Detection of coronary artery stenosis with power Doppler imaging.

BACKGROUND: Power Doppler is a new imaging method for detecting microbubbles during myocardial contrast echocardiography (MCE) based on the registration of variance resulting from ultrasound-induced nonlinear bubble behavior. We tested the hypothesis that power Doppler imaging can be used to quantify coronary stenoses. METHODS AND RESULTS: Three left anterior descending (LAD) coronary stenoses of varying severity were created in each of 9 open-chest dogs. MCE was performed by continuous intravenous infusion of a nitrogen-filled bilayer shell microbubble, PB127, during triggered power Doppler imaging at incremental pulsing intervals. MCE and radiolabeled microsphere measurements were made at baseline and during each stenosis, with and without adenosine stress. Videointensities in the LAD and left circumflex (LCx) beds were plotted against pulsing interval and fit to a previously described exponential function modeling microbubble destruction and replenishment, which was used to derive parameters of bubble velocity (beta) and peak plateau videointensity (A). Contrast defects matching the location of radiolabeled microsphere hypoperfusion were clearly seen, without need for image processing. The product of beta and A was linearly related to LAD/LCx flow (r=0.90, P<0.0001) and inversely related to stenosis gradient (r=-0.70, P<0.0001). Endocardial/epicardial flow ratios were visualized and quantifiable. CONCLUSIONS: As with B-mode harmonics, a model of microbubble destruction/replenishment can be applied to power Doppler data as a means to detect a broad range of stenoses. Image clarity and the lack of attenuation or requirement for background subtraction are additional advantages of this imaging approach. Power Doppler MCE imaging holds promise for the detection of coronary artery disease.

Adverse reactions of low osmolality contrast media during cardiac angiography: a prospective randomized multicenter study.

A multicenter study was performed to determine the incidence of adverse reactions to two contrast media with similar low osmolality during cardiac angiography. The study was of a randomized double-blind design comparing ioxaglate (an ionic dimer) and iopamidol (a nonionic compound) and included 500 patients; 250 patients received ioxaglate and 250 iopamidol. There were 58 adverse reactions attributed to the contrast media in the ioxaglate group and 29 in the iopamidol group (p less than 0.001). Chest pain occurred in 11 patients in the ioxaglate group compared with 5 in the iopamidol group (p = 0.123). Nausea or vomiting was present in 20 and 2 patients, respectively (p less than 0.0003). Allergic adverse reactions, such as bronchospasm, urticaria and itching, occurred in 15 of the ioxaglate group and only 1 of the patients receiving iopamidol (p less than 0.0007). Fifty-two patients in the ioxaglate group had a known allergic history (not to contrast medium) or asthma, whereas 77 receiving iopamidol had a similar history. Seven of the 52 ioxaglate-treated patients developed an allergic adverse reaction compared with none of the 77 in the iopamidol group (p = 0.001). Of 41 patients receiving ioxaglate who were premedicated with diphenhydramine, 4 had an allergic adverse event. In the iopamidol group 45 patients received similar premedication and none had an allergic adverse reaction (p less than 0.03). Thus, this multicenter study shows that adverse reactions occur more often with ioxaglate than with iopamidol and that patients with an allergic history have a greater risk with ioxaglate therapy compared with iopamidol.

Effects of high arterial oxygen tension on function, blood flow distribution, and metabolism in ischemic myocardium.

BACKGROUND: Although oxygen inhalation therapy has long been used in the treatment of acute myocardial ischemia, experimental evidence that increased arterial PO2 has any beneficial effect in the absence of hypoxemia is equivocal. In this study, we used a swine model of subendocardial myocardial ischemia to determine the effects of arterial hyperoxia on regional myocardial contractile function (sonomicrometry), myocardial blood flow distribution (microspheres), and regional myocardial glycolytic metabolism (carbon isotope-labeled substrates). METHODS AND RESULTS: In 10 domestic swine, the left anterior descending coronary artery was cannulated and flow to this artery was strictly controlled via a roller pump in the perfusion circuit. Arterial PO2 was controlled by manipulating inspired oxygen concentration (FIO2). Low-flow myocardial ischemia was induced by reducing pump flow to 50% of the control value, which diminished regional endocardial systolic shortening to 30-50% of normal. After a 15-minute period of flow stability, each animal was exposed in randomized order to two additional 15-minute experimental periods: coronary normoxia (PO2 = 90-110 mm Hg) and coronary hyperoxia (PO2 greater than 400 mm Hg). At each level of oxygenation, we measured regional myocardial function, regional myocardial blood flow and metabolism, and hemodynamic indexes of myocardial oxygen demand. Myocardial ischemia during normoxia reduced systolic shortening to 10.9 +/- 5.3% in the ischemic zone. Hyperoxia increased ischemic zone systolic shortening substantially to 15.2 +/- 4.6%. During myocardial ischemia, endocardial blood flow was decreased to 0.26 +/- 0.06 ml.g-1.min-1 in the ischemic zone. During hyperoxia, endocardial blood flow rose to 0.34 +/- 0.10 ml.g-1.m-1. The endocardial: epicardial flow ratio was 0.45 +/- 0.18 in the initial ischemia period and rose to 0.61 +/- 0.23 in the hyperoxic period. Myocardial ischemia increased regional uptake of glucose, conversion of glucose to released lactate, and net myocardial lactate release. In the ischemic myocardium, coronary hyperoxia decreased both chemically measured lactate production and isotopically measured lactate release and decreased glucose extraction and the conversion of glucose to lactate. CONCLUSIONS: These data demonstrate for the first time that increasing arterial PO2 to high levels during acute low-flow myocardial ischemia improves both function and flow distribution in the ischemic myocardium and decreases glycolytic metabolism in the ischemic zone. The degree of improvement in contractile function (5% absolute increase in systolic shortening or 25% change normalized to preischemic values) is consistent with the observed increase in subendocardial blood flow.

