this unique approach in the treatment of chronic, hard-to-heal and infected wounds.

 

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Efficacy of a 3D Electrospun Synthetic Polymer Matrix on Hard-to-Heal Wounds

C. Jake Lambert, Jr, MD, FACS, CWSP, Clinic PA, Winter Haven, Florida, Frank Aviles, Jr, PT, CWS, FACCWS, CLT-LANA, ALM, AWCC, Hyperbaric Physicians of Georgia, Cumming, Georgia, Kristen A. Eckert, Mphil, Strategic Solutions, Inc., Bozeman, Montana, Matthew Garoufalis, DPM, FASPS, FACPM, CWS, Professional Foot Care Specialists, PC, Chicago, Illinois, Richard A. Schilling, DPM, FACFAS, ABC Podiatry, Columbus, Ohio

1744

 

Abstract


Introduction: The aim of this study was to evaluate the efficacy of a 3D electrospun synthetic polymer matrix (3DESPM) on hard-to-heal wounds. Materials and Methods: This prospective case series took place at four sites. The primary endpoints were the percentage area reduction (PAR) in wound area at four and eight weeks. Secondary endpoints included time to heal (Kaplan-Meier analysis) and the proportion of healed wounds at 12 weeks. After applying 3DESPM, the physician applied sterile saline, as appropriate, to adhere the matrix to the wound bed and facilitate the polymer degradation process. A nonadherent dressing, a secondary dressing, and additional bandages (as needed) were then applied. The physician left the product on the wound until complete degradation was observed, as appropriate, and reapplied, as appropriate. Combination advanced therapies were applied, per physician discretion.
Results: Thirty-eight patients (mean age: 64.3 years [SD: 17.6]) with 50 wounds (35 chronic, 70%) participated. The mean number of comorbidities per patient was 4.4 (2.3). All wounds received 3DESPM; 12 wounds (24%) received combination therapies; and 38 wounds (76%) completed the study. The mean (SD) PAR at four and eight weeks was 67.6% (38%) and 80% (35%), respectively. Thirty-three wounds (66%) healed at 12 weeks. The Kaplan-Meier mean time to heal for all wounds was 49.0 days (95% confidence interval: 41.3–56.7).
Conclusions: In a complex patient population with severe comorbidities and heterogeneous wounds, 3DESPM appeared to accelerate the stalled healing process to contribute to wound closure. Further investigation of 3DESPM on a larger patient population and in a controlled setting is pending.

 

 

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