Physical Model for Investigating Intracranial Pressure with Clinical Pressure Sensors and Diagnostic Ultrasound: Preliminary Results.

Introduction: Intracranial pressure (ICP) is a commonly collected neurocritical parameter, but accurate signal modelling remains challenging. The goal of this project was to mimic clinical ICP waveforms using a physical model.

Materials And Methods: A physical head model was developed.

Polycomb regulation is coupled to cell cycle transition in pluripotent stem cells.

When self-renewing pluripotent cells receive a differentiation signal, ongoing cell duplication needs to be coordinated with entry into a differentiation program. Accordingly, transcriptional activation of lineage specifier genes and cell differentiation is confined to the G phase of the cell cycle by unknown mechanisms. We found that Polycomb repressive complex 2 (PRC2) subunits are differentially recruited to lineage specifier gene promoters across cell cycle in mouse embryonic stem cells (mESCs).

The Chemogenetic Receptor Ligand Clozapine N-Oxide Induces Neuroreceptor Occupancy and Reduces Striatal Glutamate Levels.

Chemogenetic studies with the ligand clozapine N-oxide (CNO) are predicated upon the assumption that CNO is devoid of actions at natural neuroreceptors. However, recent evidence shows that CNO may be converted back to clozapine (CLZ) , which could yield plasma concentrations that may be sufficient to occupy inter alia dopamine D and serotonin 5HT receptors in living brain. To test this phenomenon, we measured striatal dopamine D receptor occupancy with [F]fallypride PET and serotonin 5HT occupancy using [F]MH.

Ensemble theory for slightly deformable granular matter.

Given a granular system of slightly deformable particles, it is possible to obtain different static and jammed packings subjected to the same macroscopic constraints. These microstates can be compared in a mathematical space defined by the components of the force-moment tensor (i.e.

Impact of the timestep in some molecular dynamics simulations on compression of granular systems.

We conduct two-dimensional molecular dynamics simulations to study the statistical distribution of the force-moment (defined as stress multiplied by volume) of static granular packings under external isotropic compression. To that end, we generate packings by compressing initially ordered lattices using irregular, randomly generated, walls. Velocity-Verlet algorithm and linear spring-dashpot interactions are employed.