Miniaturized Negative-Pressure Wound Therapy for Split-Thickness Skin Graft Donor Sites

• Methods
• Results
• Discussion
• Conclusion
• References

Abstract

Background Multiple therapeutic options exist for the treatment of split-thickness skin graft (STSG) donor sites, but there is no clear consensus among surgeons about the best option. Negative-pressure wound therapy (NPWT) has rapidly gained in popularity since its invention. Recently, several miniaturized, single-patient NPWT (SP-NPWT) devices have become available. Compared with traditional NPWT devices, SP-NPWT devices are associated with equal wound healing capability and reliability, but offer several advantages. We present a series of 10 consecutive patients whose STSG donor sites were treated with a commercially available SP-NPWT device.

Methods We performed a retrospective review for 10 consecutive patients who underwent STSG procedures and were treated with SP-NPWT devices.

Results From 2015 to 2017, 10 consecutive patients underwent oncologic reconstruction using STSG and had their donor sites treated with SP-NPWT devices. The SP-NPWT dressing had been left in place for 2 weeks after surgery. The average donor site area measured 80 cm² (range: 76–106 cm²). In all 10 patients, the donor sites healed uneventfully and with no complications.

Conclusion Off-the-shelf, miniaturized, SP-NPWT systems appear to be at least as effective as traditional dressings for STSG donor sites and require no maintenance (skilled nursing or dressing changes). Compared with larger and less portable standard NPWT devices, SP-NPWT dressing systems provide a potential cost benefit as well as enhanced convenience and portability.

Skin grafting is one of the procedures most commonly performed by plastic and reconstructive surgeons. Harvesting a split-thickness skin graft (STSG) removes the entire epidermal layer as well as a partial-thickness dermal layer that provides the structural support for the graft. The partial-thickness wound that is created at the donor site heals by re-epithelialization via migration of keratinocytes (epidermal cells).[1] To ensure robust healing by secondary intention, the wound should be protected from desiccation and mechanical trauma. There are a variety of methods used to treat STSG donor sites, as indicated in a recent systematic review of wound dressings for skin graft donor sites.[2] Among the non-occlusive dressings, the most commonly used were Xeroform (DeRoyal Industries, Inc., Powell, TN), Scarlet Red (Kendall Healthcare, Mansfield, MA), and Jelonet (Smith & Nephew, Hull, United Kingdom), whereas Kaltostat (ConvaTec, Oklahoma City, OK), Opsite (Smith & Nephew, Hull, United Kingdom), DuoDERM (ConvaTec, Oklahoma City, OK), and Allevyn (Smith & Nephew, Hull, United Kingdom) were the most frequently used occlusive or absorbent dressings.[2]

The use of negative-pressure wound therapy (NPWT) has increased rapidly since it was first described in 1997.[3] [4] There are many indications[1] [5] [6] [7] now for the use of NPWT, including stabilization and bolstering of STSGs,[8] [9] [10] [11] [12] [13] [14] and as a dressing for skin graft donor sites.[15] [16] Over the past several years, several miniaturized, disposable, single-patient NPWT (SP-NPWT) devices have been introduced.[5] [6] [17] [18] [19] [20] [21] These devices have the potential to simplify wound care in the management of skin graft donor sites in the outpatient setting. The authors describe a series of 10 patients with STSG donor site wounds treated with an off-the-shelf, miniaturized, SP-NPWT device.

Methods

Our institutional review board approved a retrospective review of our patient database.

From 2015 to 2017, the donor sites of 10 consecutive patients who underwent STSG procedures were treated with SP-NPWT devices (PICO System, Smith & Nephew, Hull, UK) by a single surgeon (P.G.C.). The skin grafts were each harvested using an electric dermatome (with a 3-inch (7.62 cm) guard) set to 0.013-inch (0.033 cm) thickness. The donor sites were dressed with either a fine-mesh gauze impregnated with 3% bismuth tribromophenate and petrolatum (Xeroform, DeRoyal Industries, Inc., Powell, TN) or a knitted cellulose acetate fabric impregnated with petrolatum (Adaptic, Acelity, San Antonio, TX) and then were covered with a 15 × 30-cm SP-NPWT dressing ([Fig. 1]). Patients were sent home with the dressing in place, which had been left in place for 2 weeks and was then removed in the outpatient clinic. The SP-NPWT device remained attached until the battery ran out (usually by postoperative day 7). The donor site was assessed for re-epithelialization 2 weeks postoperatively.

