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Background and aims: Bacteria in wounds can lead to stagnation of wound healing as well as to local or even systemic wound infections up to potentially lethal sepsis. Consequently, the bacterial load should be reduced as part of wound treatment. Therefore, the efficacy of simple mechanical wound debridement should be investigated in terms of reducing bacterial colonisation. Patients and methods: Patients with acute or chronic wounds were assessed for bacterial colonisation with a fluorescence camera before and after mechanical wound debridement with sterile cotton pads. If bacterial colonisation persisted, a second, targeted wound debridement was performed. Results: A total of 151 patients, 68 (45.0%) men and 83 (55.0%) women were included in this study. The male mean age was 71.0 years and the female 65.1 years. By establishing a new analysis method for the image files, we could document that the bacterial colonised areas were distributed 21.9% on the wound surfaces, 60.5% on the wound edges (up to 0.5 cm) and 17.6% on the wound surroundings (up to 1.5 cm). One mechanical debridement achieved a significant reduction of bacterial colonised areas by an average of 29.6% in the wounds, 18.9% in the wound edges and 11.8% in the wound surroundings and was increased by performing it a second time. Conclusions: It has been shown that even a simple mechanical debridement with cotton pads can significantly reduce bacterial colonisation without relevant side effects. In particular, the wound edges were the areas that were often most contaminated with bacteria and should be included in the debridement with special attention. Since bacteria remain in wounds after mechanical debridement, it cannot replace antimicrobial therapy strategies, but offer a complementary strategy to improve wound care. Thus, it could be shown that simple mechanical debridement is effective in reducing bacterial load and should be integrated into a therapeutic approach to wounds whenever appropriate.
The combination of hyaluronic acid and iodine (Hyodine) has sparked interest in wound care and could have valuable applications in treating burn injuries. We aimed to provide valuable insight into the potential advantages, limitations, and implications of using Hyodine in burn wound management. We studied 25 male rats to assess the clinical outcomes and wound-healing effects of Hyodine. Each rat received a deep second-degree burn wound on their back using metal stamps. Subsequently, the rats were then randomly split into two groups. The first group was treated with a layer of Hyodine gel, while the second group received Vaseline. The burn sites were photographed on days 1, 7, 14, and 21 using a digital camera. After excision of the burn wounds, histopathology slides were stained and evaluated in terms of the degree of epithelialization, angiogenesis, inflammatory cells' infiltration, and collagen amount and arrangement. Despite a non-significant difference regarding the extent of burn wound area between intervention and control groups in the first day of experiment, the rats that were treated with Vaseline showed a significant decrease compared to those who received Hyodine in the second and third weeks (p = 0.02). On the other hand, epithelialization, pathology score, and collagen synthesis were significantly different between days 7, 14, and 21 of each group. However, collagen arrangement and neovascularization were only significantly different between days 7, 14, and 21 in Hyodine group (p = 0.02 and p = 0.03, respectively). The Hyodine gel may offer beneficial outcomes in patients with a burn wound. Based on our findings, despite a non-significant difference in the extent of burn wound area, using Hyodine revealed a significant improvement in different histopathological variables including neovascularization, and collagen arrangement.
Platelet-rich fibrin (PRF), which is the rich source of growth factors, has been used as an efficient scaffold in tissue engineering and wound healing. In this study, tannic acid as a green cross-linker with different concentrations (0.5%, 1%, 5% and 10%) was used to improve the properties of PRF. The cross-linked gel scaffolds were evaluated by analyses such as scanning electron microscopy, Fourier transform infrared spectroscopy, swelling and degradation, mechanical strength, cell toxicity, cell adhesion and antibacterial test. The results showed that the scaffold structure changes by increasing cross-linker concentration. The swelling rate decreased from 49% to 5% for the samples without the cross-linker and with tannic acid (10%), respectively. The degradation percentage for the cross-linked samples was 8%, which showed a lower degradation rate than the non-cross-linked samples (63%). The mechanical strength of the scaffold with the cross-linker increased up to three times (Young's modulus for the non-cross linked and the cross-linked samples: 0.01 and 0.6 MPa, respectively). Cytotoxicity was not observed up to 10% cross-linker concentration. The cells proliferated well on the cross-linked scaffolds and also showed a good antibacterial effect. In general, tannic acid can improve the physical and mechanical properties of PRF without negatively affecting its biological properties.
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