Neural control and innate self-tuning of the hair cell's active process.

We propose a model for the feedback control processes that underlie the robustness and high sensitivity of mechanosensory hair cells. Our model encompasses self-tuning active processes intrinsic to these cells, which drive the amplification of mechanical stimuli by consuming metabolic energy, and a neural input process that protects these cells from damage caused by powerful stimuli. We explore the effects of these two feedback mechanisms on mechanical self-oscillations of the sense cells and their response to external forcing.

Descriptive parameters of the erythrocyte aggregation phenomenon using a laser transmission optical chip.

The study of red blood cell (RBC) aggregation is of great interest because of its implications for human health. Altered RBC aggregation can lead to microcirculatory problems as in vascular pathologies, such as hypertension and diabetes, due to a decrease in the erythrocyte surface electric charge and an increase in the ligands present in plasma. The process of erythrocyte aggregation was studied in stasis situation (free shear stresses), using an optical chip based on the laser transmission technique.

In vitro alterations of erythrocyte aggregation by action of Trichinella spiralis newborn larvae.

Possible changes in the erythrocyte membrane, by in vitro interaction with newborn larvae of T. spiralis (NL), were evaluated analyzing the alterations in erythrocyte aggregation by digital image analysis and laser transmission in a new optical chip aggregometer. NL were obtained from CBi mice infected with T.