Cerium nitrate enhances anti-bacterial effects and imparts anti-inflammatory properties to silver dressings in a rat scald burn model.

Current commercially available silver-based wound dressings such as silver-nylon have been used as antimicrobial barriers for burn and trauma care in combat conditions for over 10 years. However, these dressings do not stabilize the eschar or reduce its toxicity. Cerium nitrate (CN) solutions have been established clinically to stabilize the eschar by decreasing release of inflammatory mediators from burned tissue thereby allowing delayed excision and grafting. In this report, we tested the extent to which CN imparts CN benefits to silver dressings for temporizing treatments of burn wounds and enhancing anti-bacterial activity. Using a rat full-thickness scald burn model, we showed that CN enhanced the anti-bacterial effects of the tested silver-based dressings (Acticoat™, Mepilex™, and Silverlon®), while also imparting anti-inflammatory properties to these dressings. Compared to the use of silver dressings alone, CN significantly decreased the levels of IL-1ß and GRO/KC, and exhibited downward trending levels of IL-1α, MIP-1α, and bacterial bioburden within the wound. Based on our findings, we conclude that CN has the ability to expand and enhance the function of several silver dressings. We propose the use of CN in combination with silver dressings to stabilize burn wounds thereby allowing postponement of excision and grafting, most notably in scenarios where the standard of care is not feasible such as in combat situations, resource limited regions, and new emergent health care challenges as seen during the COVID-19 pandemic in which COVID-positive severe burn patients are not able to undergo surgery during an active outbreak.

Cerium Nitrate Treatment Provides Eschar Stabilization through Reduction in Bioburden, DAMPs, and Inflammatory Cytokines in a Rat Scald Burn Model.

In this study, we used a clinically relevant rat scald burn model to determine the treatment effects of cerium nitrate (CN) for stabilizing burn eschars through reduction of damage-associated molecular patterns (DAMPs), inflammatory cytokines, and bioburden. Forty-two male Sprague-Dawley rats were anesthetized before undergoing a scald burn at 99°C for 6 seconds to create a 10% full-thickness burn. The test groups included sham burn, burn with water bathing, and burn with CN bathing. End point parameters included circulating DAMPs, proinflammatory cytokines, tissue myeloperoxidase activity, and quantification of resident flora in burn skin. The high mobility group protein box 1 was found to be elevated in burn animals at postoperative days (POD) 1 and 7. CN significantly alleviated the increase (P < .05 at POD 1 and P < .01 at POD 7). CN also lessened the heightened levels of hyaluronan in burn animals (P < .05 at POD 7). Additionally, CN significantly reduced the burn-induced increases in interleukin-1ß, growth-regulated oncogene/keratinocyte chemoattractant, and macrophage inflammatory protein-1α in burn wounds. The anti-inflammatory effect of CN was also demonstrated in its ability to mitigate the upregulated circulatory xanthine oxidase/dehydrogenase and increased tissue neutrophil infiltration in burn animals. Last, CN suppressed postburn proliferation of resident skin microbes, resulting in a significant 2-log reduction by POD 7. In conclusion, these results suggest that CN attenuates the burn-induced DAMPs, tissue inflammatory responses, and regrowth of resident skin flora, all of which collectively could improve the quality of burn eschar when applied at the point of injury in prolonged field care situations.

Exacerbated and prolonged inflammation impairs wound healing and increases scarring.

Altered inflammation in the early stage has long been assumed to affect subsequent steps of the repair process that could influence proper wound healing and remodeling. However, the lack of explicit experimental data makes the connection between dysregulated wound inflammation and poor wound healing elusive. To bridge this gap, we used the established rabbit ear hypertrophic scar model for studying the causal effect of dysregulated inflammation. We induced an exacerbated and prolonged inflammatory state in these wounds with the combination of trauma-related stimulators of pathogen-associated molecular patterns from heat-killed Pseudomonas aeruginosa and damage-associated molecular patterns from a dermal homogenate. In stimulated wounds, a heightened and lengthened inflammation was observed based on quantitative measurements of IL-6 expression, tissue polymorphonuclear leukocytes infiltration, and tissue myeloperoxidase activity. Along with the high level of inflammation, wound healing parameters (epithelial gap and others) at postoperative day 7 and 16 were significantly altered in stimulated wounds compared to unstimulated controls. By postoperative day 35, scar elevation of stimulated wounds was higher than that of control wounds (scar elevation index: 1.90 vs. 1.39, p < 0.01). Moreover, treatment of these inflamed wounds with Indomethacin (at concentrations of 0.01, 0.1, and 0.4%) reduced scar elevation but with adverse effects of delayed wound closure and increased cartilage hypertrophy. In summary, successful establishment of this inflamed wound model provides a platform to understand these detrimental aspects of unchecked inflammation and to further test agents that can modulate local inflammation to improve wound outcomes.

In vitro characterization of scaffold-free three-dimensional mesenchymal stem cell aggregates.

Mesenchymal stem cells (MSCs) are capable of self-renewal and differentiation along multiple cell lineages and have potential applications in a wide range of therapies. These cells are commonly cultured as monolayers on tissue culture plastic but possibly lose their cell-specific properties with time in vitro. There is growing interest in culturing adherent cells via three-dimensional (3D) techniques in order to recapitulate 3D in vivo conditions. We describe a novel method for generating and culturing rabbit MSCs as scaffold-free 3D cell aggregates by using micropatterned wells via a forced aggregation technique. The viability and proliferative capability of MSC aggregates were assessed via Live/Dead staining and 5-ethynyl-2'-deoxyuridine (EdU) incorporation. Enzyme-linked immunosorbent assay and antibody-based multiplex protein assays were used to quantify released growth factors and chemokines. The gene expression profile of MSCs as 3D aggregates relative to MSCs grown as monolayers was evaluated via quantitative real-time polymerase chain reaction. The rabbit MSCs were able to form compact cell aggregates and remained viable in 3D culture for up to 7 days. We also demonstrated enhanced gene and protein expression related to angiogenesis and wound healing in MSCs cultured under 3D conditions. In vitro tube formation and scratch assay revealed superior neovessel formation and greater cell recovery and migration in response to 3D conditioned media after wounding. Our data further suggest that adipose-derived stem cell aggregates have greater potential than dermal fibroblasts or bone-marrow-derived MSCs in accelerating wound healing and reducing scarring.