Alterations in nitric oxide activity and sensitivity in early streptozotocin-induced diabetes depend on arteriolar size.

Changes in NO activity may play an important role in the early increase in microvascular flow that has been implicated in the pathogenesis of diabetic microangiopathy. We assessed, in the in situ spinotrapezius muscle preparation of 6 weeks' streptozotocin-diabetic rats (n = 6) and of age-matched controls (n = 8), basal inside diameters of A2-A4 arterioles and the reactivity to topically applied acetylcholine and nitroprusside, before and after N(G)-nitro-L-arginine. In diabetic rats, cholinergic vasodilatation in A2-A4 arterioles was intact. Basal diameter in A3 and A4 arterioles was significantly higher in streptozotocin-diabetic rats. The increased basal diameter in A3 arterioles was partially due to an increased contribution of NO to basal diameter. The response to nitroprusside was impaired in streptozotocin-diabetic rats in A2, but not in A3 and A4 arterioles. Thus, this study shows that NO activity and sensitivity are altered after 6 weeks of streptozotocin-induced diabetes. These streptozotocin-induced changes are anatomically specific and, for arterioles, depend on their position within the vascular tree.

Pump-induced platelet aggregation in albumin-coated extracorporeal systems.

OBJECTIVE: Coating of extracorporeal systems with heparin does not prevent platelet activation and subsequent bleeding disorders. We investigated whether this could be due to elevated shear stress caused by a roller pump. METHODS: Human or rat blood was made to flow through an uncoated or an albumin-coated medical polyvinyl chloride tube with or without a roller pump. Aggregation of platelets in the tubing was recorded continuously with a photometric device. RESULTS: Although in vitro gravitational flow in uncoated tubes caused immediate platelet aggregation and platelet loss, this remained absent in coated tubes. When the pump was started in experiments with a coated tube strong platelet aggregation was observed and platelet count fell within 5 minutes to 78% +/- 2% and 71% +/- 3% of control values in human and rat blood, respectively. In vivo, no aggregation was observed during spontaneous flow in rats with an albumin-coated tube running from the carotid artery to the femoral artery, but aggregation started as soon as the blood was pumped. Pump-induced platelet aggregation, both in vitro and in vivo, could be prevented with aurintricarboxylic acid, which specifically inhibits shear-induced platelet aggregation as has recently been shown. Pump perfusion of blood in an uncoated tube did not elicit platelet aggregation. CONCLUSIONS: Pump perfusion of blood in coated systems elicits shear-induced platelet aggregation, which may be prevented by administration of substances that block the binding of von Willebrand factor to glycoprotein Ib receptors on the platelets. The effects of pumping on platelets are masked in uncoated circuits because of the dominant influence of blood-material contact.

Soluble glucan protects against endotoxin shock in the rat: the role of the scavenger receptor.

Soluble carboxymethyl-b-1,3-glucan (CMG), a possible ligand for scavenger receptors, has macrophage-activating action but lacks the granulomatose inflammatory side effect: it is a promising immunomodulator that may mitigate the severity of sepsis. This motivated us to study in rats the effect of CMG (25 mg/kg), injected into the tail vein at 48 and 24 h prior to the administration of 5 mg/kg Escherichia coli 0127.B8 endotoxin on survival, hemodynamic condition, and, in vitro, on the chemiluminescence of PMNs and macrophages, and on macrophagal tumor necrosis factor (TNF) production. Acetylated low density lipoprotein (AcLDL) clearance in vivo and in vitro binding to macrophages was used to study scavenger receptor function. In the nonpretreated group 9 of 10 rats died during the first 24 h after endotoxin, but all CMG-pretreated rats survived. CMG-pretreatment prevented severe decreases in cardiac output and blood pressure after endotoxin. Chemiluminescence of macrophages and PMNs from CMG-pretreated rats was about two times less (p < .05) than that from nonpretreated ones; the endotoxin induced TNF production by macrophages also decreased. Pretreatment with CMG increased, but coinjection of CMG and AcLDL decreased the AcLDL clearance, while coinjection of endotoxin and AcLDL decreased the survival rate. In vitro AcLDL uptake by macrophages decreased after coinjection with CMG. Our results thus showed that CMG was protective in rat endotoxin shock, which seemed partly connected with enhancement of endotoxin clearance through scavenger receptors and to decreased TNF production.

