Copper Ions Ameliorated Thermal Burn-Induced Damage in ex vivo Human Skin Organ Culture.

INTRODUCTION: The zone of stasis is formed around the coagulation zone following skin burning and is characterized by its unique potential for salvation. The cells in this zone may die or survive depending on the severity of the burn and therefore are target for the local treatments of burns. Their low survival rate is consistent with decreased tissue perfusion, hypotension, infection, and/or edema, resulting in a significant increase in the wound size following burning. Copper is an essential trace mineral needed for the normal function of almost all body tissues, including the skin. OBJECTIVE: The aim of the work was to study the effect copper ions have on skin burn pathophysiology. METHODS: Skin obtained from healthy patients undergoing abdominoplasty surgery was cut into 8 × 8 mm squares, and round 0.8-mm diameter burn wounds were inflicted on the skin explants. The burned and control intact skin samples were cultured up to 27 days after wounding. Immediately following injury and then again every 48 h, saline only or containing 0.02 or 1 µM copper ions was added onto the skin explant burn wounds. RESULTS: We found that exposing the wounded sites immediately after burn infliction to 0.02 or 1 µM copper ions reduced the deterioration of the zone of stasis and the increase in wound size. The presence of the copper ions prevented the dramatic increase of pro-inflammatory cytokines (interleukin (IL)-6 and IL-8) and transforming growth factor beta-1 that followed skin burning. We also detected re-epithelialization of the skin tissue and a greater amount of collagen fibers upon copper treatment. CONCLUSION: The deterioration of the zone of stasis and the increase in wound size following burning may be prevented or reduced by using copper ion-based therapeutic interventions.

Increased pro-collagen 1, elastin, and TGF-ß1 expression by copper ions in an ex-vivo human skin model.

BACKGROUND: Clinical studies demonstrated that continued exposure to copper oxide-embedded textiles, such as pillowcases, significantly reduces depth of facial wrinkles and skin sagging and enhances skin elasticity. OBJECTIVE: Study the mechanisms by which the exposure to copper ions improve the well-being of the skin. METHODS: Human skin explants, cultured ex-vivo, were exposed topically to saline alone or saline containing 0.02 or 1 µmol/L copper ions. The skin explants viability, histology and secretion of elastin, pro-collagen 1, and TGF-ß1 to the culture medium were determined at various time intervals. RESULTS: Exposure to saline containing 0.02 or 1 µmol/L copper ions did not affect the viability or morphological profile of the explants as compared to control explants treated with saline only. Notably, exposure of the skin grafts to 0.02 or to 1 µmol/L of copper ions resulted in ~100% and ~20% increases in elastin and pro-collagen 1 concentrations, respectively, in the culture supernatants already after 1 day of incubation, which remained statistically significantly elevated also after 6 days on incubation, as compared to the control explants. In addition, ~2- and ~4-fold increases in TGF-ß1 levels in the culture supernatants of explants exposed to the copper ions were detected after 4 and 6 days of culture, as compared to the explants exposed to saline alone. CONCLUSION: This study substantiated the anti-aging effect that copper ions have on the skin and gave insights into the mechanisms by which exposure of the skin to copper ions improves the skin well-being.