Activated Carbon Interphase Effect on Biofilm and Total Bacterial Load

Wounds located on the lower extremity and feet are caused by several conditions, including diabetes and venous insufficiency. These types of wounds may not heal quickly and can become chronic. Chronic wounds are at risk for infection and limb amputation. As such, these wounds are a serious health issue, especially in diabetics and the elderly, and pose a significant public health burden. The healing of such wounds is an ongoing challenge to clinicians, who continue to seek effective management modalities.

The study treatment evaluated in this study is Zorflex® dressing (Chemviron Carbon Cloth Carbon, West Midlands, United Kingdom; a division of Calgon Carbon Corporation, Pittsburgh, PA). According to the Instructions for Use for the product, it is a low-adherent, 100% pure activated carbon cloth dressing that highly conforms to the body contours and maintains contact with the wound surface. It provides an effective antimicrobial barrier for a minimum of 7 days per dressing, protecting the wound from invasive microorganisms, while exhibiting an antimicrobial effect against microorganisms already present in the wound. The dressing may be used either dry or moistened with sterilized water. Zorflex® is indicated as an antimicrobial dressing over dry or discharing, partial and full thickness wounds.

The following unique properties of the activated carbon dressing are believed to aid in wound healing and patient comfort when used for wound management: 1) antimicrobial; 2) odor management; and 3) conductive. The dressing is antimicrobial and manages odor because of its naturally occurring "van der Waal's" electrostatic forces. These forces draw small gas or liquid molecules, including endotoxins and odor molecules, away from the wound into the highly structured micropores of the dressing, where they become trapped. Bacteria cells also are attracted to the dressing, but are too big to enter the micropores. Instead, the microorganisms become trapped on the surface, away from the wound bed. Electrostatic tension builds up in the trapped microorganisms until the tension overcomes the tensile strength of the cell walls, at which time the cell walls of the microorganisms rupture, killing the microorganisms. Any endotoxins released in the process are drawn into the micropores and also become trapped. The conductive nature of the dressing restores the body's natural transepithelial potential across the wound bed, thereby aiding in healing. The positive effects of electrostimulation on wound healing have been previously established.

Several studies, primarily case series, have reported promising preliminary results with the use of Zorflex® as an antimicrobial dressing for wound management. In a case series involving four patients with recalcitrant venous leg ulcers that were prone to recurrent infection, treatment with this particular activated carbon cloth dressing resulted in a reduction in clinical signs of infection, such as exudate and pain levels, and improvement in wound bed appearance after 7 days. A retrospective study evaluating the use of this activated carbon cloth dressing for the management of 18 chronic wounds demonstrated 90.7% wound closure at 5 weeks. Finally, another case series examining the use of Zorflex® in chronic lower extremity and foot wounds demonstrated a reduction in odor control and progression of healing with the use of the dressing.

Studies examining the efficacy of such activated carbon dressings are limited and, therefore, more research, particularly randomized and prospective in design, is needed to better elucidate possible effects of this dressing on preventing infection and promoting healing. The purpose of this multi-center, randomized, prospective study is to evaluate how this activated carbon dressing affects the total bacterial load and biofilm in a wound bed in wounds of the lower extremity and foot. We anticipate that the use of Zorflex® Activated Carbon Cloth dressing will maintain the bacterial burden in the wound bed below the level of critical colonization, with potential secondary benefits of pain reduction, decrease in inflammation, and control of odor. Wound bed healing progression/acceleration also will be assessed.