Casson Flow of Blood Containing Au and Ta Nanoparticles Over a Stenotic Artery

Decreases in regional endocardial function (ultrasonic dimension technique) and blood flow (radioactive microsphere technique) were correlated in 14 conscious dogs with acute graded levels of coronary stenosis. Coronary stenosis affected overall ventricular function only slightly, but induced gradual reductions in regional blood flow (BF) and segment length (SL) shortening in the ischemic zone. The relationship was best fit by an exponential function relating % change in SL to % change in BF; i.e., SL(% delta) = -161.6 e -0.047BF(% delta) (r = 0.92). In 14 segments, where no change in function was observed, blood flow fell by 6 +/- 1%. However, 10--20% reductions of blood flow impaired function significantly. Severe reduction of blood flow was required to reduce function completely. In 12 segments exhibiting paradoxical motion, blood flow fell by 95 +/- 2%, a value greater (P < 0.01) than in four akinetic segments, i.e., those with no shortening or lengthening (-82 +/- 4%). These data, which show on one hand that only 10-20% reductions in blood flow impair function significantly and that, on the other hand, severe reductions in blood flow are required to abolish active shortening completely, indicate sensitive coupling between blood flow and function in the conscious dog with acute myocardial ischemia.

We have previously demonstrated that there is a reduction of blood flow in the abdominal wall in rats insufflated with air concomitant with an increase in tumor growth. The present study was designed to examine whether a reduction of blood flow achieved by clamping or insufflation with carbon dioxide (CO(2)) would increase tumor growth in the abdominal wall. In the first part of the experiments, laser Doppler blood flow of both rectus muscles was measured in 16 Wistar Fu rats. The left rectus muscle was clamped to reduce blood flow, and 5 x 10(4) adenocarcinoma cells were injected into both rectus muscles. Clamping was maintained for 45 min. In the second part, 22 rats had 5 x 10(4) adenocarcinoma cells injected into the rectus muscle and blood flow was measured. The experimental group (n = 11) was insufflated with CO(2) at 10 mmHg for 45 min; the control group (n = 11) was not insufflated. After 9 days, tumor weight and volume were analyzed. Clamping caused a 69% reduction of blood flow (p < 0.001), whereas no reduction was registered on the nonclamped side. Tumor weight (p = 0.028) and volume (p = 0.030) were increased on the clamped side. The insufflation of CO(2) caused a 71% reduction of blood flow, whereas no reduction was registered in the control group. Tumor weight (p = 0.006) and volume (p = 0.006) were increased in the insufflated group. Clamping, as well as CO(2) insufflation, causes a significant reduction of blood flow in the abdominal wall, which seems to increase tumor growth at the same site.

The effect of moderate reductions in testicular blood flow has not been studied systematically. The aim of this study was, therefore, to examine the effects of different degrees of blood flow reduction on testicular morphology and to determine how much flow can be reduced before damage occurs. The subcapsular testicular artery was partially ligated in the left testes of adult rats. Testicular blood flow was measured before, immediately after, and 5 h after the ligation using laser Doppler flowmetry. After 5 h of partial ligation, the testes were removed, and their morphology was examined and related to the degree of blood flow reduction. The number of in situ end-labeled- or TUNEL-positive (i.e., dying) germ cells and the volume density of intravascular polymorphonuclear (PMN) leukocytes were measured. When flow was reduced to approximately 70% or less of its pretreatment value, a dose-related increase in the number of dying spermatogonia and early spermatocytes was seen. The PMN leukocytes accumulated in testicular blood vessels after partial ligation, and the maximum number was observed in testes where flow was reduced by approximately 50% of the pretreatment value. In conclusion, early stages of spermatogenesis are sensitive to a moderate, acute reduction in blood flow. Discrete reductions in flow may, therefore, have a large impact on sperm production.

We have compared the metabolism of infused somatostatin 14 (SS14) and somatostatin 28 (SS 28) in anesthetized dogs. After iv infusion of either peptide, plasma SS-like immunoreactivity (SLI) coeluted from Bio-Gel P10 columns with the corresponding synthetic peptide marker. The hepatic extraction, renal extraction, MCR, and plasma half-life of plasma SLI and after SS28 infusion were 11.0 +/- 1.5%, 50 +/- 4.8%, 9.9 +/- 1.4 ml/kg.min, and 2.8 +/- 0.3 min, respectively. Corresponding values after SS14 infusion were 43.1 +/- 7.4%, 82.2 +/- 6.6%, 21.9 +/- 6.5 ml/kg.min, and 1.7 +/- 0.2 min. These differences between SS28 and SS14 were all statistically significant (P less than 0.05). When equimolar amounts of each peptide were given as bolus injections, both led to a significant reduction in portal venous blood flow. After the injection of SS14, the reduction in flow was short-lived and returned to baseline by 4 min. However, between 2-7.5 min after the injection of SS28, the reduction in blood flow was significantly greater than that induced by SS14, and returned to baseline only by 15 min. These studies indicate that the metabolism of plasma SLI is significantly slower during the steady state infusion of SS28 in pharmacological doses than after similar infusions of SS14. SS28 led to a more prolonged reduction in portal blood flow than SS14; this effect is probably due to its slowed metabolism. This suggests that further modification of the SS28 molecule may increase its therapeutic potential by slowing its in vivo metabolism.

