RESUMO
Cerebral malaria (CM), a severe neurological pathology caused by Plasmodium falciparum infection, poses a significant global health threat and has a high mortality rate. Conventional therapeutics cannot cross the blood-brain barrier (BBB) efficiently. Therefore, finding effective treatments remains challenging. The novelty of the treatment proposed in this study lies in the feasibility of intranasal (IN) delivery of the nanostructured lipid carrier system (NLC) combining microRNA (miRNA) and artemether (ARM) to enhance bioavailability and brain targeting. The rational use of NLCs and RNA-targeted therapeutics could revolutionize the treatment strategies for CM management. This study can potentially address the challenges in treating CM, allowing drugs to pass through the BBB. The NLC formulation was developed by a hot-melt homogenization process utilizing 3% (w/w) precirol and 1.5% (w/v) labrasol, resulting in particles with a size of 94.39 nm. This indicates an effective delivery to the brain via IN administration. The results further suggest the effective intracellular delivery of encapsulated miRNAs in the NLCs. Investigations with an experimental cerebral malaria mouse model showed a reduction in parasitaemia, preservation of BBB integrity, and reduced cerebral haemorrhages with the ARM+ miRNA-NLC treatment. Additionally, molecular discoveries revealed that nicotinamide adenine dinucleotide phosphate oxidase 2 (NOX2) and Interleukin-6 (IL-6) levels were reduced in the treated groups in comparison to the CM group. These results support the use of nanocarriers for IN administration, offering a viable method for mitigating CM through the increased bioavailability of therapeutics. Our findings have far-reaching implications for future research and personalized therapy.
RESUMO
Several epigenome studies reported the ability of genes to modulate the lipogenic and glucogenic pathways during insulin signaling as well as the other pathways involved in cardiometabolic diseases. Epigenetic plasticity and oxidative stress are interrelated in the pathophysiology of insulin resistance (IR) and cardiometabolic disease conditions. This review aims to ascertain the previous research evidence pertaining to the role of the epigenome and the variations of histone and non-histone proteins during cardiometabolic disease conditions and insulin signaling to develop effective disease-based epigenetic biomarkers and epigenetics-based chromatic therapy. Several public databases, including PubMed, National Library of Medicine, Medline, and google scholar, were searched for the peer-reviewed and published reports. This study delineates the consistent body of evidence regarding the epigenetic alterations of DNA/histone complexes pertinent to oxidative stress, insulin signaling, metabolic cardiomyopathy, and endothelial dysfunction in patients with cardiometabolic diseases. It has been described that both DNA methylation and post-translational histone alterations across visceral and subcutaneous adipose tissue could facilitate gene transcription to modulate inflammation, lipogenesis, and adipogenesis as the complex network of chromatin-modifying enzymatic proteins involved in the defensive insulin signaling across vasculature in patients with cardiometabolic diseases. Resveratrol, vorinostat, trichostatin, and apabetalone are reported to have significant implications as epigenetic modulators. Based on the epigenetic alterations, a wide range of protein/gene markers, such as interleukin-4 (IL-4) and interferon-γ (IFNγ) genes, may be considered as biomarkers in these patients due to their ability to the polarization of immune cells involved in tissue inflammation and atherosclerosis. Hence, it is crucial to unravel the cell-specific epigenetic information to develop individual risk assessment strategies for chromatin-modifying therapies in patients with cardiometabolic diseases.