Myocardial metabolism during hypoxia: maintained lactate oxidation during increased glycolysis.

In the intact animal, myocardial lactate utilization and oxidation during hypoxia are not well understood. Nine dogs were chronically instrumented with flow probes on the left anterior descending coronary artery and with a coronary sinus sampling catheter. [14C]lactate and [13C]glucose tracers, or [13C]lactate and [14C]glucose were administered to quantitate lactate and glucose oxidation, lactate conversion to glucose, and simultaneous lactate extraction and release. The animals were anesthetized and exposed to 90 minutes of severe hypoxia (PO2 = 25 +/- 4 torr). Hypoxia resulted in significant increases in heart rate, cardiac output and myocardial blood flow, but no significant change in myocardial oxygen consumption. The arterial/coronary sinus differences for glucose and lactate did not change from normoxia to hypoxia; however, the rate of glucose uptake increased significantly due to the increase in myocardial blood flow. Tracer-measured lactate extraction did not decrease with hypoxia, despite a 250% increase in lactate release. During hypoxia, 90% +/- 4% of the extracted 14C-lactate was accounted for by the appearance of 14CO2 in the coronary sinus, compared with 88% +/- 4% during normoxia. Thus, in addition to the expected increase in glucose uptake and lactate production, we observed an increase in lactate oxidation during hypoxia.

Increased lactate appearance and reduced clearance during hypoxia in dogs.

In order to assess the effects of severe hypoxia on whole body glucose and lactate kinetics, nine experiments were performed on anesthetized, ventilated mongrel dogs. [U-13C]glucose and [1-14C]lactate (n = 5), or [6-14C]glucose and [U-13C]lactate (n = 4) were infused using the primed-continuous infusion method. Cardiac output was measured by thermodilution. After a control period with 21% O2, inspired O2 was reduced for 90 minutes. Three of the experiments resulted in unstable hemodynamics and lactate levels, and are excluded from the mean data. Arterial PO2 fell from a control level of 106.8 +/- 11.9 to 24.2 +/- 3.5 mmHg during the last 45 minutes of hypoxia, and O2 transport fell to 52% of normoxic values. Arterial lactate concentration and the rate of appearance increased by 428% and 182%, respectively, from control to hypoxia. The metabolic clearance rate for lactate fell by 34%. Arterial glucose levels did not change significantly with hypoxia, but the rate of glucose disappearance rose by 70%, and the rate of glucose conversion to lactate increased 3-fold. It is concluded that acute severe hypoxia in anesthetized dogs causes 1) a large increase in arterial lactate levels, but no significant change in glycemia, 2) a large increase in the rate of lactate disappearance and only a small increase in the rate of glucose disappearance and 3) a fall in the metabolic clearance rate of lactate.

Myocardial lactate release during ischemia in swine. Relation to regional blood flow.