Results

All 10 patients underwent oncologic reconstruction at remote sites requiring STSG. The mean age of the patients was 55 years (range: 28–80 years), and five were male. The average dimension of the thigh donor site was 80 cm² (range: 76–106 cm²). In all 10 patients, the donor sites had complete re-epithelialization within 2 weeks. There were no wound healing complications at the STSG donor site in any of the patients ([Fig. 2A] and [B]).

Discussion

Skin-graft donor site wounds may be treated using one of many different dressings, including NPWT.[15] [16] Dressing STSG donor sites with a vacuum-assisted closure (VAC) device has several benefits over traditional dressings, including collection of excess wound exudate, convenience, improved wound healing, and decreased hospital length of stay (LOS). Since the release of off-the-shelf, disposable, miniaturized SP-NPWT devices, such as the PICO System (Smith & Nephew, Hull, UK), many surgeons have begun to use these SP-NPWT devices for several indications[5] [6] [17] [18] [19] [20] [21] that were previously treated with standard VAC devices. Compared with traditional NPWT devices, SP-NPWT devices are associated with equal wound-healing capability[17] [21] and reliability,[5] [6] but have unique benefits.

Following STSG harvest, a significant amount of exudate typically drains from the donor site. When traditional dressings are applied to these wounds, excess fluid may leak from the dressing and can present a management problem for patients and caregivers, necessitating frequent, painful dressing changes. Although it was not formally measured with the use of a standardized patient-reported outcome instrument, the patients in our series did seem to report less pain as compared with patients treated with traditional dressings. Standard NPWT dressings collect these exudates in a canister attached to the device. The PICO System is able to manage the exudate through a combination of an absorbent dressing layer and evaporative loss of the fluid.[17] Since these miniaturized systems do not require a canister, they are much more compact than the standard devices used for NPWT, which allows for increased patient mobility and comfort.[10] [17] This is in contrast to other miniaturized, SP-NPWT systems that do require the use of a small canister, and thus are less able to handle moderate amounts of exudate without being emptied. Both traditional and disposable NPWT devices used to treat STSG donor site wounds may be used continuously for up to 14 days without the need to be changed. No specialty nursing services are required to change dressings or monitor therapy as an outpatient, and patient discomfort is minimized.

NPWT has also been shown to accelerate the healing of STSG donor sites. Nuutila et al[16] examined gene expression and exudate content and found significant induction of genes involved in inflammation and cell proliferation, along with significant suppression of cell differentiation genes on postoperative day 7 in patients treated with NPWT, compared with control. They concluded that short-term use of NPWT improves healing by promotion of inflammation that is associated with cell migration and wound healing, but may inhibit cell differentiation with longer term use. Genecov et al[15] compared the rate of re-epithelialization between one STSG donor site treated with NPWT and another site treated with vapor-permeable dressing. The comparison was initially performed in a porcine model (n = 4), with the second site in the same subject (serving as an internal control), then subsequently in humans (n = 10). They reported more rapid re-epithelialization in 70% of patients treated with NPWT by postoperative day 7 (p < 0.013). In the treatment of other types of wounds, NPWT has also been shown to promote wound granulation and decrease interstitial edema, thereby increasing tissue perfusion.[4] [22] Notably, wound healing with the use of SP-NPWT seems to be at least equivalent to standard NPWT using full-sized devices.[17] [21] SP-NPWT devices have also been shown to decrease postoperative wound complications, compared with standard dressings.[18]

Standard NPWT techniques utilize a device that is rented by the healthcare facility or by the patient in the outpatient setting. When applied in the inpatient setting, patients typically remain in the hospital until insurance authorization has been obtained. In comparison, patients with an off-the-shelf, ultra-portable SP-NPWT dressing may be discharged without insurance approval or the need for specialty nursing services. This leads to reduced LOS in the hospital, compared with patients treated with traditional dressings[6] [18] [23] and traditional NPWT devices[20] and has the potential to decrease healthcare costs. The PICO System costs around $217 which is substantially more than the traditional dressing at $54 per use; however, the majority patients require at least one dressing change with the traditional dressings. Thus, traditional dressings cost closer to $100 per patient; however, the cost of skilled nursing necessary to perform the dressing change is not included in this amount.