The mechanisms responsible for changes in myocardial contractility during regional ischemia are unknown. Since changes in high-energy phosphates during ischemia are sensitive to reductions in myocardial blood flow, it was hypothesized that myocardial function under steady-state conditions of graded regional ischemia is closely related to changes in myocardial high-energy phosphates. Therefore, phosphorus-31 nuclear magnetic resonance spectroscopy was employed in an in vivo porcine model of graded coronary stenosis. Simultaneous measurements of regional subendocardial blood flow, high-energy phosphates, pH, and myocardial segment shortening were made during various degrees of regional ischemia in which subendocardial blood flow was reduced by 16-94%. During mild reductions in myocardial blood flow (subendocardial blood flow = 83% of nonischemic myocardium), only the ratio of phosphocreatine to inorganic phosphate (PCr/Pi), Pi, and [H+] were significantly changed from control. PCr, ATP, and PCr/ATP were not significantly reduced from control with mild reductions in blood flow. Changes in myocardial segment shortening were most closely associated with changes in PCr/Pi (r = 0.94). Pi and [H+] were negatively correlated with segment shortening (r = -0.64 and -0.58, respectively) and increased over twofold when blood flow was reduced by 62%. Thus, these data demonstrate that PCr/Pi is sensitive to reductions in myocardial blood flow and closely correlates with changes in myocardial function. These data are also consistent with a role for Pi or H+ as inhibitors of myocardial contractility during ischemia.

Leptomeningeal collateral vessels, linking the 3 major arterial territories over the surface of the brain, have been recognized for >140 years.1 More widespread use of advanced clinical imaging in the past decade has led to increasing recognition of the key importance of collaterals in ischemic stroke outcome.2 However, recent studies from several groups indicate that failure of initially good collateral supply is a key feature of patients with delayed infarct expansion.3,4 This clinically challenging problem typically occurs in the first 1 to 2 days after hospital admission in patients with initially mild stroke symptoms. Rethrombosis of reperfused vessels was previously thought to be the likely cause of delayed infarct expansion in most patients. However, this theory is not supported by more recent evidence from imaging studies. Despite the important recent observations, there is limited understanding of the dynamic control of the collateral circulation, in particular, the cause of collateral blood flow failure. In this article, we will discuss recent observations from our experimental stroke model, indicating a dramatic increase in intracranial pressure (ICP) occurring around 24 hours after onset of even small stroke.5,6 We have also shown a significant linear reduction of collateral blood flow in response to progressive ICP elevation.7 We believe that a similar transient ICP elevation occurring during the first 1 to 2 days post stroke is a likely mechanism to explain delayed infarct expansion in patients with minor stroke. Perhaps surprisingly, we can find no published data on ICP at 24 hours in patients with minor stroke. The preclinical findings suggest that gathering such data should be a priority. ### Human Stroke There is a strong association between the extent of leptomeningeal collaterals and clinical stroke outcome. Initial studies using digital subtraction angiography permitted direct visualization of collateral vessels and …

a) To determine whether isovolemic exchange transfusion with cell-free, bovine fumaryl beta beta-crosslinked hemoglobin results in a different pattern of regional blood flow distribution than transfusion with a poor oxygen-carrying, colloidal solution. b) Because of potential nitric oxide scavenging by plasma-based hemoglobin, to determine whether blood flow differences are reduced after nitric oxide synthase inhibition. A prospective, randomized design with repeated blood flow measurements within groups. Experimental physiology laboratory in a university medical center. Pentobarbital-anesthetized female cats. Three groups of eight cats were studied: a) a control group with no transfusion (hematocrit of 32%); b) an anemia group in which exchange transfusion with an albumin-containing solution reduced hematocrit to 18% over a 40- to 50-min period; and c) a group in which cell-free hemoglobin was exchanged transfused to reduce hematocrit to 18%, without a proportional reduction in oxygen-carrying capacity. Bovine hemoglobin was covalently crosslinked intramolecularly between the 81-lysine residues on the beta-subunits to stabilize the tetramer. Regional blood flow was measured by the radiolabeled microsphere technique before transfusion and at 10, 100, and 180 mins from the start of transfusion. At 190 mins, N omega-nitro-L-arginine methyl ester (L-NAME; 10mg/kg) was infused to inhibit nitric oxide synthase and blood flow was measured 30 mins later. Mean arterial pressure was unchanged in the control and albumin-transfused groups. However, mean arterial pressure increased rapidly in the hemoglobin-transfused group. With hemoglobin transfusion, there were marked reductions in blood flow to the intestines, kidneys and adrenal glands. Administration of L-NAME after hemoglobin transfusion failed to increase arterial pressure or cause further reductions in intestinal, renal, or adrenal blood flow. Administration of L-NAME to the control and albumin-transfused groups increased arterial pressure and reduced intestinal, renal, and adrenal blood flows to values attained with hemoglobin transfusion. In contrast, in skeletal muscle and left ventricle, blood flow rates increased in the albumin-transfused group and were greater than those values found in the control group and hemoglobin-transfused group. The greater flow in the albumin-transfused group persisted after L-NAME administration. There was no difference in renal sodium, potassium, or osmolar excretion, or in urine flow between groups. Transfusion with cell-free, bovine crosslinked hemoglobin in cats can selective reductions in blood flow in the intestines, kidneys, and adrenal glands without evidence of renal dysfunction by a mechanism consistent with nitric oxide scavenging. In skeletal and cardiac muscle, the increase in blood flow persisted after nitric oxide inhibition in the albumin group relative to the hemoglobin-transfused group at equivalent hematocrit values. This finding is consistent with compensatory vasoconstriction with hemoglobin transfusion due to improved oxygenation by this oxygen carrier.

