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This research explores the potential of encapsulating thyme essential oil (TEO) and thymol (TH) into quaternized chitosan nanocapsules to combat SARS-CoV-2. Initially, the bioactive materials, TH and TEO, were extracted from Thymus vulgaris and then structurally and phytochemically characterized by spectral and GC-MS analyses. Meanwhile, O-quaternized ultrasonic-mediated deacetylated chitosan (QUCS) was successfully synthesized and characterized. Lastly, nanobiocomposites (NBCs; NBC1 and NBC2) were fabricated using QUCS as a scaffold to encapsulate either TEO or TH, with the mediation of Tween 80. By encapsulating these bioactive materials, we aim to enhance their efficacy and targeted delivery, bioavailability, stability, and anti-COVID properties. The new NBCs were structurally, morphologically, and physically characterized. Incorporating TEO or TH into QUCS significantly increased ZP values to ±53.1 mV for NBC1 and ±48.2 mV for NBC2, indicating superior colloidal stability. Interestingly, Tween 80-QUCS provided outstanding packing and release performance, with entrapment efficiency (EE) and loading capacity (LC) values of 98.2% and 3.7% for NBC1 and 83.7% and 1.9% for NBC2. The findings of in vitro antiviral studies not only highlight the potential of these nanobiocomposites as potential candidates for anti-COVID therapies but also underscore their selectivity in targeting SARS-CoV-2.
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BACKGROUND: Orlistat (Orli) is an anti-obesity medication that has been approved by the US Food and Drug Administration. It has relatively limited oral bioavailability with promising inhibitory effects on cell proliferation as well as reducing the growth of tumors. AIMS: This investigation was done to evaluate the potential protective effect of Tamoxifen/Orlistat nanocrystals alone or in combination against Solid Ehrlich Carcinoma (SEC) and to clarify the possible underlying influences. MATERIALS AND METHODS: The liquid antisolvent precipitation technique (bottom-up technology) was utilized to manufacture Orlistat Nanocrystals. To explore potential causes for the anti-tumor action, female Swiss Albino mice bearing SEC were randomly assigned into five equal groups (n = 6). Group 1: Tumor control group, group 2: Tam group: tamoxifen (0.01â¯g/kg, IP), group 3: Free-Orli group: orlistat (0.24â¯g/kg, IP), group 4: Nano-Orli: orlistat nanocrystals (0.24â¯g/kg, IP), group 5: Tam-Nano-Orli: Both doses of Tam and Nano-Orli. All treatments were administered for 16 days. KEY FINDINGS: The untreated mice showed development in the tumor volume and weight. As well as histopathology results from these mice revealed many tumor large cells as well as solid sheets of malignant cells. Also, untreated mice showed raised VEGF and TGF-1beta content. Moreover, results of gene expression in the SEC-bearing mice noted upregulation in HIF-1α, MMP-9, Bcl-2, and P27 gene expression and downregulation of TXNIP, BAX, and P53 gene expression. On the other hand, administrated TAM, Free-Orli, Nano-Orli, and a combination of Tam-Nano-Orli distinctly suppressed the tumor effects on estimated parameters with special reference to Tam-Nano-Orli. SIGNIFICANCE: The developed Tamoxifen/Orlistat nanocrystals combination could be considered a promising approach to augment antitumor effects.
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One flavonoid glycoside with demonstrated therapeutic potential for several illnesses, including cancer, is hesperidin. However, because of its limited bioavailability and solubility, it is only marginally absorbed, necessitating a delivery mechanism to reach the intended therapeutic target. Additionally, the cytoskeleton of crustaceans yields chitosan, a naturally occurring biopolymer with mucoadhesive properties that has been used to improve the absorption of advantageous chemical substances like flavonoids. Chitosan/hesperidin nanoparticles (Hes-Nanoparticles) were made using the ion gelation technique. The synthesis of Hes-Nanoparticles was confirmed by several characterization methods, including the swelling test, zeta potential, particle size, FTIR, XRD, TEM, and SEM. DPPH and ABTS were used to demonstrate radical scavenging activity in antioxidant assays of chitosan, hesperidin, and the synthesized Hes-Nanoparticles. In addition, by a viability assay against MDA-MB-231, the anticancer efficacies of chitosan, hesperidin, and the synthesized Hes-Nanoparticles were assessed. Furthermore, annexin-V/PI double staining and the cycle of cell analysis were determined by flow cytometry. The results displayed that Hes-Nanoparticles have higher antioxidant activity than chitosan and hesperidin alone. Also, it has been demonstrated that Hes-Nanoparticles are more effective in early cell cycle arrest, suppressing the viability of cancer cells, and increasing cell apoptosis than chitosan and hesperidin alone. In conclusion, Hes-Nanoparticles demonstrated more antioxidant and antitumor activities than chitosan and hesperidin alone. Moreover, it has been established that Hes-Nanoparticles, in a highly soluble form, increase activity in contrast to the poorly soluble form of hesperidin alone.
