Negative modulation of NO for diaphragmatic contractile reduction induced by sepsis and restraint position.
- Author:
Jian XIANG
;
Su-Dong GUAN
;
Xiang-He SONG
;
Hui-Yun WANG
;
Zhen-Yong GU
- Publication Type:Research Support, Non-U.S. Gov't
- MeSH:
Animals;
Asphyxia;
Diaphragm/physiology*;
Muscle Contraction;
Muscle, Skeletal;
Nitric Oxide/metabolism*;
Nitric Oxide Synthase;
Nitric Oxide Synthase Type II;
Rats;
Respiration Disorders;
Restraint, Physical;
Sepsis
- From:
Journal of Forensic Medicine
2014;30(3):161-165
- CountryChina
- Language:English
-
Abstract:
In practice of forensic medicine, potential disease can be associated with fatal asphyxia in restraint position. Research has demonstrated that nitric oxide (NO) and nitric oxide synthase (NOS) are plentifully distributed in skeletal muscle, contributing to the regulation of contractile and relaxation. In the current study, respiratory functions, indices of diaphragmatic biomechanical functions ex vivo, as well as NO levels in serum, the expressions of diaphragmatic inducible NOS (iNOS) mRNA, and the effects of L-NNA on contractility of the diaphragm were observed in sepsis induced by cecal ligation and puncture (CLP) under the condition of restraint position. The results showed that in the CLP12-18h rats, respiratory dysfunctions; indices of diaphragmatic biomechanical functions (Pt, +dT/dt(max), -dT/dt(max), CT, Po, force over the full range of the force-frequency relationship and fatigue resistance) declined progressively; the NO level in serum, and iNOS mRNA expression in the diaphragm increased progressively; force increased significantly at all stimulation frequencies after L-NNA pre-incubation. Restraint position 1 h in CLP12 h rats resulted in severe respiratory dysfunctions after relative stable respiratory functions, almost all the indices of diaphragmatic biomechanical functions declined further, whereas little change took place in NO level in serum and diaphragmatic iNOS mRNA expression; and the effects of L-NNA were lack of statistical significance compared with those of CLP12 h, but differed from CLP18 h group. These results suggest that restraint position and sepsis act together in a synergistic manner to aggravate the great reduction of diaphragmatic contractility via, at least in part, the negative modulation of NO, which may contribute to the pathogenesis of positional asphyxia.