Conclusion

SP-NPWT is useful in the management of donor sites following the harvest of STSG. This option appears to be at least as effective as traditional donor site dressings and requires no maintenance, which can be both painful and messy. Compared with larger and less portable standard NPWT devices, the SP-NPWT dressing systems provide a potential cost benefit as well as enhanced convenience and portability.

Conflict of Interest

None.

• References

• 1 Thorne CH, Chung KC, Gosain AK. , et al. Grabb and Smith's Plastic Surgery. 7th ed. Philadelphia, PA: Lippincott Wiliams & Wilkins; 2013
  Google Scholar
• 2 Voineskos SH, Ayeni OA, McKnight L, Thoma A. Systematic review of skin graft donor-site dressings. Plast Reconstr Surg 2009; 124 (01) 298-306
  CrossrefPubMedGoogle Scholar
• 3 Morykwas MJ, Argenta LC, Shelton-Brown EI, McGuirt W. Vacuum-assisted closure: a new method for wound control and treatment: animal studies and basic foundation. Ann Plast Surg 1997; 38 (06) 553-562
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• 4 Argenta LC, Morykwas MJ. Vacuum-assisted closure: a new method for wound control and treatment: clinical experience. Ann Plast Surg 1997; 38 (06) 563-576
  CrossrefPubMedGoogle Scholar
• 5 Payne C, Edwards D. Application of the single use negative pressure wound therapy device (PICO) on a heterogeneous group of surgical and traumatic wounds. Eplasty 2014; 14: e20
  PubMedGoogle Scholar
• 6 Selvaggi F, Pellino G, Sciaudone G. , et al. New advances in negative pressure wound therapy (NPWT) for surgical wounds of patients affected with Crohn's disease. Surg Technol Int 2014; 24: 83-89
  PubMedGoogle Scholar
• 7 Huang C, Leavitt T, Bayer LR, Orgill DP. Effect of negative pressure wound therapy on wound healing. Curr Probl Surg 2014; 51 (07) 301-331
  CrossrefPubMedGoogle Scholar
• 8 Trop M, Schintler M, Urban E, Roedl S, Stockenhuber A. Are 1:4 mesh and donor site contraindications for vacuum-assisted closure device?. J Trauma 2006; 61 (05) 1267-1270
  CrossrefPubMedGoogle Scholar
• 9 Waltzman JT, Bell DE. Vacuum-assisted closure device as a split-thickness skin graft bolster in the burn population. J Burn Care Res 2014; 35 (05) e338-e342
  CrossrefPubMedGoogle Scholar
• 10 Sposato G, Molea G, Di Caprio G, Scioli M, La Rusca I, Ziccardi P. Ambulant vacuum-assisted closure of skin-graft dressing in the lower limbs using a portable mini-VAC device. Br J Plast Surg 2001; 54 (03) 235-237
  CrossrefPubMedGoogle Scholar
• 11 Llanos S, Danilla S, Barraza C. , et al. Effectiveness of negative pressure closure in the integration of split thickness skin grafts: a randomized, double-masked, controlled trial. Ann Surg 2006; 244 (05) 700-705