Influence of fluid resuscitation on renal function in bacteremic and endotoxemic rats.

PURPOSE: Fluid resuscitation, which is the most important primary therapy in sepsis, is not always able to prevent acute renal failure. In this study, we investigated in two different rat models of distributive shock whether fluid resuscitation would increase renal plasma flow (RPF) and subsequently glomerular filtration rate (GFR). MATERIALS AND METHODS: In pentobarbital anesthetized wistar rats Haemaccel (Behring Pharma, Hoechst, the Netherlands) infusion (1.2 mL/100 g/h for 3 hours) was started immediately during either bacteremia (bolus of living Escherichia coli bacteria, 10(9) or endotoxemia (1 hour infusion of E. coli endotoxin, 8 mg/kg), as well as in time-matched healthy controls. RESULTS: After 3 hours, this treatment had increased RPF (clearance of 131I-hippurate) above normal in control (+67%) and bacteremic rats (+75%), whereas in endotoxemic animals, the significantly decreased RPF was normalized. On the other hand, in bacteremic animals, the lowered GFR (clearance of creatinine; x44%) was normalized, whereas in endotoxemic animals GFR remained depressed (x30%). The lack of improvement in GFR during endotoxemia was also indicated by a profound fall in urine flow, which by contrast steadily increased in control and bacteremic rats owing to volume loading. In both shocked groups, the decreased renal oxygen delivery was normalized, but the higher renal oxygen consumption than expected on the basis of the work needed for sodium reabsorption was not influenced by Haemaccel treatment, despite the fact that it caused this work load to rise in bacteremic but not in endotoxemic rats. In both shock models, renal cortical adenosine triphosphate content did not differ from healthy controls and was not influenced by volume loading. CONCLUSIONS: In conclusion, our study suggests that a decrease in GFR caused by live bacteria in the circulation may benefit from fluid resuscitation, while during endotoxemia this therapy could not prevent acute renal failure.

Renal function and oxygen consumption during bacteraemia and endotoxaemia in rats.

BACKGROUND: The hypothesis that renal failure during septic shock may occur as a result of hypoxia-related cell dysfunction was investigated in two rat models of distributive shock. METHODS: Pentobarbitone-anaesthetized rats received either a bolus (1 ml) of living Escherichia coli bacteria (hospital-acquired strain, 1 x 10(9) CFU/ml; BA-group, n = 7), or a 1-h infusion of endotoxin (E. coli O127.B8: 8 mg/kg; ET-group, n = 7), or saline to serve as time matched controls (C-group, n = 7). RESULTS: Urine flow in the BA- and ET-group reached a nadir at 1 h, but thereafter increased and reached values higher than control at 3 h. At this time point, renal oxygen delivery had decreased, in the BA-group mainly due to a fall in arterial oxygen content and in the ET-group to a fall in renal plasma flow (clearance of 131I-hippurate). However, renal oxygen extraction had significantly increased, by 31% in the BA and by 59% in the ET group, while renal oxygen consumption remained the same. Net tubular sodium reabsorption had decreased by 55% in the BA and by 25% in the ET group, due to a fall in glomerular filtration rate (clearance of creatinine). Hence, an excess oxygen consumption was found which was caused neither by an increased renal glucose release nor by the presence of an increased number of leukocytes stuck in the glomeruli. Renal tubular cells showed normal morphology. An indication that proximal tubular function in the BA and ET group remained largely intact were normal ATP levels, absence of urinary glucose, and a normal fractional excretion of sodium. However, since urine flow had increased in shocked rats at 3 h, water appeared selectively lost. CONCLUSIONS: Our data indicate that in rat models of septic shock renal failure is not caused by cortical hypoxia or a shortage of cellular energy supply.

Laparotomy and renal function during endotoxin shock in rats.

