The GALA peptide (WEAALAEALAEALAEHLAEALAEALEALAA) was originally designed to induce the destabilization of endosomal membranes based on its ability to undergo a pH-dependent conformational change from a random coil to an α-helix. We recently found that liposomes modified with GALA peptide (GALA-LPs) extensively accumulate in lung endothelial cells (ECs) after intravenous injection. However, the uptake mechanism of GALA-LPs and their ability to reach alveolar epithelium was unclear. We report herein that GALA-LPs are internalized into ECs via a clathrin-mediated pathway. Surprisingly, GALA-LPs had the ability to pass lung ECs and reach other cells through transcytosis. GALA-LPs were taken up by>70% of lung ECs, while they also accumulated in ~30% of type I alveolar epithelium (ATI). GALA-modified gold nanoparticles were detected in ECs, in the basement membrane and in other cells such as ATI, type II alveolar epithelium (ATII) and alveolar macrophages. Consistent with this result, a significant gene knockdown was achieved in lung epithelium cells using GALA-LPs encapsulating anti-podoplanin siRNA. This indicates that GALA-LPs can be used as a carrier for delivering macromolecules to parenchymal as well as to endothelial cells in the lung. Although caveolae are commonly linked to the transendothelial transport of proteins and antibodies, our data indicate that clathrinmediated endocytosis might also participate in the transcytosis process.

The presented review with 74 references covers most of the methods described for the analysis of Rivaroxaban (RXB); the first and selective oral direct inhibitor of activated factor X in its pure forms, in different pharmaceutical dosage forms and in biological fluids. The review covers the period from 2005 till now.

Nanomedicine promises to play an important role in next generation therapy, including Nucleic acid/Gene therapy. To accomplish this, innovative nanotechnologies will be needed to support nanomedicine by controlling not only the biodistribution but also the intracellular trafficking of macromolecules such as RNA/DNA. A multifunctional envelope-type nano device (MEND) was developed to meet this requirement. We herein provide an update regarding the functions of the MEND system focusing on the introduction of different functional biomaterials that enhance efficiency. The octaarginine (R8) peptide enhances cellular uptake and controls intracellular trafficking to induce synergism in transgene expression. The R8 was also used for developing a MITOPorter system for mitochondrial targeting. The function of the MITO-Porter system was extended by developing a mitochondrial reporter gene for mitochondrial gene therapy. For efficient in vivo gene delivery, new pH-sensitive lipids have been introduced to achieve controlled biodistribution and to enhance endosomal escape. For example, the CL4H6 lipid exerts a more efficient in vivo gene silencing than that of ONPATTROTM, a preparation that has been approved by the US Food and Drug Administration. We further summarize new technologies that have been successfully applied to cancer immunotherapy leading to the introduction of a new strategy based on the concept of the Cancer-Immunity Cycle.

Candida albicans, as the main causative fungus of vaginal candidiasis, is currently a global issue of concern due to its high prevalence, biofilm formation and emergence of resistance. Ketoconazole (KTZ), an antifungal drug, which has poor water-solubility and penetration capacity, is ineffective against deep-seated Candida infection. Considering these issues, this work aimed to develop a novel multifunctional carrier for KTZ via encapsulation of KTZ/β-cyclodextrin (β-CD) co-ground mixture into chitosan/gellan gum gel-flakes (threadlike and polygonal structures). Analytical studies revealed existence of electrostatic-derived complexes between negatively charged gellan gum and positively charged chitosan. Gel-flakes were then loaded in in situ gel of pluronic F-127 (PF-127). Based on gelation temperature (Tgel), viscosity and release studies; selected formulation was further evaluated, showing significant in vitro anti-candida activity. Despite reduced dosage regimen (50 mg/daily/three days), KTZ flakes in situ gel was as effective as Gynoconazol vaginal cream® (80 mg terconazole/daily/three days) in im- proving patient complaints and Candida eradication. Multifunctionality of KTZ carrier was based on efficient spreading and coating of the vagina due to free-flowing properties during application, flakes entanglement within folded vaginal epithelia, sustained release and increased penetration capacity of KTZ to reach deep-seated infections. In conclusion, flakes in situ gel could be considered as a highly promising KTZ delivery option for treatment of vaginal candidiasis.

The COVID-19 pandemic caused by the newly emerged severe acute respiratory syndrome coronavirus- 2 (SARS-CoV-2) puts the world in an unprecedented crisis, leaving behind huge human losses and deep socioeconomic damages. Due to the lack of specific treatment against SARS-CoV-2, effective vaccines and antiviral agents are urgently needed to properly restrain the COVID-19 pandemic. Repositioned drugs such as remdesivir have revealed a promising clinical efficacy against COVID-19. Interestingly, nanomedicine as a promising therapeutic approach could effectively help win the battle between coronaviruses (CoVs) and host cells. This review discusses the potential therapeutic approaches, in addition to the contribution of nanomedicine against CoVs in the fields of vaccination, diagnosis and therapy.

