Diversity Oriented Routes to Thiopeptide Antibiotics: A Solution to the "Thiazole Problem".

The Goossen decarboxylative coupling reaction enables the union of thiazole-2-carboxylic acids with a 2-pyridyl triflate, leading to the formation of pyridine-thiazole clusters of the kind found in thiopeptide antibiotics. The method avoids problematic or technically challenging reaction sequences involving 2-thiazolyl organometallics, facilitating the investigation of the structure-activity relationship of the thiopeptides.

Genetic engineering of transfusable platelets with mRNA-lipid nanoparticles is compatible with blood banking practices.

Platelets contribute to a variety of physiological processes, including inflammation, sepsis, and cancer. However, because of their primary role in hemostasis, platelet transfusions are largely restricted to managing thrombocytopenia and bleeding. One way to expand the utility of platelet transfusions would be to genetically engineer donor platelets with new or enhanced functions.

Claisen Self-Condensation of Lactones in the Synthesis of Ionizable Lipids.

The Claisen self-condensation of lactones can be carried out safely and efficiently under Mukaiyama conditions, in the presence of TiCl and triethylamine. The primary Claisen products can be elaborated to various derivatives or converted directly into dihydroxyketones. Such compounds are valuable educts for the synthesis of ionizable lipids for the delivery of nucleic acid therapeutics and can now be accessed through a concise, economical, scalable route that avoids more technically challenging reaction sequences.

Quantitative Visualization of Lipid Nanoparticle Fusion as a Function of Formulation and Process Parameters.

Lipid nanoparticles (LNPs) have proven to be promising delivery vehicles for RNA-based vaccines and therapeutics, particularly in LNP formulations containing ionizable cationic lipids that undergo protonation/deprotonation in response to buffer pH changes. These nanoparticles are typically formulated using a rapid mixing technique at low pH, followed by a return to physiological pH that triggers LNP-LNP fusion. A detailed understanding of these dynamic processes is crucial to optimize the overall performance and efficiency of LNPs.