Mechanotransduction and the homeostatic significance of maintaining blood viscosity in hypotension, hypertension and haemorrhage.

The increase of plasma and blood viscosity is usually associated with pathological conditions; however, elevation of both parameters often results in increased perfusion and the lowering of peripheral vascular resistance. In extreme haemodilution, blood viscosity is too low and insufficient to maintain functional capillary density, a problem that in experimental studies is shown to be corrected by increasing plasma viscosity up to 2.2 cP.

Blood viscosity maintains microvascular conditions during normovolemic anemia independent of blood oxygen-carrying capacity.

Responses to exchange transfusion with red blood cells (RBCs) containing methemoglobin (MetRBC) were studied in an acute isovolemic hemodiluted hamster window chamber model to determine whether oxygen content participates in the regulation of systemic and microvascular conditions during extreme hemodilution. Two isovolemic hemodilution steps were performed with 6% dextran 70 kDa (Dex70) until systemic hematocrit (Hct) was reduced to 18% (Level 2). A third-step hemodilution reduced the functional Hct to 75% of baseline by using either a plasma expander (Dex70) or blood adjusted to 18% Hct with all MetRBCs.

Increased cardiac output and microvascular blood flow during mild hemoconcentration in hamster window model.

The effect of small hematocrit (Hct) increases on cardiac index (cardiac output/body wt) and oxygen release to the microcirculation was investigated in the awake hamster window chamber model by means of exchange transfusions of homologous packed red blood cells. Increasing Hct between 8 and 13% from baseline increased cardiac index by 5-31% from baseline (P < 0.05) and significantly lowered systemic blood pressure (P < 0.

Oxygen release from arterioles with normal flow and no-flow conditions.

The rate of oxygen release from arterioles ( approximately 55 microm diameter) was measured in the hamster window chamber model during flow and no-flow conditions. Flow was stopped by microvascular transcutaneous occlusion using a glass pipette held by a manipulator. The reduction of the intra-arteriolar oxygen tension (Po2) was measured by the phosphorescence quenching of preinfused Pd-porphyrin, 100 microm downstream from the occlusion.

Microvascular effects following treatment with polyethylene glycol-albumin in lipopolysaccharide-induced endotoxemia.

Objective: To determine whether resuscitation with polyethylene glycol conjugated bovine serum albumin (2.5% weight/volume) infused at 16 mL/kg/hr (PEG-BSA-16) or at 24 mL/kg/hr (PEG-BSA-24) for 1 hr improves microcirculatory conditions in endotoxemia compared with dextran 70 (6% weight/volume) infused at 24 mL/kg/hr (Dex).

Design: Prospective study.

Nitric oxide regulation of microvascular oxygen exchange during hypoxia and hyperoxia.

The objective of this work was to test the hypothesis that the limitation of nitric oxide (NO) availability accentuates microvascular reactivity to oxygen. The awake hamster chamber window model was rendered hypoxic and hyperoxic by ventilation with 10 and 100% oxygen. Systemic and microvascular parameters were determined in the two conditions and compared with normoxia in a group receiving the NO scavenger nitronyl nitroxide and a control group receiving only the vehicle (saline).

The vascular wall as a regulator of tissue oxygenation.

Purpose Of Review: The development of the phosphorescence quenching oxygen measurement technique has allowed for a simultaneous measurement of intra and perivascular partial pressure oxygen along arteriolar vessels in vivo. Mapping the microvascular distribution and oxygen gradients across the vascular walls using this high-resolution technique reveals the existence of large radial gradients between the vasculature and the tissue, with concomitant longitudinal oxygen loss. Mass balance analysis along vessel segments indicates that the vascular wall has a high rate of oxygen consumption.

Role of endothelial nitric oxide in microvascular oxygen delivery and consumption.

Nitric oxide (NO) is an important signaling molecule modulating diverse processes such as vasodilation, neurotransmission, long-term potentiation, and immune responses. The endothelium contributes a significant fraction of NO from endothelial NO synthase (eNOS). The objective of this work was to analyze the role of eNOS in the modulation of oxygen supply to the tissues and in adaptation to maintain oxygenation uncompromised.

