Whether the increase in cerebral blood flow measured after hemodilution is mediated by a decrease in blood viscosity or in oxygen delivery to the brain is debated. In the present study, blood was replaced by an oxygen-carrying blood substitute, ultrapurified, polymerized, bovine hemoglobin (UPBHB). In contrast to normal blood, UPBHB yields a constant and defined viscosity in the brain circulation, since its viscosity is not dependent on the shear rate. CBF was determined after blood exchange with UPBHB in one group of conscious rats (UPBHB group) and in another group of blood-exchanged conscious rats in which viscosity was increased fourfold by the addition of 2% polyvinylpyrrolidone (PVP), mw 750,000 (UPBHB-PVP group). Local CBF (LCBF) was measured in 34 brain structures by means of the quantitative iodo(14C)antipyrine method. After blood replacement, systemic parameters such as cardiac index, arterial blood pressure, blood gases, and acid-base status were not different between the UPBHB and the UPBHB-PVP groups. In particular, arterial oxygen content was similar in both groups. Compared with a control group without blood exchange, LCBF was increased after blood exchange in the different brain structures by 60-102% (UPBHB group) and by 33-101% (UPBHB-PVP group). Mean CBF was increased by 77% in the UPBHB group and by 69% in the UPBHB-PVP group. No significant differences were observed in the values of LCBF or mean CBF between the UPBHB group and the UPBHB-PVP group. The results show that a fourfold variation in the viscosity of a Newtonian blood substitute does not result in differences in CBF values.(ABSTRACT TRUNCATED AT 250 WORDS)
During interhospital transport Paco2(IRMA) and Ptcco2 provide the best accuracy when compared with the reference measurement. Patients who either require a tight control of Pco2 or endured lengthy transportation could benefit greatly from the combination of expiratory capnography with mobile arterial blood gas analysis or the transcutaneous measurement of Pco2.
To date no satisfactory method has been available for the quantitative in vivo measurement of the complex hepatic blood flow. In this study two modelling approaches are proposed for the analysis of liver blood flow using positron emission tomography (PET). Five experiments were performed on three foxhounds. The anaesthetised dogs were each given an intravenous bolus injection of oxygen-15 labelled water, and their livers were then scanned using PET. Radioactivity in the blood from the aorta and portal vein was measured directly and simultaneously using closed external circuits. Time-activity curves were constructed from sequential PET data. Data analysis was performed by assuming that water behaves as a freely diffusible tracer and adapting the standard one-compartment blood flow model to describe the dual blood supply of the liver. Two particular modelling approaches were investigated: the dual-input model used both directly measured input functions (i.e. using the hepatic artery and the portal vein input, determined from the radioactivity detected in the aorta and portal vein respectively) whereas the single-input model used only the measured arterial curve and predicted the corresponding portal input function. Hepatic arterial flow, portal flow and blood volume were fitted from the PET data in several regions of the liver. The resulting estimates were then compared with reference blood flow measurements, obtained using a standard microsphere technique. The microspheres were injected in a separate experiment on the same dogs immediately prior to PET scanning. Whilst neither the single- nor the dual-input models accurately reproduced the arterial reference flow values, the flow values from the single-input model were closer to the microsphere flow values. The proposed single-input model would be a good approximation for liver blood flow measurements in man. The observed discrepancies between the PET and microsphere flow values may be due to the inherent temporal and spatial heterogeneity of liver blood flow. The results presented suggest that adaptation of the standard one-compartment blood flow model to describe the dual blood supply of the liver is limited and other flow tracers have to be considered for quantitative PET measurements in the liver.
These results indicate that the impact of plasma viscosity on the rheological properties of whole blood is completely offset by the concomitant reduction of haematocrit. Thus, the comparatively minor changes in plasma viscosity observed after prolonged use of clinical dextrans and other colloids in no way compromise the perfusion and oxygenation of vital organs.
We addressed the question to which extent cerebral blood flow (CBF) is maintained when, in addition to a high blood viscosity (Bvis) arterial oxygen content (CaO2) is gradually decreased. CaO2) was decreased by hemodilution to hematocrits (Hct) of 30, 22, 19, and 15% in two groups. One group received blood replacement (BR) only and served as the control. The second group received an additional high viscosity solution of polyvinylpyrrolidone (BR/PVP). Bvis was reduced in the BR group and was doubled in the BR/PVP. Despite different Bvis, CBF did not differ between BR and BR/PVP rats at Hct values of 30 and 22%, indicating a complete vascular compensation of the increased Bvis at decreased CaO2. At an Hct of 19%, local cerebral blood flow (LCBF) in some brain structures was lower in BR/PVP rats than in BR rats. At the lowest Hct of 15%, LCBF of 15 brain structures and mean CBF were reduced in BR/PVP. The resulting decrease in cerebral oxygen delivery in the BR/PVP group indicates a global loss of vascular compensation. We concluded that vasodilating mechanisms compensated for Bvis increases thereby maintaining constant cerebral oxygen delivery. Compensatory mechanisms were exhausted at a Hct of 19% and lower as indicated by the reduction of CBF and cerebral oxygen delivery.
Leukotriene C4 (LTC4) underwent rapid elimination from the circulating blood and was extensively converted to LTD4 within the vascular space of the guinea pig. To mimic the elimination and metabolism of endogenous LTC4 generated during anaphylaxis, 14,15-3H-labeled LTC4 was infused intravenously over a period of 15 min, leading to a recovery in bile of 85% of the infused LT radioactivity within 2 h. Corresponding to the tracer studies, LTD4 and, to a lesser extent, LTC4 were the predominant endogenous cysteinyl LTs in guinea pig bile. The biliary production rate of endogenous LTD4 increased from 0.3 +/- 0.1 to 6.2 +/- 1.8 pmol x min-1 x kg-1 (p less than 0.001) during anaphylactic shock induced by intravenous injection of OVA (0.2 mg/kg) into sensitized guinea pigs. A novel LT biosynthesis inhibitor (MK-886; 10 mg/kg, i.v., 15 min before antigen challenge) suppressed the antigen-induced cysteinyl LT production by greater than 92% (p less than 0.001). This inhibition of systemic LTC4 formation was associated with a complete protection against lethal anaphylactic shock in animals pretreated in addition with the H1 receptor antagonist pyrilamine. Pretreatment with either the inhibitor of LT synthesis or the histamine receptor antagonist reduced the lethality during anaphylactic shock from 100 to 60 and 78%, respectively. In artificially ventilated, pyrilamine-pretreated animals, the antigen-induced decrease in dynamic lung compliance and the rise in hematocrit were significantly reduced (p less than 0.05) by pretreatment with the inhibitor of LT synthesis. Dexamethasone at high doses (10 mg/kg, i.p., once daily for 7 d, or in a single dose of 10 mg/kg, i.v., 3.5 h before challenge) had no inhibitory effect on LT generation during anaphylaxis in vivo. However, in resident peritoneal macrophages, harvested from these dexamethasone-treated sensitized guinea pigs and stimulated with zymosan, both cysteinyl LT and 6-keto-PGF1 alpha formation were strongly suppressed. These studies indicate an important role of cysteinyl LTs in systemic anaphylaxis in vivo and demonstrate the blockade of anaphylactic LT generation by a novel inhibitor of LT biosynthesis (MK-886) but not by dexamethasone.
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