The cardiovascular mighty mini-ruler.

The root of the matter: nitrate-rich beetroot juice reduces skeletal muscle O2 uptake during exercise.

Gastrointestinal monitoring using measurement of intramucosal PCO2.

Gastrointestinal Monitoring Using Measurement of Intramucosal PCO2

Acute renal ischemia is an infrequently encountered clinical entity with occasionally devastating consequences. The renal compensation to acute ischemia is unknown and is the purpose of this report. Eight pigs were anesthetized and ventilated. Left atrial, aortic, CVP, left renal venous, and ureteral catheters were inserted. Renal blood flow (RBF) reduction was accomplished by the graded constriction of the left renal artery using a balloon occluder. Renal oxygen extraction ratio (RER, %), renal oxygen delivery (RO2D, cc/min per 100 gm), renal oxygen consumption (RVO2, cc/min/100 gm), creatinine clearance (CrCl, ml/min), and renal lactate production (delta [L], mg/min per hgm) were measured at baseline and following sequential 90-minute intervals of moderate and then severe left renal flow reduction. Significant increases in renal oxygen extraction were observed when RBF was severely limited (.30 +/- .05 vs .64 +/- .06, p < .01). CrCl decreased precipitously (16.5 +/- 4.6 vs 0.2 +/- 0.07, p < .05). Lactate production by the ischemic organs correlated with blood flow reduction (r = .546, p = .0034). In severe ischemia, healthy kidneys increase oxygen extraction to preserve oxygen consumption.

Adrenergic and neuropeptide Y supersensitivity in denervated nasal mucosa vasculature of the pig

In order to determine whether angiotensin II may influence sympathetically mediated arteriolar constriction in man, we have examined the effect of angiotensin II, infused directly into the left brachial artery of normal subjects, on the reduction in forearm blood flow produced by a lower-body negative pressure (LBNP) of 15 mmHg. Angiotensin II (320 fmol/min) caused no reduction in blood flow when given alone but significantly augmented the reduction in blood flow in response to LBNP. The same dose of angiotensin II did not affect a similar reduction in forearm blood flow produced by infused noradrenaline (12.5-50 ng/min). We conclude that angiotensin II augments sympathetically mediated constriction of resistance vessels in man at concentrations with no direct effect on vessel tone. The lack of an effect of angiotensin II on constriction in response to infused noradrenaline suggests the involvement of a presynaptic mechanism.

See related article, pages 103–112 Winter hibernation carries the promise of rejuvenation in the spring. In a similar fashion, myocardial “hibernation” describes a clinical phenomenon in which patients with ischemic left ventricular dysfunction demonstrate improved cardiac function following bypass surgery.1 The signature of myocardial hibernation is decreased blood flow with preserved glucose uptake, as demonstrated by positron emission tomography imaging, and identifies individuals with ischemic cardiomyopathy who may benefit from revascularization.2 In experimental models of hibernating myocardium, oxygen consumption is reduced in the absence of active ischemia.3,4 This implies that hibernation is a coordinated response to balance myocardial energy utilization with energy production capacity.5 However, within hibernating myocardium, several morphological and functional changes have been observed that can identify regions in which complete revascularization may not result in normalization of contraction.6–10 In fact, those myocardial regions with the greatest metabolic abnormalities in the hibernating tissue demonstrate the longest delay in recovery.11 In the current issue, Page et al12 demonstrate that the process of hibernation is associated with altered expression of mitochondrial proteins. Using 2D differential-in-gel electrophoresis and matrix-assisted laser desorption ionization time-of-flight mass spectrometry in a swine model of hibernation, they have found that key mitochondrial proteins associated with the electron transport chain are reduced. The functional importance of the decreased protein expression is documented by reduced activity measurements of the pyruvate dehydrogenase complex, cytochrome c oxidase, and citrate synthase. The parallel reductions in mitochondrial proteins and contractile function 5 months after placement of the coronary artery constrictor suggest that the “downregulation” of electron transport proteins is related to the reduced oxygen consumption. In fact, the reductions in ATPase correlate with the reduction in subendocardial blood flows in the hibernating myocardium. In addition, “upregulation” of several cytosolic proteins has been observed, including …