Effect of oxygen consumption by measuring method on PO2 transients associated with the passage of erythrocytes in capillaries of rat mesentery.

Mathematical models have predicted the existence of Po(2) gradients between erythrocytes in capillaries in the usual case where plasma contributes substantial resistance to oxygen diffusion. According to theoretical predictions, these gradients could be detected as rapid Po(2) fluctuations (erythrocyte-associated transients, EATs) along the capillary. However, verification of a model and correct choice of its parameters can be made only on the basis of direct experimental measurements.

Extreme hemodilution with PEG-hemoglobin vs. PEG-albumin.

Isovolemic hemodilution to 11% systemic hematocrit was performed in the hamster window chamber model using 6% dextran 70 kDa (Dx 70) and 5% human serum albumin (HSA). Systemic and microvascular effects of these solutions were compared with polyethylene glycol (PEG)-conjugated 5% albumin (MPA) and PEG-conjugated 4.2% Hb (MP4).

Early difference in tissue pH and microvascular hemodynamics in hemorrhagic shock resuscitation using polyethylene glycol-albumin- and hydroxyethyl starch-based plasma expanders.

The hamster chamber window model was subjected to hemorrhagic shock by the withdrawal of 50% of blood volume (BV). BV was restored 1 h after hemorrhage with a single volume infusion (resuscitation) of 25% BV with polyethylene glycol (PEG)-conjugated bovine serum albumin (Alb) and hydroxyethyl starch (HES). Hemorrhage, shock, and resuscitation were monitored continuously in terms of mean arterial pressure (MAP), microvascular blood flow, capillary perfusion, and tissue pH.

Increase plasma viscosity sustains microcirculation after resuscitation from hemorrhagic shock and continuous bleeding.

Resuscitation from hemorrhagic shock (50% of blood volume, BV) followed by continuous bleeding (20% of BV per hour, over the entire observation time, 90 min) was studied in the unanesthetized hamster chamber window model. Blood losses equaled 100% of total BV. A single volume infusion (resuscitation) was performed 60 min after hemorrhage using 25% of the BV with 10% hydroxyethyl starch (HES 200, group HES4), or a mixture of HES 200 with 0.

Oxygen release from low and normal P50 Hb vesicles in transiently occluded arterioles of the hamster window model.

A phospholipid vesicle encapsulating Hb [Hb vesicle (HbV)] has been developed as a transfusion alternative. One characteristic of HbV is that the O(2) affinity [Po(2) at which Hb is 50% saturated (P(50))] of Hb can be easily regulated by the amount of the coencapsulated allosteric effector pyridoxal 5'-phosphate. In this study, we prepared two HbVs with different P(50)s (8 and 29 mmHg, termed HbV(8) and HbV(29), respectively) and observed their O(2)-releasing behavior from an occluded arteriole in a hamster skinfold window model.

Effects of extreme hemodilution with hemoglobin-based O2 carriers on microvascular pressure.

A surface-modified polyethylene glycol-conjugated human hemoglobin (MP4) and alpha alpha-cross-linked human hemoglobin (alpha alpha Hb) were used to restore oxygen carrying capacity in conditions of extreme hemodilution (hematocrit 11%) in the hamster window model preparation. Changes in microvascular function were analyzed in terms of effects on capillary pressure and functional capillary density (FCD). MP4, at 1.

Alginate plasma expander maintains perfusion and plasma viscosity during extreme hemodilution.

Extreme hemodilution was performed in the hamster chamber window model using 6% Dextran 70, lowering systemic hematocrit by 60%. Animals were subsequently divided into three groups and hemodiluted to a hematocrit of 11% using 6% Dextran 70, 6% Dextran 500, and a 4% Dextran 70 + 0.7% alginate solution (n = 6 each group).

Elevated plasma viscosity in extreme hemodilution increases perivascular nitric oxide concentration and microvascular perfusion.

We tested the hypothesis that high-viscosity (HV) plasma in extreme hemodilution causes wall shear stress to be greater than low-viscosity (LV) plasma, leading to enhanced production of nitric oxide (NO). The perivascular concentration of NO was measured in arterioles and venules and the tissue of the hamster chamber window model, subjected to acute extreme hemodilution, with a hematocrit (Hct) of 11% using Dextran 500 (n = 6) or Dextran 70 (n = 5) with final plasma viscosities of 1.99 +/- 0.

