Serum-derived protein coronas affect nanoparticle interactions with brain cells.

Neuronanomedicine is an emerging field bridging the gap between neuromedicine and novel nanotherapeutics. Despite promise, clinical translation of neuronanomedicine remains elusive, possibly due to a dearth of information regarding the effect of the protein corona on these neuronanomedicines. The protein corona, a layer of proteins adsorbed to nanoparticles following exposure to biological fluids, ultimately determines the fate of nanoparticles in biological systems, dictating nanoparticle-cell interactions. To date, few studies have investigated the effect of the protein corona on interactions with brain-derived cells, an important consideration for the development of neuronanomedicines. Here, two polymeric nanoparticles, poly(lactic-co-glycolic acid) (PLGA) and PLGA-polyethylene glycol (PLGA-PEG), were used to obtain serum-derived protein coronas. Protein corona characterization and liquid chromatography mass spectrometry analysis revealed distinct differences in biophysical properties and protein composition. PLGA protein coronas contained high abundance of globins (60%) and apolipoproteins (21%), while PLGA-PEG protein coronas contained fewer globins (42%) and high abundance of protease inhibitors (28%). Corona coated PLGA nanoparticles were readily internalized into microglia and neuronal cells, but not into astrocytes. Internalization of nanoparticles was associated with pro-inflammatory cytokine release and decreased neuronal cell viability, however, viability was rescued in cells treated with corona coated nanoparticles. These results showcase the importance of the protein corona in mediating nanoparticle-cell interactions.

Non-viral gene delivery utilizing RALA modulates sFlt-1 secretion, important for preeclampsia.

Background: Overexpression of sFlt-1 or modulation of FKBPL, key antiangiogenic proteins, are important in the pathogenesis of preeclampsia. Methods: A newly developed nonviral gene-delivery system, RALA, capable of overexpressing sFlt-1 (e15a isoform) was delivered in vivo in transgenic haploinsufficient (Fkbpl+/-) mice. RALA was also used in vitro to deliver human Flt1 (hFlt1) in trophoblast cells. Results: Serum stable and nontoxic RALA/DNA-based nanoparticles induced an increase in sFlt-1 protein levels in the blood and total protein in the urine; the effect was more pronounced in Fkbpl+/- mice. In vitro, RALA-hFlt nanoparticles significantly reduced secretion of sFlt-1 in trophoblast cells. Conclusion: The RALA-based genetic nanodelivery system can be safely and effectively applied to emulate preeclampsia-like features or reduce sFlt-1 levels in vitro.

Lay abstract In this study, the investigators utilized a safe and effective approach to modulate an important circulating protein in pregnancy, sFlt-1, associated with the pregnancy complication, preeclampsia. Preeclampsia is a complex and multifactorial disease and a leading cause of death in pregnancy with no current effective treatment strategies. This is likely due to a lack of reliable preclinical models that replicate human disease. The authors demonstrate the feasibility of a new preeclampsia-like model based on the dysfunction of two key vascular proteins, sFlt-1 and FKBPL (an important protein involved in the development of new blood vessels), that could be utilized in the future for testing and development of new treatments targeting these important mechanisms in preeclampsia.

Different approaches in the treatment of obstructive pulmonary diseases.

Advances in drug formulation, inhalation device design and disease management are generating new opportunities for patients suffering from obstructive pulmonary diseases. This article provides a comprehensive review of the different promising pulmonary drug delivery technologies in the treatment of obstructive pulmonary diseases, particularly with regard to the treatment of asthma and chronic pulmonary diseases (COPD), which are increasing day by day due to increasing environmental pollution and its harmful and toxic contaminants. In the recent years, a better knowledge has been gained regarding the mechanism of action of glucocorticoids and how they suppress the chronic inflammation. New etiology has been brought into light regarding the inactivity of glucocorticoids in some patients having asthma and COPDs even though the inflammatory genes are triggered by similar molecules in both the diseases. This new knowledge has given a new platform to improve glucocorticoids and their resistance also how other combination therapy can be used for these diseases. It has also led to the quest for improving and developing other alternatives such as anti-leukotriene agents, muscarinic inhibitors, combination therapy, as well as biologic immune-modulators in the treatment of the different pulmonary diseases. Several new combinations of glucocorticoids are available in the global market for the use in pulmonary diseases especially asthma although their availability fluctuates between continents. There has been several studies done regarding the variation of effectiveness of the different inhaled glucocorticoids and hence it is important to take into consideration the different delivery systems and the methods which are used to treat the patients.