The COVID-19 pandemic caused by the newly emerged severe acute respiratory syndrome coronavirus- 2 (SARS-CoV-2) puts the world in an unprecedented crisis, leaving behind huge human losses and deep socioeconomic damages. Due to the lack of specific treatment against SARS-CoV-2, effective vaccines and antiviral agents are urgently needed to properly restrain the COVID-19 pandemic. Repositioned drugs such as remdesivir have revealed a promising clinical efficacy against COVID-19. Interestingly, nanomedicine as a promising therapeutic approach could effectively help win the battle between coronaviruses (CoVs) and host cells. This review discusses the potential therapeutic approaches, in addition to the contribution of nanomedicine against CoVs in the fields of vaccination, diagnosis and therapy.

The COVID-19 pandemic caused by the newly emerged severe acute respiratory syndrome coronavirus- 2 (SARS-CoV-2) puts the world in an unprecedented crisis, leaving behind huge human losses and deep socioeconomic damages. Due to the lack of specific treatment against SARS-CoV-2, effective vaccines and antiviral agents are urgently needed to properly restrain the COVID-19 pandemic. Repositioned drugs such as remdesivir have revealed a promising clinical efficacy against COVID-19. Interestingly, nanomedicine as a promising therapeutic approach could effectively help win the battle between coronaviruses (CoVs) and host cells. This review discusses the potential therapeutic approaches, in addition to the contribution of nanomedicine against CoVs in the fields of vaccination, diagnosis and therapy.

Aim: Hepatotoxicity is the most serious adverse effect of rifampicin (RIF). We aimed to investigate the potential hepatoprotective effect of mannose-functionalized poly(lactic-co-glycolic acid)(PLGA)/RIF nanoparticles (NPs) in rats as a possible promising approach to minimize RIF-induced hepatotoxicity. Ma- terials & methods: Mannose-functionalized PLGA/RIF NPs were fabricated and characterized in vitro, then the hepatoprotective effect of optimized NPs was studied on rat and cell culture models. Results: Follow- ing intraperitoneal administration of RIF NPs into rats, highly significant differences in levels of serum transaminases and oxidative stress markers, associated with significant differences in expression of Bax and Bcl-2 genes between NP- and free RIF-treated groups, revealing the hepatoprotective potential of NPs. Conclusion: RIF NPs may represent a promising therapeutic approach for tuberculosis via reducing dose frequency and consequently, RIF-induced hepatotoxicity.

Aim: Hepatotoxicity is the most serious adverse effect of rifampicin (RIF). We aimed to investigate the potential hepatoprotective effect of mannose-functionalized poly(lactic-co-glycolic acid)(PLGA)/RIF nanoparticles (NPs) in rats as a possible promising approach to minimize RIF-induced hepatotoxicity. Ma- terials & methods: Mannose-functionalized PLGA/RIF NPs were fabricated and characterized in vitro, then the hepatoprotective effect of optimized NPs was studied on rat and cell culture models. Results: Follow- ing intraperitoneal administration of RIF NPs into rats, highly significant differences in levels of serum transaminases and oxidative stress markers, associated with significant differences in expression of Bax and Bcl-2 genes between NP- and free RIF-treated groups, revealing the hepatoprotective potential of NPs. Conclusion: RIF NPs may represent a promising therapeutic approach for tuberculosis via reducing dose frequency and consequently, RIF-induced hepatotoxicity.

Aim: Hepatotoxicity is the most serious adverse effect of rifampicin (RIF). We aimed to investigate the potential hepatoprotective effect of mannose-functionalized poly(lactic-co-glycolic acid)(PLGA)/RIF nanoparticles (NPs) in rats as a possible promising approach to minimize RIF-induced hepatotoxicity. Ma- terials & methods: Mannose-functionalized PLGA/RIF NPs were fabricated and characterized in vitro, then the hepatoprotective effect of optimized NPs was studied on rat and cell culture models. Results: Follow- ing intraperitoneal administration of RIF NPs into rats, highly significant differences in levels of serum transaminases and oxidative stress markers, associated with significant differences in expression of Bax and Bcl-2 genes between NP- and free RIF-treated groups, revealing the hepatoprotective potential of NPs. Conclusion: RIF NPs may represent a promising therapeutic approach for tuberculosis via reducing dose frequency and consequently, RIF-induced hepatotoxicity.