Despite the wide use of laparotomy to study kidney function, the possible influence of this procedure on systemic and renal parameters in septic rats is unknown. We studied this in anesthetized Wistar rats with and without endotoxin shock (1 h Escherichia coli O 127.B8: 8 mg.kg-1 infusion). We also compared clearance of creatinine and inulin to measure glomerular filtration rate (GFR). Laparotomy attenuated the endotoxin-induced decrease in cardiac output and abolished the increase in systemic and renal vascular resistance, while renal plasma flow was maintained. Better perfusion in other organs as well was indicated by a more gradual increase in arterial lactate concentration and less intestinal damage. By contrast, GFR decreased considerably during endotoxemia, irrespective of laparotomy. This change in GFR could be reliably assessed using creatinine clearance. The ratio of creatinine-to-inulin clearance averaged between .5 and .75. Renal ATP content did not change and the endotoxin-induced increase in the number of granulocytes lodged in glomeruli was not affected by laparotomy. In conclusion, our study indicates that laparotomy significantly influences the vascular effects caused by endotoxin. Laparotomy also revealed an effect of endotoxin on GFR, independent of renal blood flow.

Gram-negative shock in rats depends on the presence of capsulated bacteria and is modified by laparotomy.

To develop a hyperdynamic sepsis model in rats, four Escherichia coli strains were used, which differed in the presence or absence of a capsule or K antigen (K1 and K-, respectively) and/or in O serogroup (O9 and O18). Of the two clinical isolates, O9K- did not survive in rat serum, whereas O18K1 and two isogenic laboratory strains (O18K1 and O18K-) were able to resist serum bacteriolysis. Pentobarbital-anesthetized rats (n = 21) received an intravenous bolus of 10(9) bacteria. In contrast to the two noncapsulated strains, both capsulated strains induced hyperdynamic shock; arterial lactate rose from a mean value of .91 to 3.09 mmol.L-1, systemic vascular resistance dropped from 1.15 to .78 mmHg.min.mL-1, and cardiac output transiently increased from 98 to 115 mL.min-1; renal plasma flow remained at 3-4 mL.min-1, whereas glomerular filtration rate decreased from 1.3 to .7 mL.min-1. Laparotomy, which is often performed to study kidney function, completely abolished the hyperdynamic condition, while glomerular filtration rate was still decreased. We conclude that in rats, in contrast to humans, capsulated bacteria are required to induce a hyperdynamic septic shock; the hyperdynamic characteristics of the shock do not occur in animals subjected to a laparotomy.

The fall of cardiac output in endotoxemic rats cannot explain all changes in organ blood flow: a comparison between endotoxin and low venous return shock.

During endotoxin shock mean arterial pressure (MAP) and cardiac output (CO) fall, and the latter is redistributed. To evaluate whether these changes are solely caused by the low output, or are also based on endotoxin itself, we compared regional hemodynamic changes during endotoxemia with those in a nonendotoxemic state of decreased CO in anesthetized rats. In group E (n = 10) endotoxin Escherichia coli O127:B8 (8 mg.kg-1) was infused from t = 0 till t = 60 min. In group B (n = 10) the same decrease of CO and MAP was obtained as in group E by inflating a balloon in the inferior caval vein, distal to the renal veins, from t = 0 till t = 60 min. We measured MAP, CO (thermodilution), central venous pressure, heart rate, organ blood flow, and redistribution of CO (microspheres), arterial lactate and glucose, and hematocrit. MAP and CO decreased (p < .05) in both groups (by 30 and 50%, respectively at t = 60). Heart rate, hematocrit, arterial lactate, and arterial glucose were significantly higher (p < .05) in group E (by 17, 12, 180, and 55%, respectively). Blood flow to most organs had similarly decreased in both groups. The decreased intestinal blood flow lead to macroscopic damage only in group E. Blood flows (absolute or as percentage of CO) to heart, hepatic artery, and diaphragm, however, had significantly increased in group E while blood flows to skin, skeletal muscle, and stomach had decreased more in group E. Except for the heart these differences could be explained by increased work load (detoxification: liver; hyperventilation: diaphragm, muscle) and thus to a more pronounced redistribution at the expense of skin and muscle blood flow. Regional hemodynamic changes during endotoxemia thus could largely be attributed to decrease of CO and redistribution of the circulating blood volume. In the heart, endotoxin seemed to exert effects independent of the hypodynamic state. This was also true for the intestinal damage and the rise in hematocrit and arterial lactate.

