Ultrastructural membrane dynamics of mouse and human cortical synapses.

Live human brain tissues provide unique opportunities for understanding the physiology and pathophysiology of synaptic transmission. Investigations have been limited to anatomy, electrophysiology, and protein localization-while crucial parameters such as synaptic vesicle dynamics were not visualized. Here we utilize zap-and-freeze time-resolved electron microscopy to overcome this hurdle.

In-home use study evaluating user satisfaction with newly developed MoliCare Premium Pants.

Background: High-quality absorbent products with effective performance characteristics help maintain user dignity and normalise incontinence.

Aim: The study evaluated the most important performance characteristics of newly developed MoliCare Premium Pants.

Methods: Fifty-two adults with incontinence in Germany were surveyed for their views and levels of satisfaction with various performance features of the tested absorbent incontinence product via a computer-assisted personal interview.

Brain-to-blood transport of fluorescein in vitro.

Investigating blood-brain barrier (BBB) dysfunction has become a pre-clinical and clinical research focus as it accompanies many neurological disorders. Nevertheless, knowledge of how diagnostic BBB tracers cross the endothelium from blood-to-brain or vice versa often remains incomplete. In particular, brain-to-blood transport (efflux) may reduce tracer extravasation of intravascularly (i.

KATP channel mutation disrupts hippocampal network activity and nocturnal gamma shifts.

ATP-sensitive potassium (KATP) channels couple cell metabolism to cellular electrical activity. Humans affected by severe activating mutations in KATP channels suffer from developmental delay, epilepsy and neonatal diabetes (DEND syndrome). While the aetiology of diabetes in DEND syndrome is well understood, the pathophysiology of the neurological symptoms remains unclear.

Human iPSC-Derived Neurons with Reliable Synapses and Large Presynaptic Action Potentials.

Understanding the function of the human brain requires determining basic properties of synaptic transmission in human neurons. One of the most fundamental parameters controlling neurotransmitter release is the presynaptic action potential, but its amplitude and duration remain controversial. Presynaptic action potentials have so far been measured with high temporal resolution only in a limited number of vertebrate but not in human neurons.