Diabetes and Dyslipidemia Screening in Pediatric Practice.

The incidence of diabetes and hyperlipidemia are increasing at rapid rates in children. These conditions are associated with increased risk of macrovascular and microvascular complications causing major morbidity and mortality later in life. Early diagnosis and treatment can reduce the lifelong risk of complications from these diseases, exemplifying the importance of screening in the pediatric population. The following article presents a summary of the current guidelines for diabetes and hyperlipidemia screening in pediatric patients.

High-throughput and high-content bioassay enables tuning of polyester nanoparticles for cellular uptake, endosomal escape, and systemic in vivo delivery of mRNA.

Nanoparticle-based mRNA therapeutics hold great promise, but cellular internalization and endosomal escape remain key barriers for cytosolic delivery. We developed a dual nanoparticle uptake and endosomal disruption assay using high-throughput and high-content image-based screening. Using a genetically encoded Galectin 8 fluorescent fusion protein sensor, endosomal disruption could be detected via sensor clustering on damaged endosomal membranes. Simultaneously, nucleic acid endocytosis was quantified using fluorescently tagged mRNA. We used an array of biodegradable poly(beta-amino ester)s as well as Lipofectamine and PEI to demonstrate that this assay has higher predictive capacity for mRNA delivery compared to conventional polymer and nanoparticle physiochemical characteristics. Top nanoparticle formulations enabled safe and efficacious mRNA expression in multiple tissues following intravenous injection, demonstrating that the in vitro screening method is also predictive of in vivo performance. Efficacious nonviral systemic delivery of mRNA with biodegradable particles opens up new avenues for genetic medicine and human health.

Efficiency of Cytosolic Delivery with Poly(ß-amino ester) Nanoparticles is Dependent on the Effective pKa of the Polymer.

The mechanism by which cationic polymers containing titratable amines mediate effective endosomal escape and cytosolic delivery of nucleic acids is not well understood despite the decades of research devoted to these materials. Here, we utilize multiple assays investigating the endosomal escape step associated with plasmid delivery by polyethylenimine (PEI) and poly(ß-amino esters) (PBAEs) to improve the understanding of how these cationic polymers enable gene delivery. To probe the role of these materials in facilitating endosomal escape, we utilized vesicle membrane leakage and extracellular pH modulation assays to demonstrate the influence of polymer buffering capacity and effective pKa on the delivery of the plasmid DNA. Our results demonstrate that transfection with PBAEs is highly sensitive to the effective pKa of the overall polymer, which has broad implications for transfection. In more acidic environments, PBAE-mediated transfection was inhibited, while PEI was relatively unaffected. In neutral to basic environments, PBAEs have high buffering capacities that led to dramatically improved transfection efficacy. The cellular uptake of polymeric nanoparticles overall was unchanged as a function of pH, indicating that microenvironmental acidity was important for downstream intracellular delivery efficiency. Overall, this study motivates the use of polymer chemical characteristics, such as effective pKa values, to more efficiently evaluate new polymeric materials for enhanced intracellular delivery characteristics.