Abdominal compressions increase vital organ perfusion during CPR in dogs: relation with efficacy of thoracic compressions.

STUDY OBJECTIVE: Abdominal compressions can be interposed between the thoracic compressions of standard CPR (SCPR). The resulting interposed abdominal compression CPR (IAC-CPR) may increase blood pressures and patient survival, particularly if applied as a primary technique after in-hospital cardiac arrest. We used a predominant cardiac compression canine model to study the effects of IAC-CPR on blood pressures and total and vital organ perfusion as a function of time after cardiac arrest and efficacy of SCPR. DESIGN: In a crossover design, we measured blood pressures and total and regional blood flow (radioactive microspheres) during 6-minute episodes of mechanical SCPR and IAC-CPR, both early (4 to 16 minutes) and late (18 to 30 minutes) after induction of ventricular fibrillation in eight dogs (weight, 25 to 33 kg) under neuroleptanalgesia/anesthesia. RESULTS: During IAC-CPR, the ascending aortic-right atrial pressure gradient increased (P < .05), and retrograde pressure pulses contributed to the rise of ascending aortic pressure. Within 2 minutes after the start of IAC-CPR, end-tidal CO2 fraction increased by 0.6 +/- 0.4 vol% (P < .05), suggesting enhanced venous return. IAC-CPR enhanced (P < .05) total forward blood flow (574 +/- 406 versus 394 +/- 266 mL/minute during SCPR for the early phase) and vital organ perfusion (including myocardium), in both early and late phases. The IAC-CPR-induced augmentation of blood flow was greater if perfusion was relatively high during SCPR. CONCLUSION: Compared with predominant cardiac compressions alone (SCPR), the addition of interposed abdominal compressions (IAC-CPR) improves total and vital organ oxygen delivery through enhanced venous return and perfusion pressures.

Protective role of NO in the regional hemodynamic changes during acute endotoxemia in rats.

The role of NO during the first hour of endotoxemia is still controversial. To evaluate whether NO is protective or detrimental to the regulation of systemic blood pressure, cardiac output (CO), and organ perfusion in rats during acute endotoxemia, we have studied the effects of inhibition of NO synthesis. Thirty minutes after 0.1 mg NG-nitro-L-arginine (L-NNA; group L, n = 7, partial inhibition), 1 mg L-NNA (group H, n = 6, complete inhibition), or saline (group E, n = 7) intravenous infusion, anesthetized volume-loaded rats were infused with endotoxin Escherichia coli O127:B8 (8 mg.kg-1 x h-1) from time (t) = 0 to 60 min. Organ blood flow was measured with radioactive microspheres. In group H, at time 0, CO was lower than in group E (by -29%; P < 0.05), and systemic vascular resistance (SVR) was higher than in groups E and L (by 72 and 51%, respectively; P < 0.05). Perfusion of the pancreas, stomach, intestines, and kidney was lower (P < 0.05) and corresponding organ vascular resistance (OVR) higher (P < 0.05) in group H than in groups E and L (except kidney in group L). At t = 60 min, in groups H and L, CO was lower (by -45 and -26%, respectively; P < 0.05) and SVR was higher (by 112 and 54%, respectively; P < 0.05) than in group E. In group L only blood flow to the heart, pancreas, intestines, and kidney was significantly lower than in group E, and corresponding OVR was higher.(ABSTRACT TRUNCATED AT 250 WORDS)

High-energy phosphates in heart, liver, kidney, and skeletal muscle of endotoxemic rats.

