Tunable Mechanically Interlocked Semi-Crystalline Networks.

High-performance polymers based on dynamic chemistry have been widely explored for multi-field advanced applications. However, noncovalent sacrificial bond-mediated energy dissipation mechanism causes a trade-off between mechanical toughness and resilience. Herein, we achieved the synchronous boost of seemingly conflicting material properties including mechanical robustness, toughness and elasticity via the incorporation of mechanical chemistry into traditional semi-crystalline networks.

[Study of neurological mechanism of lidocaine's suppression to tinnitus via microdialysis].

Objective: To elucidate the neurological mechanism of lidocaine's suppression to tinnitus.

Methods: Thirty-four Wistar rats weighing 300-350 grams were randomly divided into IC group (n = 17) and AC group (n = 17), according to microdialysis region. Each group was randomly subdivided into saline treatment group (n = 4), salicylate treatment group (n = 6), and salicylate + lidocaine treatment group (n = 7).

Hyperoxia caused by microdialysis perfusion decreased striatal monoamines: involvement of oxidative stress.

Due to complex influence, such as utilization and permeability of arterial vessels to oxygen, there is a considerable difference of oxygen tension between extracellular fluid and perfusate usually used in microdialysis (30-60 Torr versus 145 Torr). Dialysate dopamine and monoamine metabolites-3,4-dihydroxyphenylacetic acid, homovanillic acid and 5-hydroxyindoleacetic acid were measured under different kinds of oxygen tension solutions (145, 72, 48 Torr). In the acute and anesthetized group, dopamine, 3,4-dihydroxyphenylacetic acid, 5-hydroxyindoleacetic acid and homovanillic acid increased 72, 93, 86 and 65%, respectively when changing the perfusate from 145 Torr to near physiological 48 Torr, while in chronic and conscious group, carried out 72 h after surgery, these compounds showed obscure increases (only homovanillic acid produced a significant change of 14%).