A Preliminary Report Regarding the Morphological Changes of Nano-Enabled Pharmaceutical Formulation on Human Lung Carcinoma Monolayer and 3D Bronchial Microtissue.
Catalin Prodan-BarbulescuClaudia-Geanina WatzElena-Alina MoacăAlexandra-Corina FaurCristina-Adriana DeheleanIonut Flaviu FaurLaura Octavia GrigoriţăAnca Laura MaghiariPaul TuţacCiprian DuţăSorin BolintineanuLaura Andreea Bolintineanu GhenciuPublished in: Medicina (Kaunas, Lithuania) (2024)
Background and Objectives : Nowadays, the development of enabled pharmaceutical nanoparticles of solid lipid type is continuously growing, because they have the potential to be used for targeted drug release leading to an increased effect of chemotherapy, being used in lung cancer nano-diagnosis and nano-therapy. The current study reports the preliminary results obtained regarding the biological effect of a new nano-enabled pharmaceutical formulation in terms of its cytotoxic and biosafety profile. Materials and Methods : The pharmaceutical formulations consist of solid lipid nanoparticles (SLN) obtained via the emulsification-diffusion method by loading green iron oxide nanoparticles (green-IONPs) with a pentacyclic triterpene (oleanolic acid-OA). Further, a complex biological assessment was performed, employing three-dimensional (3D) bronchial microtissues (EpiAirway TM ) to determine the biosafety profile of the SLN samples. The cytotoxic potential of the samples was evaluated on human lung carcinoma, using an in vitro model (A549 human lung carcinoma monolayer). Results : The data revealed that the A549 cell line was strongly affected after treatment with SLN samples, especially those that contained OA-loaded green-IONPs obtained with Ocimum basilicum extract (under 30% viability rates). The biosafety profile investigation of the 3D normal in vitro bronchial model showed that all the SLN samples negatively affected the viability of the bronchial microtissues (below 50%). As regards the morphological changes, all the samples induce major changes such as loss of the surface epithelium integrity, loss of epithelial junctions, loss of cilia, hyperkeratosis, and cell death caused by apoptosis. Conclusions : In summary, the culprit for the negative impact on viability and morphology of 3D normal bronchial microtissues could be the too-high dose (500 µg/mL) of the SLN sample used. Nevertheless, further adjustments in the SLN synthesis process and another complex in vitro evaluation will be considered for future research.
Keyphrases
- drug delivery
- cell death
- sentinel lymph node
- drug release
- high dose
- oxidative stress
- cancer therapy
- cell cycle arrest
- fatty acid
- iron oxide nanoparticles
- risk assessment
- radiation therapy
- knee osteoarthritis
- endoplasmic reticulum stress
- machine learning
- deep learning
- data analysis
- artificial intelligence
- adverse drug
- signaling pathway