Endotoxemia can affect the storage of high-energy phosphates [ATP, creatine phosphate (CrP)] even in organs in which global blood flow does not fall. If a decrease in this storage is due to an inadequate oxygen supply-to-demand ratio, improving the perfusion should restore it. Therefore, in anesthetized endotoxemic rats we studied organ perfusion and the storage of high-energy phosphates of heart, liver, kidney, and skeletal muscle and measured the effects of improving cardiac output (CO) and organ blood flow with cardiostimulatory drugs [dopexamine (DX) and dobutamine (DB)]. Endotoxin (Escherichia coli O127.B8, 8 mg/kg) was infused from 0 to 60 min in three groups of anesthetized rats: one untreated (saline only) group (ES; n = 10), and two groups in which we infused DX (3 x 10(-8) mol.kg-1.min-1; n = 10) or DB (10(-7) mol.kg-1.min-1; n = 8) from 60 to 135 min. A fourth group served as time-matched controls (C; n = 8). Organ blood flows at 0 and 135 min (end of experiment) were measured with radioactive microspheres. In biopsies (at 135 min) we measured lactate, ATP, and CrP concentrations. Endotoxemia decreased CO (45% at 135 min; P < 0.05), which could be restored by DX and DB. Myocardial and skeletal muscle blood flow and ATP did not differ in the groups at 135 min. Hepatic and renal blood flow decreased in the ES group 44 and 52%, respectively (P < 0.05); DX restored the fall of hepatic and DB of renal blood flow.(ABSTRACT TRUNCATED AT 250 WORDS)

Vasodilation by shear-induced platelet aggregation in extracorporeal circuits.

Extracorporeal circulation may have adverse effects on vascular reactivity. To reduce such effects, we recently coated a tube connecting the carotid and the distal femoral artery of rats with albumin. When we partially occluded this perfusion line, the reduction of flow was followed by a marked increase, which seemed not to be caused by autoregulation but by release of a vasodilator at the site of occlusion. In the present study, we investigated whether this vasodilator could originate from platelets aggregating under the influence of increased shear stress at the site of occlusion. Blood distal to the site of occlusion indeed contained numerous platelet aggregates that were not present before occlusion. Continuous recording with a photometric device showed that aggregation in the tube started before flow increased and ended before flow decreased again. Blockade of serotonin S1- and S2-receptors with methiothepin prevented the flow response. Estimated shear stress (231 +/- 17 dyn/cm2) and shear rate (6,370 +/- 478 s-1) at the site of occlusion were of the magnitude known to elicit platelet aggregation. Others have recently demonstrated that shear-induced platelet aggregation is mediated by binding of von Willebrand factor to platelet glycoprotein Ib, which is inhibited by aurintricarboxylic acid. This drug (35 mg/kg iv) completely abolished both platelet aggregation and flow increase in our experiments. These results suggest that the vasodilation during partial tube occlusion is mediated by serotonin released from platelets that aggregate as a result of high shear stress.

Systemic and regional hemodynamic changes during endotoxin or platelet activating factor (PAF)-induced shock in rats.

To evaluate the role of platelet activating factor (PAF) during endotoxin shock, we compared its effects with those of endotoxin. We measured arterial pressure (MAP), heart rate (HR), cardiac output (CO; thermodilution), arterial lactate (Calact), organ blood flow (radioactive microspheres), and organ vascular resistance in four groups of anesthetized (pentobarbital) male Wistar rats (n = 7 per group), infused from t = 0 to t = 60 min with saline (group C: time matched control), endotoxin Escherichia coli O127:B8, 8 mg.kg-1 (group E), a "low PAF dose" (1 microgram.kg-1) to cause the same decrease in MAP as in group E (group PL), or a "high PAF dose" (3 micrograms.kg-1) to cause the same decrease in CO as in group E (group PH). At t = 60 min, MAP had decreased by 33% in E and PL, and by 55% in PH group. CO had decreased by 41% in the E and PH group. Calact had increased in the E and PH group by 300 and 200%, respectively. In the E, PL and PH group, coronary vascular resistance decreased. In the splanchnic organs, endotoxin caused a decrease in blood flow due to vasoconstriction, whereas PAF (both concentrations) caused vasodilation (except for spleen). Renal vascular resistance decreased (P < 0.05) in the PL group. In all groups, vascular resistance had increased (P < 0.05) in skin, and not changed in skeletal muscle (P < 0.05). Thus, hemodynamic changes after PAF infusion were partially similar to those after endotoxin infusion (coronary vasodilation and vasoconstriction in spleen and skin).(ABSTRACT TRUNCATED AT 250 WORDS)

Organ blood flow and distribution of cardiac output in dopexamine- or dobutamine-treated endotoxemic rats.