  CrossrefPubMedGoogle Scholar
• 12 Petkar KS, Dhanraj P, Kingsly PM. , et al. A prospective randomized controlled trial comparing negative pressure dressing and conventional dressing methods on split-thickness skin grafts in burned patients. Burns 2011; 37 (06) 925-929
  CrossrefPubMedGoogle Scholar
• 13 Azzopardi EA, Boyce DE, Dickson WA. , et al. Application of topical negative pressure (vacuum-assisted closure) to split-thickness skin grafts: a structured evidence-based review. Ann Plast Surg 2013; 70 (01) 23-29
  CrossrefPubMedGoogle Scholar
• 14 Moisidis E, Heath T, Boorer C, Ho K, Deva AK. A prospective, blinded, randomized, controlled clinical trial of topical negative pressure use in skin grafting. Plast Reconstr Surg 2004; 114 (04) 917-922
  CrossrefPubMedGoogle Scholar
• 15 Genecov DG, Schneider AM, Morykwas MJ, Parker D, White WL, Argenta LC. A controlled subatmospheric pressure dressing increases the rate of skin graft donor site reepithelialization. Ann Plast Surg 1998; 40 (03) 219-225
  CrossrefPubMedGoogle Scholar
• 16 Nuutila K, Siltanen A, Peura M. , et al. Gene expression profiling of negative-pressure-treated skin graft donor site wounds. Burns 2013; 39 (04) 687-693
  CrossrefPubMedGoogle Scholar
• 17 Malmsjö M, Huddleston E, Martin R. Biological effects of a disposable, canisterless negative pressure wound therapy system. Eplasty 2014; 14: e15
  PubMedGoogle Scholar
• 18 Pellino G, Sciaudone G, Candilio G, Campitiello F, Selvaggi F, Canonico S. Effects of a new pocket device for negative pressure wound therapy on surgical wounds of patients affected with Crohn's disease: a pilot trial. Surg Innov 2014; 21 (02) 204-212
  CrossrefPubMedGoogle Scholar
• 19 Holt R, Murphy J. PICO™ incision closure in oncoplastic breast surgery: a case series. Br J Hosp Med (Lond) 2015; 76 (04) 217-223
  CrossrefPubMedGoogle Scholar
• 20 Gabriel A, Thimmappa B, Rubano C, Storm-Dickerson T. Evaluation of an ultra-lightweight, single-patient-use negative pressure wound therapy system over dermal regeneration template and skin grafts. Int Wound J 2013; 10 (04) 418-424
  CrossrefPubMedGoogle Scholar
• 21 Isaac AL, Rose J, Armstrong DG. Mechanically powered negative pressure wound therapy as a bolster for skin grafting. Plast Reconstr Surg Glob Open 2014; 2 (02) e103
  PubMedGoogle Scholar
• 22 Demaria M, Stanley BJ, Hauptman JG. , et al. Effects of negative pressure wound therapy on healing of open wounds in dogs. Vet Surg 2011; 40 (06) 658-669
  CrossrefPubMedGoogle Scholar
• 23 Khanbhai M, Fosah R, Oddy MJ, Richards T. Disposable NPWT device to facilitate early patient discharge following complex DFU. J Wound Care 2012; 21 (04) 180-182
  CrossrefPubMedGoogle Scholar

