1.
[Myocardial dysfunction in sepsis].
Andresen, M, Regueira, T
Revista medica de Chile. 2010;(7):888-96
Abstract
Myocardial dysfunction appears in 25% of patients with severe sepsis and in 50% of patients with septic shock, even in the presence of hyper dynamic states. It is characterized by a reduction in left ventricle ejection fraction, that reverts at the seventh to tenth day of evolution. Right ventricular dysfunction and diastolic left ventricular dysfunction can also appear. There is no consensus if an increase in end diastolic volume is part of the syndrome. High troponin or brain natriuretic peptide levels are associated with myocardial dysfunction and a higher mortality. The pathogenesis of myocardial dysfunction is related to micro and macro circulatory changes, inflammatory response, oxidative stress, intracellular calcium management disturbances, metabolic changes, autonomic dysfunction, activation of apoptosis, mitochondrial abnormalities and a derangement in catecholaminergic stimulation. Since there is no specific treatment for myocardial dysfunction, its management requires an adequate multi systemic support to maintain perfusion pressures and systemic flows sufficient for the regional and global demands.
2.
Signaling mechanisms of altered cellular responses in trauma, burn, and sepsis: role of Ca2+.
Sayeed, MM
Archives of surgery (Chicago, Ill. : 1960). 2000;(12):1432-42
Abstract
Alterations in cellular responses in various organ systems contribute to trauma-, burn-, and sepsis-related multiple organ dysfunction syndrome. Such alterations in muscle contractile, hepatic metabolic, and neutrophil and T-cell inflammatory-immune responses have been shown to result from cell-signaling modulations and/or impairments in the respective cell types. Altered Ca(2+) signaling would seem to play an important role in the myocardial and vascular smooth muscle contractile dysfunction in the injury conditions; Ca(2+)-linked signaling derangement also plays a crucial role in sepsis-induced altered skeletal muscle protein catabolism and resistance to insulin-mediated glucose use. The injury-related increased hepatic gluconeogenesis and acute-phase protein response could also be caused by a pathophysiologic up-regulation of hepatocyte Ca(2+)-signal generation. The increased oxidant production by neutrophil, a potentially detrimental inflammatory response in early stages after burn or septic injuries, seems to result from an up-regulation of both the Ca(2+)-dependent as well as Ca(2+)-independent signaling pathways. The injury conditions would seem to cause an inappropriate up-regulation of Ca(2+)-signal generation in the skeletal myocyte, hepatocyte, and neutrophil, while they lead to a down-regulation of Ca(2+) signaling in T cells. The crucial signaling derangement that causes T-cell proliferation suppression seems to be a decrease in the activation of protein tyrosine kinases, which subsequently down-regulates Ca(2+) signaling. The delineation of cell-signaling derangements in trauma, burn, or sepsis conditions can lead to development of therapeutic interventions against the disturbed cellular responses in the vital organ systems.