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Background: Cardiotoxicity is one of the limiting side effects of the commonly used anticancer agent cyclophosphamide (Cyclo). Materials and methods: The possible protective effects of telmisartan and nanoformulated Spirulina platensis (Sp) methanolic extract against Cyclo-induced cardiotoxicity were examined in this study. Experimental groups of rats were randomly divided into nine groups as control vehicle, control polymer, telmisartan (TEL, 10 mg/kg), free Sp extract (300 mg/kg), nano Sp extract (100 mg/kg), Cyclo (200 mg/kg), TEL + Cyclo, free Sp + Cyclo, and nano Sp + Cyclo. The groups with Cyclo combinations were treated in the same manner as their corresponding ones without Cyclo, with a single dose of Cyclo on day 18. Results: The results indicate that Cyclo causes significant cardiotoxicity, manifesting in the form of notable increases of 155.49%, 105.74%, 451.76%, and 826.07% in the serum levels of glutamic oxaloacetic transaminase (SGOT), lactate dehydrogenase (LDH), creatine kinase MB (CK-MB), and cardiac troponin I (cTnI) enzyme activities, respectively, as compared to the control. In addition, the cardiac glutathione (GSH) content and activity of glutathione peroxidase-1 (GPX-1) enzyme decreased by 65.94% and 73.85%, respectively. Treatment with nano Sp extract showed the most prominent restorations of the altered biochemical, histopathological, and immunohistochemical features as compared with those by TEL and free Sp; moreover, reductions of 30.64% and 43.02% in the p-AKT content as well as 60.43% and 75.30% of the endothelial nitric oxide synthase (eNOS) immunoreactivity were detected in the TEL and free Sp treatment groups, respectively. Interestingly, nano Sp boosted the autophagy signal via activation of beclin-1 (36.42% and 153.4%), activation of LC3II (69.13% and 195%), downregulation of p62 expressions (39.68% and 62.45%), and increased gene expressions of paraoxonase-1 (PON-1) (90.3% and 225.9%) compared to the TEL and free Sp treatment groups, respectively. Conclusion: The findings suggest the protective efficiency of telmisartan and nano Sp extract against cardiotoxicity via activations of the antioxidant, antiapoptotic, and autophagy signaling pathways.
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BACKGROUND: Orlistat (ORL) is an effective irreversible inhibitor of the lipase enzyme, and it possesses anticancer effects and limited aqueous solubility. This study was designed to improve the aqueous solubility, oral absorption, and tissue distribution of ORL via the formulation of nanocrystals (NCs). METHODS: ORL-NC was prepared using the liquid antisolvent precipitation method (bottom-up technology), and it demonstrated significantly improved solubility compared with that of the blank crystals (ORL-BCs) and untreated ORL powder. The biodistribution and relative bioavailability of ORL-NC were investigated via the radiolabeling technique using Technetium-99m (99mTc). Female Swiss albino mice were used to examine the antitumor activity of ORL-NC against solid Ehrlich carcinoma (SEC)-induced hepatic damage in mice. RESULTS: The prepared NCs improved ORL's solubility, bioavailability, and tissue distribution, with evidence of 258.70% relative bioavailability. In the in vivo study, the ORL-NC treatment caused a reduction in all tested liver functions (total and direct bilirubin, AST, ALT, and ALP) and improved modifications in liver sections that were marked using hematoxylin and eosin staining (H&E) and immunohistochemical staining (Ki-67 and ER-α) compared with untreated SEC mice. CONCLUSIONS: The developed ORL-NC could be considered a promising formulation approach to enhance the oral absorption tissue distribution of ORL and suppress the liver damage caused by SEC.