Varying Negative Pressure Wound Therapy Acute Effects on Human Split-Thickness Autografts.

Over 6.5 million people in the United States suffer from traumatic, burn, acute, and chronic wounds yearly. When reconstruction is required, split and full-thickness autografts are a first line of treatment intervention. Negative pressure wound therapy (NPWT) is gaining traction as an adjunct modality to improve graft survival, yet the specifics on what settings to apply topically over the graft is unsubstantiated and associated with morbidities. This study was performed in an effort to understand initial changes in wound and graft healing with a long-term goal of surface pressure optimization. Excess skin from elective procedures from six human subjects was trimmed to 0.012 inch in order represent a split-thickness autografts. These grafts were treated continuously with either -75 mm Hg (n = 4), -125 mm Hg (n = 4), or no pressure (n = 4) for 3 hours. Six skin grafts were treated with no sponge or pressure control (n = 6). RNAseq was performed on all treatment groups and compared with no pressure control. Significant gene expression changes with a subset focusing on inflammatory, cellular/extracellular matrix proliferation and angiogenic mediators and having greater than 2-fold were confirmed with immunohistochemistry staining. There are 95 significant gene transcription differences among all treatment groups. NPWT leads to significantly increased gene expression of FGFR1, ET-1, and 22 Keratin proteins. Between -75 and -125 mm Hg groups, there are 19 significant gene changes. Proinflammatory genes S100A8 and Tenacin C (TNC) demonstrate an 8.8- and 9.1-fold change, respectively, and is upregulated in -125 mm Hg group and downregulated in -75 mm Hg group. Fibrinogen genes fibrinogen gamma chain and fibrinogen alpha chain had respective log2-fold changes of -7.9 and -7.4 change between treatment groups and were downregulated in -125 mm Hg group and upregulated in -75 mm Hg group. There are varying effects of surface pressures on human split-thickness autografts during the imbibition time period. NPWT may improve cellular migration, proliferation, and angiogenesis over controls. Human skin grafts respond differently to -125 and -75 mm Hg within 3 hours of NPWT treatment. The results suggest -75 mm Hg leads to less inflammation and increased fibrinogen production compared with the -125 mm Hg group, at least initially. Reducing "time to heal" with NPWT is critical to successful outcomes and quality of life within young patients who often experience pain/discomfort when treated at the current standard pump settings. The results from this study and continued investigation may quickly translate to the clinical setting by finding the ideal pressure setting utilized in an effort to reduce NPWT length of treatment, improve patient comfort, satisfaction, and psychosocial well-being.

Evaluation of Bio-VOC Sampler for Analysis of Volatile Organic Compounds in Exhaled Breath.

Monitoring volatile organic compounds (VOCs) from exhaled breath has been used to determine exposures of humans to chemicals. Prior to analysis of VOCs, breath samples are often collected with canisters or bags and concentrated. The Bio-VOC breath sampler, a commercial sampling device, has been recently introduced to the market with growing use. The main advantage for this sampler is to collect the last portion of exhaled breath, which is more likely to represent the air deep in the lungs. However, information about the Bio-VOC sampler is somewhat limited. Therefore, we have thoroughly evaluated the sampler here. We determined the volume of the breath air collected in the sampler was approximately 88 mL. When sampling was repeated multiple times, with the succeeding exhalations applied to a single sorbent tube, we observed linear relationships between the normalized peak intensity and the number of repeated collections with the sampler in many of the breath VOCs detected. No moisture effect was observed on the Tenax sorbent tubes used. However, due to the limitation in the collection volume, the use of the Bio-VOC sampler is recommended only for detection of VOCs present at high concentrations unless repeated collections of breath samples on the sampler are conducted.