Address for correspondence

• References

• 1 Thorne CH, Chung KC, Gosain AK. , et al. Grabb and Smith's Plastic Surgery. 7th ed. Philadelphia, PA: Lippincott Wiliams & Wilkins; 2013
  Google Scholar
• 2 Voineskos SH, Ayeni OA, McKnight L, Thoma A. Systematic review of skin graft donor-site dressings. Plast Reconstr Surg 2009; 124 (01) 298-306
  CrossrefPubMedGoogle Scholar
• 3 Morykwas MJ, Argenta LC, Shelton-Brown EI, McGuirt W. Vacuum-assisted closure: a new method for wound control and treatment: animal studies and basic foundation. Ann Plast Surg 1997; 38 (06) 553-562
  CrossrefPubMedGoogle Scholar
• 4 Argenta LC, Morykwas MJ. Vacuum-assisted closure: a new method for wound control and treatment: clinical experience. Ann Plast Surg 1997; 38 (06) 563-576
  CrossrefPubMedGoogle Scholar
• 5 Payne C, Edwards D. Application of the single use negative pressure wound therapy device (PICO) on a heterogeneous group of surgical and traumatic wounds. Eplasty 2014; 14: e20
  PubMedGoogle Scholar
• 6 Selvaggi F, Pellino G, Sciaudone G. , et al. New advances in negative pressure wound therapy (NPWT) for surgical wounds of patients affected with Crohn's disease. Surg Technol Int 2014; 24: 83-89
  PubMedGoogle Scholar
• 7 Huang C, Leavitt T, Bayer LR, Orgill DP. Effect of negative pressure wound therapy on wound healing. Curr Probl Surg 2014; 51 (07) 301-331
  CrossrefPubMedGoogle Scholar
• 8 Trop M, Schintler M, Urban E, Roedl S, Stockenhuber A. Are 1:4 mesh and donor site contraindications for vacuum-assisted closure device?. J Trauma 2006; 61 (05) 1267-1270
  CrossrefPubMedGoogle Scholar
• 9 Waltzman JT, Bell DE. Vacuum-assisted closure device as a split-thickness skin graft bolster in the burn population. J Burn Care Res 2014; 35 (05) e338-e342
  CrossrefPubMedGoogle Scholar
• 10 Sposato G, Molea G, Di Caprio G, Scioli M, La Rusca I, Ziccardi P. Ambulant vacuum-assisted closure of skin-graft dressing in the lower limbs using a portable mini-VAC device. Br J Plast Surg 2001; 54 (03) 235-237
  CrossrefPubMedGoogle Scholar
• 11 Llanos S, Danilla S, Barraza C. , et al. Effectiveness of negative pressure closure in the integration of split thickness skin grafts: a randomized, double-masked, controlled trial. Ann Surg 2006; 244 (05) 700-705
  CrossrefPubMedGoogle Scholar
• 12 Petkar KS, Dhanraj P, Kingsly PM. , et al. A prospective randomized controlled trial comparing negative pressure dressing and conventional dressing methods on split-thickness skin grafts in burned patients. Burns 2011; 37 (06) 925-929
  CrossrefPubMedGoogle Scholar
• 13 Azzopardi EA, Boyce DE, Dickson WA. , et al. Application of topical negative pressure (vacuum-assisted closure) to split-thickness skin grafts: a structured evidence-based review. Ann Plast Surg 2013; 70 (01) 23-29
  CrossrefPubMedGoogle Scholar
• 14 Moisidis E, Heath T, Boorer C, Ho K, Deva AK. A prospective, blinded, randomized, controlled clinical trial of topical negative pressure use in skin grafting. Plast Reconstr Surg 2004; 114 (04) 917-922
  CrossrefPubMedGoogle Scholar
• 15 Genecov DG, Schneider AM, Morykwas MJ, Parker D, White WL, Argenta LC. A controlled subatmospheric pressure dressing increases the rate of skin graft donor site reepithelialization. Ann Plast Surg 1998; 40 (03) 219-225
  CrossrefPubMedGoogle Scholar
• 16 Nuutila K, Siltanen A, Peura M. , et al. Gene expression profiling of negative-pressure-treated skin graft donor site wounds. Burns 2013; 39 (04) 687-693
  CrossrefPubMedGoogle Scholar
• 17 Malmsjö M, Huddleston E, Martin R. Biological effects of a disposable, canisterless negative pressure wound therapy system. Eplasty 2014; 14: e15
  PubMedGoogle Scholar
• 18 Pellino G, Sciaudone G, Candilio G, Campitiello F, Selvaggi F, Canonico S. Effects of a new pocket device for negative pressure wound therapy on surgical wounds of patients affected with Crohn's disease: a pilot trial. Surg Innov 2014; 21 (02) 204-212
  CrossrefPubMedGoogle Scholar
• 19 Holt R, Murphy J. PICO™ incision closure in oncoplastic breast surgery: a case series. Br J Hosp Med (Lond) 2015; 76 (04) 217-223
  CrossrefPubMedGoogle Scholar
• 20 Gabriel A, Thimmappa B, Rubano C, Storm-Dickerson T. Evaluation of an ultra-lightweight, single-patient-use negative pressure wound therapy system over dermal regeneration template and skin grafts. Int Wound J 2013; 10 (04) 418-424
  CrossrefPubMedGoogle Scholar
• 21 Isaac AL, Rose J, Armstrong DG. Mechanically powered negative pressure wound therapy as a bolster for skin grafting. Plast Reconstr Surg Glob Open 2014; 2 (02) e103
  PubMedGoogle Scholar
• 22 Demaria M, Stanley BJ, Hauptman JG. , et al. Effects of negative pressure wound therapy on healing of open wounds in dogs. Vet Surg 2011; 40 (06) 658-669
  CrossrefPubMedGoogle Scholar
• 23 Khanbhai M, Fosah R, Oddy MJ, Richards T. Disposable NPWT device to facilitate early patient discharge following complex DFU. J Wound Care 2012; 21 (04) 180-182
  CrossrefPubMedGoogle Scholar