Baxdrostat: A Novel Aldosterone Synthase Inhibitor for Treatment Resistant Hypertension.

Hypertension is a global epidemic, affecting around 30.4% of the population and being the leading preventable risk factor for death. Despite the availability of numerous antihypertensive agents, less than 20% of individuals have their blood pressure controlled. Resistant hypertension poses a challenge, but a new class of medication, aldosterone synthase inhibitors (ASI), shows promise. ASI reduces aldosterone production by inhibiting aldosterone synthase. This review article focuses on Baxdrostat, a highly potent ASI currently in phase 3 trials. It discusses the drug's biochemical pathway, efficacy trials in animals and humans, and its potential in uncontrolled hypertension, chronic kidney disease, and primary aldosteronism.

Exploring the functional composition of the human microbiome using a hand-curated microbial trait database.

BACKGROUND: Even when microbial communities vary wildly in their taxonomic composition, their functional composition is often surprisingly stable. This suggests that a functional perspective could provide much deeper insight into the principles governing microbiome assembly. Much work to date analyzing the functional composition of microbial communities, however, relies heavily on inference from genomic features. Unfortunately, output from these methods can be hard to interpret and often suffers from relatively high error rates. RESULTS: We built and analyzed a domain-specific microbial trait database from known microbe-trait pairs recorded in the literature to better understand the functional composition of the human microbiome. Using a combination of phylogentically conscious machine learning tools and a network science approach, we were able to link particular traits to areas of the human body, discover traits that determine the range of body areas a microbe can inhabit, and uncover drivers of metabolic breadth. CONCLUSIONS: Domain-specific trait databases are an effective compromise between noisy methods to infer complex traits from genomic data and exhaustive, expensive attempts at database curation from the literature that do not focus on any one subset of taxa. They provide an accurate account of microbial traits and, by limiting the number of taxa considered, are feasible to build within a reasonable time-frame. We present a database specific for the human microbiome, in the hopes that this will prove useful for research into the functional composition of human-associated microbial communities.