Epithelial-mesenchymal transition in chemoradiation-induced lung damage: Mechanisms and potential treatment approaches.

Pulmonary injury is one of the key restricting factors for the therapy of malignancies with chemotherapy or following radiotherapy for chest cancers. The lung is a sensitive organ to some severely toxic antitumor drugs, consisting of bleomycin and alkylating agents. Furthermore, treatment with radiotherapy may drive acute and late adverse impacts on the lung. The major consequences of radiotherapy and chemotherapy in the lung are pneumonitis and fibrosis. Pneumonitis may arise some months to a few years behind cancer therapy. However, fibrosis is a long-term effect that appears years after chemo/or radiotherapy. Several mechanisms such as oxidative stress and severe immune reactions are implicated in the progression of pulmonary fibrosis. Epithelial-mesenchymal transition (EMT) is offered as a pivotal mechanism for lung fibrosis behind chemotherapy and radiotherapy. It seems that pulmonary fibrosis is the main consequence of EMT after chemo/radiotherapy. Several biological processes, consisting of the liberation of pro-inflammatory and pro-fibrosis molecules, oxidative stress, upregulation of nuclear factor of κB and Akt, epigenetic changes, and some others, may participate in EMT and pulmonary fibrosis behind cancer therapy. In this review, we aim to discuss how chemotherapy or radiotherapy may promote EMT and lung fibrosis. Furthermore, we review potential targets and effective agents to suppress EMT and lung fibrosis after cancer therapy.

Engineered urolithin A-laden functional polymer-lipid hybrid nanoparticles prevent cisplatin-induced proximal tubular injury in vitro.

Functional polymer-lipid hybrid nanoparticles (H-NPs) are a promising class of nanocarriers that combine the benefits of polymer and lipid nanoparticles, offering biocompatibility, structural stability, high loading capacity, and, most importantly, superior surface functionalization. Here, we report the synthesis and design of highly functional H-NPs with specificity toward the transferrin receptor (TfR), using a small molecule ligand, gambogic acid (GA). A fluorescence study revealed the molecular orientation of H-NPs, where the lipid-dense core is surrounded by a polymer exterior, functionalized with GA. Urolithin A, an immunomodulator and anti-inflammatory agent, served as a model drug-like compound to prepare H-NPs via traditional emulsion-based techniques, where H-NPs led to smaller particles (132 nm) and superior entrapment efficiencies (70 % at 10 % drug loading) compared to GA-conjugated polymeric nanoparticles (P-NPs) (157 nm and 52 % entrapment efficiency) and solid lipid nanoparticles (L-NPs) (186 nm and 29 % entrapment efficiency). H-NPs showed superior intracellular accumulation compared to individual NPs using human small intestinal epithelial (FHs 74) cells. The in vitro efficacy was demonstrated by flow cytometry analysis, in which UA-laden H-NPs showed excellent anti-inflammatory properties in cisplatin-induced injury in healthy human proximal tubular cell (HK2) model by decreasing the TLR4, NF-κß, and IL-ß expression. This preliminary work highlights the potential of H-NPs as a novel functional polymer-lipid drug delivery system, establishing the foundation for future research on its therapeutic potential in addressing chemotherapy-induced acute kidney injury in cancer patients.