Endotoxemia causes a decrease of blood flow to most organs. If this could be prevented, chances of survival might improve. In endotoxemic rats, we studied the effect of a therapeutic infusion of dopexamine (dopaminergic, beta 2-adrenergic) on blood flow and percentage of the cardiac output distributed to heart, brain, hepatic artery, stomach, intestines, spleen, pancreas, kidneys, adrenals, diaphragm, skeletal muscle, and skin. Dopexamine action was compared with that of dobutamine (beta 1-adrenergic). Endotoxin shock was induced in 28 rats with infusion of 8 mg/kg Escherichia coli O127:B8 endotoxin from 0 to 60 minutes; the rats were then divided into 3 groups, which received from 60 to 135 minutes of an infusion of saline (ES; n = 10), dopexamine hydrochloride (DX, 3 x 10(-8) mol/kg.min; n = 10) or dobutamine (DB, 10(-7) mol/kg.min; n = 8). A fourth group served as time-matched controls (C, saline from 0 to 135 minutes; n = 8). In the untreated endotexemic rats, cardiac output decreased and organ blood flow decreased except in the diaphragm, heart, and brain; the percentage of the cardiac output to those organs increased. Dopexamine and dobutamine similarly improved cardiac output in endotoxemic rats. All organs benefitted to the same extent from the increased cardiac output. Therapeutic infusion of dopexamine during endotoxemia did not favor flow to any particular organ; redistribution of cardiac output changed little after administration of dopexamine, and its effects were not significantly different from those of dobutamine.

Development of renal failure in endotoxemic rats: can it be explained by early changes in renal energy metabolism?

Endotoxin shock not only causes renal failure, endotoxemia also leads to metabolic impairment, resulting in energy shortage and loss of cellular integrity; therefore, we tested the hypothesis that early changes in renal metabolism contribute to the development of acute renal failure during endotoxin shock. Endotoxin (Escherichia coli 127B8; 8 mg/kg from t = 0 to 60 min) was infused in three groups of 8 rats, in which renal biopsies were taken at t = 30, 50 and 90 min, respectively; a fourth group (n = 8) served as control. In the biopsies, glucose, lactate, ATP, ADP, AMP and creatine phosphate concentrations were determined. Renal plasma flow (RPF) and glomerular filtration rate (GFR) were measured from the clearances of 131I-hippurate and 125I-thalamate, respectively. We also assayed urine flow (V; catheter in the bladder), cardiac output (CO), blood pressure (MAP), heart rate (HR) and arterial lactate, glucose and creatinine concentrations. During the first 30 min of endotoxemia, we found no systemic hemodynamic or biochemical changes. From t = 30 to t = 90, CO and MAP decreased to 59 and 70%, respectively, while HR and serum levels rose to 110 and 800%, respectively (p < 0.05), indicating progression of shock. Renal function clearly deteriorated from t = 30; at t = 90 RPF, GFR and V had decreased by 86, 84 and 86%, respectively, plasma creatinine being 193% of the baseline value (p < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)

Extracorporeal circuits and autoregulation: effect of albumin coating.

Autoregulation of muscle blood flow often is difficult to demonstrate when extracorporeal perfusion is used. This could be caused by contact of blood and foreign material. Accordingly, we tested whether autoregulation is preserved when the system is coated with albumin. Polyurethane tubing between the carotid and distal femoral artery of rats was partially occluded for 1-2 min. With the system uncoated (n = 6 rats) autoregulation was absent. With coated systems (n = 6 rats) the closed-loop gain (Gc) of the apparent autoregulation (0 < Gc < 1) for the pressure range from control (137 +/- 14) to 80 mmHg was 0.40 +/- 0.24 (mean +/- SD). In most cases autoregulation was preceded by a period of "superregulation": after a variable delay flow rose above control. When the distance between occluder and tip of femoral cannula was varied in another group of rats (n = 6), the delay (20-75 s) was linearly related to transit time (10-35 s) of blood. Flow increase thus seemed to be caused by a blood-borne vasodilator originating at the occlusion site and not by a myogenic or metabolic response to decreased pressure and flow. The vasodilator did not originate from the albumin coating. Partial occlusion of an extracorporeal shunt thus can increase flow to the perfused tissue when the system is coated with albumin. The reaction readily disappears when the system is not coated.

