Gaso-transmitters: expanding the kinetic universe of cell signaling

Impaired Neurovascular Coupling and Increased Functional Connectivity in the Frontal Cortex Predict Age-Related Cognitive Dysfunction

Impaired cerebrovascular function contributes to the genesis of age-related cognitive decline. In this study, the hypothesis is tested that impairments in neurovascular coupling (NVC) responses and brain network function predict cognitive dysfunction in older adults. Cerebromicrovascular and working memory function of healthy young (n = 21, 33.2±7.0 years) and aged (n = 30, 75.9±6.9 years) participants are assessed. To determine NVC responses and functional connectivity (FC) during a working memory (n-back) paradigm, oxy- and deoxyhemoglobin concentration changes from the frontal cortex using functional near-infrared spectroscopy are recorded. NVC responses are significantly impaired during the 2-back task in aged participants, while the frontal networks are characterized by higher local and global connection strength, and dynamic FC (p < 0.05). Both impaired NVC and increased FC correlate with age-related decline in accuracy during the 2-back task. These findings suggest that task-related brain states in older adults require stronger functional connections to compensate for the attenuated NVC responses associated with working memory load.

LIMPID: a versatile method for visualization of brain vascular networks

Visualization of cerebrovascular networks is crucial for understanding the pathogenesis of many neurological diseases. Recently developed optical clearing techniques offer opportunities in deep tissue imaging, and have been successfully applied in many research studies. The development of nanotechnology enables the labeling of brain vessels with functionalized micro/nanoparticles embedded with fluorescent dyes. We herein report an efficient method, named LIMPID (Labeled and Interlinked Micro/nanoparticles for Imaging and Delipidation), specific for the precise fluorescence imaging of vascular networks in clearing-treated tissues. This robust vessel labeling technique replaces conventional fluorescence dyes with functionalized polymer micro/nanoparticles that are able to cross-link with polyacrylamide to form dense hydrogels in vessels. LIMPID shows high-robustness during the clearing process without sacrificing fluorescence signals and clearing performance. LIMPID enables three dimension (3D) visualization of elaborate vascular networks in mouse brains and is compatible with other fluorescence-labeling techniques. We have successfully applied this method to acquire cortical vasculature images simultaneously with the neurons or microglia, as well as to evaluate vascular damage in a mouse model of stroke. The LIMPID method provides a novel tool for the precise analysis of vascular dysfunction and vascular diseases.