Microvascular oxygen delivery and consumption following treatment with verapamil.

The microvascular distribution of oxygen was studied in the arterioles and venules of the awake hamster window chamber preparation to determine the contribution of vascular smooth muscle relaxation to oxygen consumption of the microvascular wall during verapamil-induced vasodilatation. Verapamil HCl delivered in a 0.1 mg/kg bolus injection followed by a continuous infusion of 0.

Oxygen transport by low and normal oxygen affinity hemoglobin vesicles in extreme hemodilution.

The oxygen transport capacity of phospholipid vesicles encapsulating purified Hb (HbV) produced with a Po(2) at which Hb is 50% saturated (P 50 ) of 8 (HbV(8)) and 29 mmHg (HbV(29)) was investigated in the hamster chamber window model by using microvascular measurements to determine oxygen delivery during extreme hemodilution. Two isovolemic hemodilution steps were performed with 5% recombinant albumin (rHSA) until Hct was 35% of baseline. Isovolemic exchange was continued using HbV suspended in rHSA solution to a total [Hb] of 5.

Oxygen distribution and respiration by the microcirculation.

Longitudinal and radial oxygen gradients in the microcirculation due to oxygen release from arterioles show that in some tissues oxygen is primarily supplied by arterioles and secondarily by capillaries. In several tissues, the arteriolar rate of oxygen exit is too large to be explained by diffusion alone, indicating that in these tissues oxygen consumption of the arteriolar wall in vivo is much greater than that shown in in vitro studies of endothelium and vascular smooth muscle, a phenomenon that may be related to the synthesis autocoids by the endothelium in vivo. The functional significance of the high metabolic rate of the arteriolar vessels may be related to the need of providing a metabolic barrier for protecting the parenchymal tissue from high oxygen levels in arterial blood, thus reducing formation of oxygen free radicals in the perivascular tissue, a supposition supported by the finding that the radial oxygen gradient at the microvascular wall and therefore its rate of oxygen consumption are proportional to local blood oxygen partial pressure (pO(2)).

Microvascular perfusion upon exchange transfusion with stored red blood cells in normovolemic anemic conditions.

Background: Transfusions are intended to augment oxygen-carrying capacity. The ability of fresh and stored red blood cells (RBCs) to maintain microvascular perfusion and oxygen delivery to the tissue has not been directly measured.

Study Design And Methods: Microvascular responses to exchange transfusion with fresh and stored RBCs after acute isovolemic hemodilution with a plasma expander were investigated with the hamster window chamber model.

Hyperosmotic-hyperoncotic versus hyperosmotic-hyperviscous: small volume resuscitation in hemorrhagic shock.

The aim of this study was to test the effects of using a high-viscosity fluid after small-volume hyperosmotic resuscitation from hemorrhagic shock and to compare this to hyperosmotic followed by hyperoncotic resuscitation. Studies were made in the awake hamster window chamber preparation with the animals subjected to hemorrhage of 50% of blood volume and resuscitated with a small volume of a 7.5% NaCl solution, which was followed within minutes by infusion of 25% of withdrawn volume of either 0.

Resuscitation from hemorrhagic shock with MalPEG-albumin: comparison with MalPEG-hemoglobin.

Our aim was to determine the efficacy of polyethylene glycol-conjugated human albumin (MalPEG-Alb) in restoring circulatory volume after 1 h of hemorrhagic shock. Experiments were performed in the awake condition in the hamster skin fold preparation. Microhemodynamic parameters and tissue Po2 were assessed with intravital microscopy and the use of the phosphorescence quenching technique.

Increased tissue PO2 and decreased O2 delivery and consumption after 80% exchange transfusion with polymerized hemoglobin.

The O2-carrying blood substitute based on polymerized bovine hemoglobin (PBH) was used to determine efficacy in maintaining tissue Po2 after an 80% isovolemic blood exchange leading to a hematocrit of 19% [5.4 g Hb/dl from red blood cells (RBCs) and 6.3 g Hb/dl from PBH].