Metabolic vasodilatation with glucose-insulin-potassium does not change the heterogeneous distribution of coronary blood flow in the dog.

OBJECTIVE: The heterogeneous distribution of coronary blood flow could represent regional differences in demand, or mismatching of regional O2 supply to demand, caused by regionally exhausted vasodilatation (anatomical/mechanical factors) or by regional arteriovenous diffusional O2 shunting. Regional coronary blood flow and global myocardial oxygenation and metabolism were measured during metabolic vasodilatation with glucose-insulin-potassium (GIK). METHODS: Variables were studied before and 30 and 60 min after start of a 30 min infusion of GIK (50% glucose, 4 ml.kg-1, 8 mM KCl, and 3 U insulin.kg-1). Regional blood flows were measured by radioactive microsphere technique and cardiac output by thermodilution. Experimental subjects were six anaesthetised mongrel dogs, weighing 20-27 kg. RESULTS: GIK increased plasma osmolarity and lactate, decreased haemoglobin, and increased cardiac output by 67(29)% and systemic O2 supply by 32(13)%, at unchanged arterial and central venous pressures and heart rate. Coronary blood flow rose by 97(50)% and left ventricular O2 supply by 56(41)%. Although regional blood flows in small tissue samples of about 1 g in the left ventricle ranged from a factor 0.31 to 1.73 of mean flow, GIK did not change flow heterogeneity and regional flows significantly correlated in time. Left ventricular O2 uptake rose by 42(40)%, while venous PO2 increased and O2 extraction decreased. Global lactate uptake increased at unchanged extraction. Changes were reversed after GIK. CONCLUSIONS: GIK transiently increases myocardial O2 uptake following a raised cardiac output, caused by a hyperosmolarity induced rise in cardiac contractility rather than by haemodilution. Although myocardial O2 supply is distributed heterogeneously, the fractional rise with GIK is almost equal among regions. At constant lactate extraction, increased venous PO2 and decreased O2 extraction do not indicate overperfusion in some regions at the cost of underperfusion in others, are probably caused by a small, direct vasodilating effect of hyperosmolarity, and argue against diffusional O2 shunting. As for global O2 supply to demand, the increase in regional O2 supply is probably well adapted to regionally increased demand during GIK, so that the heterogeneous distribution of O2 supply can be explained by regional differences in demand and not by regionally exhausted vasodilatation or O2 shunting.

Renal function and metabolism during endotoxemia in rats: role of hypoperfusion.

Renal failure often complicates endotoxin shock. This might be due to renal hypoperfusion, but endotoxemia could also have additional effects. We studied in anesthetized rats renal plasma flow (RPF), glomerular filtration rate (GFR), and metabolism (ATP, CrP = creatine phosphate, energy charge = [ATP + 0.5 ADP]/[ATP + ADP + AMP], lactate, glucose) during endotoxin shock (Escherichia coli endotoxin, 10 mg/kg for 60 min; n = 10) and "balloon shock" (balloon inflated in vena cava below renal vein to cause comparable decreases in cardiac output and RPF as in endotoxin-treated rats; n = 10). A third group of rats served as controls (n = 10). At t = 0 infusion of endotoxin was started. At t = 90 min, when cardiac output was low and serum lactate was high (indicating shock), GFR and RPF were obtained from plasma disappearance rates (from t = 90 to t = 135 min) of 125I-thalamate and 131I-hippurate, respectively. Experiments ended at t = 135 min. In both shock groups RPF decreased (by ca. - 75% compared with control rats), but filtration fraction only increased (by 72%) in the "balloon shock" rats. In renal biopsies lactate concentration increased more (by 407 vs. 167%) and ATP decreased more (by -63 vs. - 35%) during endotoxin shock than during "balloon shock"; the endotoxin-treated rats also showed a significant decrease in CrP (by - 58%), energy charge (by - 31%), and glucose concentration (by - 34%), and an increase in the number of leukocytes in the glomeruli (by 730%). Renal function and metabolism thus was more affected in this hypodynamic form of endotoxin shock than in "balloon shock." This may be caused by the effects of endotoxin on sticking of leukocytes and renal metabolism.

