High-resolution blood flow imaging confirms the presence of large, long-living synchronous clusters in renal microcirculation and reveals how vasoactive drugs affect synchronization properties.

Excitatory and inhibitory cortical neurons drive parallel vasodilatory pathways, while vasoconstriction is mediated exclusively by inhibition acting via Neuropeptide Y binding to Y1 receptors.

The causal link between capillary amyloid‑β accumulation in the brain and cerebrovascular dysfunction, previously established in the Tg‑SwDI mouse model, is to be mitigated and remains to be fully uncovered.

Genetic mouse models identify a critical mechanism of myogenic vasoconstriction and reveal the in vivo function of myogenic autoregulation in protecting from organ overperfusion and in maintaining vascular resistance.

The main proteins of clathrin-mediated endocytosis bind and unbind rapidly, continuously turning over about five times during the formation of an endocytic vesicle in yeast.

The existence of a slow-moving zone around the transcription site may unify conflicting models of co-transcriptional versus post-transcriptional mRNA splicing.

Cutting-edge super-resolution microscopy methods reveal the architecture and dynamics of the sealing zone formed by human osteoclasts and composed of coordinated groups of podosomal cores encircled by adhesion complexes.

A one-photon three-dimensional light sculpture technique has been developed and demonstrated for high spatio-temporal resolution photostimulation and imaging of dozens of neurons in the intact mouse brain in vivo.