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Natural product therapy has been gaining therapeutic importance against various diseases,
including cancer. The failure of chemotherapy due to its associated adverse effects promoted adjunct
therapy with natural products. Phytochemicals exert anti-carcinogenic activities through the regulation
of various cell signaling pathways such as cell survival, inflammation, apoptosis, autophagy and metastasis.
The ‘small molecule-chemosensitizing agents’ from plants induce apoptosis in drug-resistant and
host-immune resistant cancer cells in in vitro as well as in vivo models. For example, alkaloids from Nelumbo
nucifera, liensinine, isoliensinine and neferine exert the anticancer activity through enhanced
ROS generation, activation of MAP kinases, followed by induction of autophagy and apoptotic cell
death. Likewise, these alkaloids also exert their cytoprotective action against cerebrovascular
stroke/ischemic stroke, diabetes, and chemotherapy-induced cytotoxicity. Therefore, the present review
elucidates the pharmacological activities of these bisbenzylisoquinoline alkaloids which include the cytoprotective,
anticancer and chemosensitizing abilities against various diseases such as cardiovascular
diseases, neurological diseases and cancer.
An array of chalcones from vanillin/isovanillin and differently substituted acetophenones were synthesized and assessed for their anticancer activity against A549, MCF7 and MIA PaCa-2 cell lines using MTT assay. Some of the chalcones exhibited good anticancer activity with IC 50 values below 10 lM. Compound 5f with IC 50 values 5.4 ± 0.7, 10.45 ± 2.15 and 13.0 ± 1.68 lM on MIA PaCa-2, A549 and MCF7, respectively, was more potent than curcumin and hence was analyzed for changes in cell morphology, inhibition of cell migration, mechanism of cell death and arrest of cell cycle progression on MIA PaCa-2 cells.
Cisplatin chemotherapy to the colorectal cancer cells (CRCs) is accompanied by dose‐limiting adverse effects along with the acquisition of drug resistance implicating low therapeutic outcomes. The present study is aimed to evaluate the chemosensitizing efficacy of neferine/isoliensinine or combinatorial regimen of neferine/isoliensinine with cisplatin against CSCs (cisplatin resistant colon stem cells). CSCs were developed using pulse exposure of cisplatin to parental HCT‐15 cells. Neferine/isoliensinine or combinatorial regimens of Neferine/isoliensinine and cisplatin exhibited a stronger cytotoxic activity against CSCs compared to control. IC50 doses were found to be 6.5 μM for neferine, 12.5 μM for isoliensinine, and 120 μM for cisplatin respectively. Furthermore, the combinatorial regimen of a low dose of cisplatin (40 μM) with 4 μM neferine/8 μM isoliensinine induced cell death in a synergistic manner as described by isobologram. Neferine/isoliensinine could confer extensive intracellular reactive oxygen species generation in CSCs. Neferine/isoliensinine or combinatorial regimens dissipated mitochondrial membrane potential and enhanced intracellular [Ca2+]i, which were measured by spectroflurimetry. Furthermore, these combinatorial regimens induced a significant increase in the sub G0 phase of cell cycle arrest and PI uptake and alleviated the expression of ERCC1 in CSCs. Combinatorial regimens or neferine/isoliensinine treatments downregulated the cell survival protein expression (PI3K/pAkt/mTOR) and activated mitochondria‐mediated apoptosis by upregulating Bax, cytochrome c, caspase‐3, and PARP cleavage expression while downregulating the BCl‐2 expression in CSCs. Our study confirms the chemosensitizing efficacy of neferine/isoliensinine or combinatorial regimens of neferine/isoliensinine with a low dose of cisplatin against CSCs.
Drug repurposing has been gaining increasing interest recently due to the reduction in development cost and reduced development timelines. Here, we report the antibacterial activity of the anticancer drug etoposide investigated in combination with the eggshell-derived hydroxyapatite (EHA). Hydroxyapatite (HA) is a well-known bioactive material with enhanced osteoconductivity and possesses superior drug delivery properties. In the present work, we have synthesized etoposide-loaded EHA by the wet precipitation method. The physicochemical characterization of the samples confirmed the composition and amount of drug encapsulation. Screening for antibacterial activity confirmed the antibacterial effect of etoposide against Staphylococcus aureus. Biofilm formation test on pristine and etoposide-loaded samples showed the inhibition of biofilm formation on etoposide loading, which was further studied by confocal laser scanning microscopy (CLSM) and colony forming units (CFUs). It has been found that etoposide-loaded HA exhibited a sustained release of the drug upto 168 h. Analysis of the inhibition mechanism of etoposide against S. aureus revealed damage to the cell membrane and has been quantified using flow cytometry by the uptake of propidium iodide. Etoposide-loaded eggshell-derived HA (EHA-ET) exhibited excellent bioactivity and cytocompatibility against mouse fibroblast cells (L929) and supressed the growth of osteosarcoma cells (MG-63). Our studies reveal that the EHA-ET has a great potential for treating osteosarcoma and osteomyelitis.
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