Arteriolar and venular reactivity to superfusate pO2 in tissues with different metabolic capacity. A study in skeletal muscle and mesentery of the rat.

In skeletal muscle (extensor hallucis proprius) and mesentery of anesthetised (pentobarbital 30 mg/kg) female rats (200 g) we have compared reactivity to O2 of arterioles and venules with their response to a vasoconstrictor (epinephrine 5.5 x 10(-7) M) and a vasodilator (adenosine 10(-4) M). Muscle arterioles fully constricted with O2 and epinephrine and dilated with adenosine (22%). Muscle venules did not respond to changes in superfusate pO2, constricted 18% with epinephrine and dilated 10% with adenosine. In the mesentery changes in superfusate pO2 had no effect on diameters of arterioles or venules but epinephrine fully constricted arterioles and constricted venules by 19%, while adenosine dilated arterioles (6%) but not venules. When we set arteriolar and venular diameters during adenosine superfusion at 100%, muscle arterioles appeared to operate at 63% and mesenterial arterioles at 84% of maximal diameter at normal tissue pO2. For venules these percentages were 91 and 97%, respectively. Arterioles and venules in muscle thus have higher tone and muscle arterioles are greatly sensitive to changes in tissue pO2 while in our preparation mesenterial arterioles are not.

Maldistribution of heterogeneous coronary blood flow during canine endotoxin shock.

STUDY OBJECTIVE - The aim was to investigate whether heterogeneous coronary blood flow is maldistributed during endotoxin shock. DESIGN - Variables were studied before (t = 0) and at t = 90 and t = 120 min after bolus injection of saline (n = 6) or endotoxin (n = 6). SUBJECTS - 12 anaesthetised mongrel dogs, weight 20-27 kg, were used. MEASUREMENTS AND MAIN RESULTS - We studied myocardial blood flows in small tissue sections (of about 1 g in left and 2 g in right ventricle) with radioactive microspheres, together with haemodynamic variables and global myocardial metabolism. At t = 0 min in controls, regional flows per 100 g were heterogeneous and ranged from a factor 0.2 to 2.7 and 0.6 to 1.6 of mean flow per 100 g to the left and right ventricle respectively; heterogeneity was unchanged at t = 90 and t = 120 min. Between t = 0, t = 90, and t = 120 min regional flows correlated: r = 0.78(SD 0.14), n = 18, for left ventricle, and r = 0.70(0.17) for right ventricle. In the endotoxin group, cardiac output and mean arterial pressure decreased by 44(7) and 48(11)% respectively, and lactate increased by 3.2(0.6) mmol.litre-1 at t = 120 min. Global left ventricle blood flow and delivery and metabolism of O2 were unchanged; lactate extraction and external work fell. The ratio between global right ventricular O2 delivery and external work also rose. Regional blood flows ranged from a factor 0.2 to 2.7 and 0.1 to 1.8 of mean flow to left and right ventricles respectively; heterogeneity did not differ from controls and did not change with time. Flow correlations with time were reduced: 0.45(0.24) for left ventricle and 0.45(0.26) for right ventricle (both n = 18, p less than 0.005 v controls). The left ventricular endocardial to epicardial flow ratio fell; flow was redistributed to both layers. CONCLUSIONS - Heterogeneous blood flow is redistributed throughout the heart during canine endotoxin shock so that, at unchanged global blood flow and flow heterogeneity, flow decreases in some but increases in other areas. Flow maldistribution may be associated with focal ischaemia, which may be masked by a rise in O2 uptake for a given workload (contractile inefficiency) in overperfused areas, and may thereby contribute to a fall in global myocardial external work for a given O2 delivery.