Melanoma spheroid-containing artificial dermis as an alternative approach to in vivo models.

Melanoma spheroid-loaded 3D skin models allow for the study of crucial tumor characteristics and factors at a superior level because the neoplastic cells are integrated into essential human skin components, permitting tumor-skin model communication. Herein, we designed a melanoma-containing artificial dermis by inserting multicellular tumor spheroids from the metastatic phase of WM 1617 melanoma cells into an artificial dermis. We cultured multicellular melanoma spheroids by hanging drop method (250 cells per drop) with a size of 420 µm in diameter after incubation for 14 days. These spheroids were integrated into the dermal equivalents that had been previously preparedwith a type-I collagen matrix and healthy fibroblasts. The melanoma spheroid cells invaded and proliferated in the artificial dermis. Spheroids treated with a 1.0 µmol/L aluminum chloride phthalocyanine nanoemulsion in the absence of light showed high cell viability. In contrast, under irradiation with visible red light (660 nm) at 25 J/cm2, melanoma cells were killed and the healthy tissue was preserved, indicating that photodynamic therapy is effective in such a model. Therefore, the 3D skin melanoma model has potential to promote research in full-thickness skin model targeting optimized preclinical assays.

Implications of dichlorofluorescein photoinstability for detection of UVA-induced oxidative stress in fibroblasts and keratinocyte cells.

Although the dichlorofluorescein (DCF) assay is widely used to detect the production of UVA-induced ROS, the photostability and phototoxicity of the probe after UVA irradiation remains controversial and the experimental conditions often vary across studies, making it difficult to compare results from different studies. This study aimed to evaluate the suitability of the DCF assay for detection of UVA-induced ROS in human cells after UVA irradiation. Human primary fibroblasts (HPF) and HaCaT cells were loaded with 2',7'-dichlorodihydrofluorescein diacetate (DCFDA) (2, 10, and 50 µM) for 10 and 30 min, before and after exposure to UVA radiation (5-50 J cm-2). Fluorescence was recorded immediately or 30 min after irradiation using three different techniques: microplate reading, flow cytometry, and confocal scanning microscopy. Cell viability was assessed by flow cytometry before and after UVA exposure. A UVA-dose-dependent increase in ROS was observed at 5-50 µM DCFDA, and the magnitude of the fluorescent signal was affected by RPMI medium, as well as DCFDA loading concentration and incubation period. However, higher concentrations of DCFDA compromised the viability of both HaCaT and HPF cells after UVA irradiation. The most sensitive and reliable combination for the ROS assay was pre-incubation with 10 µM DCFDA for 30 min in PBS. Reading the fluorescence 30 min after UVA irradiation diminished the emission signal, as did the DCFDA post-incubation. In conclusion, this single-point DCF assay allowed reproducible and sensitive UVA-induced ROS detection in HaCaT and HPF cells without compromising the cell viability or morphology.