Abstract
Biodegradable materials, including the widely used poly (lactic-co-glycolic acid) (PLGA) nanoparticles contained in slow-release drug formulations, scaffolds and implants, are ubiquitous in modern biomedicine and are considered inert or capable of being metabolized through intermediates such as lactate. However, in the presence of metabolic stress, such as in obesity, the resulting degradation products may play a detrimental role, which is still not well understood. We evaluated the effect of intravenously-administered PLGA nanoparticles on the gut-liver axis under conditions of caloric excess in C57BL/6 mice. Our results show that PLGA nanoparticles accumulate and cause gut acidification in the cecum, accompanied by significant changes in the microbiome, with a marked decrease of Firmicutes and Bacteroidetes. This was associated with transcriptomic reprogramming in the liver, with a downregulation of mitochondrial function, and an increase in key enzymatic, inflammation and cell activation pathways. No changes were observed in systemic inflammation. Metagenome analysis coupled with publicly available microarray data suggested a mechanism of impaired PLGA degradation and intestinal acidification confirming an important enterohepatic axis of metabolite-microbiome interaction resulting in maintenance of metabolic homeostasis. Thus, our results have important implications for the investigation of PLGA use in metabolically-compromised clinical and experimental settings.
Highlights
Biodegradable materials, including the widely used poly (PLGA) nanoparticles contained in slow-release drug formulations, scaffolds and implants, are ubiquitous in modern biomedicine and are considered inert or capable of being metabolized through intermediates such as lactate
It has been previously shown that IV injection of PLGA NPs accumulate in the liver, spleen, lungs, heart and kidneys[13]; studies have shown that orally ingested PLGA NPs are found in the intestine[14,15]
These results led us to hypothesize that PLGA NPs travelled to the gastrointestinal tract (GIT) via enterohepatic circulation; for this, we performed an acute experiment of bile duct ligation in C57BL/6 mice followed by PLGA-Eu injection (Fig. 1B)
Summary
Biodegradable materials, including the widely used poly (lactic-co-glycolic acid) (PLGA) nanoparticles contained in slow-release drug formulations, scaffolds and implants, are ubiquitous in modern biomedicine and are considered inert or capable of being metabolized through intermediates such as lactate. The use of PLGA nanoparticles is of great interest in the design of new drug delivery systems and medical d evices[2]; there is still knowledge lacking regarding some of their potential effects It is not completely understood how injected nanoparticle carriers, including PLGA, are sequestered by immune cells, which have enhanced affinity towards particles, and whether their further disposal has an impact on the reticuloendothelial or digestive. Most work has focused on orally ingested NPs, showing that intake can induce dysbiosis by inhibiting or killing specific microbial members; it has been previously shown that intravenous (IV) drugs can interact with gut microbiota, such as certain IV chemotherapeutic agents[9] This interaction can lead to severe side effects, warranting the need to further investigate the impact of IV drug delivery systems on the GIT and improve their use in treatment. Considering the prevalence (and rise) of obesity and the metabolic syndrome[12], it seems appropriate to broaden the scope and understand the potential impact of these conditions towards IV-administered PLGA
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