Blockade of nitric oxide synthase potentiates the suppression of vasodilators by norepinephrine in the hepatic artery

NO netting, health and stress – Studying wellness from a net perspective

On the nature of wellness, stress, netting and the radical gas nitric oxide (NO). The multi-complex role of NO resulted in its discoverers receiving a Nobel award, its presence everywhere and volatility makes it a suitable candidate to be a main signal in an instantaneous communication network. Such network, with the capacity of tight physiological monitoring, enables assets distributions in the body. A model is presented suggesting that an inter-cellular communication network coordinates the various bodily functions. Radical gases like nitric oxide (NO) are signals in this net and its usability affects health and indicates wellness. From this netting point of view, stress is the sense of flow interruption or blockage of the information stream. Such flow interruption affects also physiological functions and can explain the association between stress and many ailments. It is suggested that netting is a prerequisite route of wellness, enabling bodily unconscious managerial decisions. This vital diffusive network is extremely labile and potentially could contain the interplay of consciousness and unconsciousness effected by activities such as yoga or guided imagery. Vast data from studies on NO signals, health and the relaxation/stress processes have already been accumulated. Integration of these data supports this novel look of an NO network as a coordinator. Interactions between stress and health are discussed in net perspective and include basic concepts of some integrative health approaches. Studying the nature of such communication network and of NO may suggest new ways to reduce stress and approach wellness.

Late hemodynamic changes following controlled hemorrhage and volume restitution with blood or Haemaccel in anesthetized portal hypertensive rats

BACKGROUND AND AIM

In portal hypertensive rats, hemorrhage and acute volume restitution with Haemaccel induced increased cardiac output and portal venous inflow. In the present study, the late hemodynamic effects of this procedure were explored.

METHODS

Portal hypertension was induced by portal vein constriction. Blood was withdrawn 11.2 +/- 3.2 days later, at a rate of 0.3 mL/min, for 15 min, followed by 15 min of stabilization. Haemaccel or blood were infused at the same rate and volume used for withdrawal. Hemodynamic measurements were performed after 24 h, using radioactive microspheres. Viscosity was measured with an Ostwald viscometer. Vascular hindrance was calculated as resistance/viscosity ratio.

RESULTS

Blood viscosity of the Haemaccel group (n = 11), was lower than in the blood group (n = 11): 2.7 +/- 0.2 versus 4.0 +/- 0.4 (P < 0.01). Arterial pressure, cardiac output, peripheral resistance, portal pressure, portal venous inflow and splanchnic arteriolar resistance were not significantly different. Splanchnic arteriolar and portocollateral hindrance were higher in the Haemaccel group (11.7 +/- 5.3 and 1.5 +/- 0.6 vs 7.7 +/- 3.0 and 0.9 +/- 0.4 mmHg x min x 100 gram body weight/mL, respectively, P < 0.05).

CONCLUSION

In portal hypertensive rats, vital organs perfusion, 24 h after hemorrhage and isovolemic volume restitution with Haemaccel and blood, was similar. However, in Haemaccel-transfused animals, a reduction in vascular hindrance, indicating vasoconstriction, was observed in the splanchnic organs, which drain into the portal circulation. Vasoconstriction of the portocollateral vascular bed was observed as well. We suggest that slow-rate volume replacement during a portal-hypertensive-related bleeding episode enables hemodynamic adaptation to occur. Thus, undesirable hyperdynamic changes, which may aggravate secondary bleeding, are attenuated.