To determine the relation between regional myocardial blood flow, contractile function, and myocardial lactate release during mild-to-moderate regional myocardial ischemia, nine open-chest swine were instrumented for measurement of regional myocardial blood flow (microsphere method), contractile function (sonomicrometry), and hemodynamics. L-[1-14C]Lactate or L-[U-13C]lactate was infused intravenously using a primed continuous infusion technique to quantify regional myocardial lactate release. D-[U-13C]glucose or D-[6-14C]glucose was simultaneously infused to determine the contribution of exogenous glucose to lactate release. Graded coronary ischemia (two to three levels) was created in the left anterior descending coronary arterial distribution by mechanically constricting the artery in five animals or by decreasing flow through a cannulated left anterior descending artery in four animals. In all nine animals, subendocardial blood flow was 0.99 +/- 0.21 (ml/min)/g during control and 0.34 +/- 0.14 (ml/min)/g during the most severe grade of underperfusion (p less than 0.001) in the left anterior descending coronary arterial distribution. Regional myocardial lactate release was 0.15 +/- 0.09 and 1.19 +/- 0.75 mumols/ml, respectively (p less than 0.003). A highly significant inverse correlation was observed between subendocardial blood flow and myocardial lactate release during the graded reductions in blood flow (r = -0.71, p less than 0.001). Results from sonomicrometry showed a significant reduction in contractile ventricular function in the anterior wall during the graded reductions in blood flow. The regional arterial-venous glucose difference increased significantly with underperfusion in the left anterior descending coronary arterial distribution, from 0.14 +/- 0.15 to 0.56 +/- 0.37 mumols/ml (p less than 0.003). The contribution of exogenous glucose to lactate release also increased significantly; 0.04 +/- 0.03 mumols/ml of the lactate came from exogenous glucose during control compared with 0.64 +/- 0.59 mumols/ml during the most severe underperfusion (p less than 0.02). A significant positive correlation exists between lactate release and lactate from exogenous glucose during graded underperfusion (r = 0.96, p less than 0.001). In summary, these data demonstrate a close inverse relation between regional myocardial lactate release and regional subendocardial blood flow during graded ischemia.

Effects of acute hyperglycemia on myocardial glycolytic activity in humans.

The effects of hyperglycemia on myocardial glucose metabolism were investigated in seven healthy male subjects (age 24 +/- 4 yr). [6-14C]Glucose and [U-13C]lactate were infused as tracers. Circulating glucose was elevated to two hyperglycemic levels using a clamp technique for 1 h at each level. The mean arterial glucose concentration was 4.95 +/- 0.29 (control), 8.33 +/- 0.31 and 10.84 +/- 0.60 mumols/ml, respectively. Glucose extraction increased significantly from control (0.15 +/- 0.13 mumols/ml) during each level of the glucose clamp (0.28 +/- 0.12, P less than 0.02, and 0.54 +/- 0.14 mumols/ml, P less than 0.005, respectively). Myocardial production of 14CO2 showed that during control 9 +/- 10% of exogenous glucose was oxidized immediately upon extraction. Despite a significant increase in the amount of exogenous glucose oxidized with level II hyperglycemia, it represented only 32 +/- 10% of the glucose extracted. [13C]Lactate analysis showed that the myocardium was releasing lactate; during control 40 +/- 30% of this lactate was derived from exogenous glucose and during hyperglycemia this value increased to 97 +/- 37% (P less than 0.005). Thus, these data show that during short-term hyperglycemia, myocardial glucose extraction is enhanced. However, despite increases in exogenous glucose oxidation and the contribution of exogenous glucose to lactate release, the majority of the extracted glucose (i.e., 57%) is probably stored as glycogen.

Tracer mixing: sites of tracer infusion and sampling.

Controversy exists in the literature concerning the correct infusion and sampling sites in studies measuring substrate turnover rates. To investigate this problem, we examined the results obtained with various infusion and sampling sites in 7 anesthetized dogs. [1-14C]lactate was infused by a primed continuous infusion method in three different sites (the left ventricle, ascending aorta, and the aortic arch) in a sequential fashion; samples were obtained simultaneously from five sites (femoral artery, carotid artery, pulmonary artery, superior vena cava and inferior vena cava) for each of the three different infusion sites. [U-13C]lactate was also infused in a femoral vein and simultaneous samples were obtained in the carotid artery and femoral artery for analysis of the stable isotope. [14C]lactate analysis demonstrated that infusion of the tracer into the left ventricular chamber resulted in a uniform distribution in the systemic circulation. Infusion into the ascending aorta near the aortic valve resulted in uniform distribution of tracer in four out of five experiments. Tracer infusion into the aortic arch resulted in nonuniform systemic distribution of tracer. The [U-13C]lactate results showed that infusion into the femoral vein gives uniform systemic distribution, similar to that observed with left ventricular infusion. The pulmonary artery lactate specific activities varied from those in the superior vena cava. Thus, this study shows that the tracer must be infused in the left ventricle or upstream from this chamber to obtain optimal systemic distribution. Vena caval sampling, especially superior vena caval sampling, will not give a consistent mixed venous concentration of the lactate tracer. Therefore, aortic tracer infusion with vena caval sampling may lead to errors in determining substrate turnover values.

Inhibition of endogenous lactate turnover with lactate infusion in humans.

The extent to which lactate infusion may inhibit endogenous lactate production, though previously considered, has never been critically assessed. To examine this proposition, single injection tracer methodology (U-14C Lactate) has been used for the estimation of lactate kinetics in 12 human subjects under basal conditions and with the infusion of sodium lactate. The basal rate of lactate turnover was measured on a day before the study with lactate infusion, and averaged 63.7 + 5.5 mg/kg/h. Six of these individuals received a stable lactate infusion at an approximate rate of 160 mg/kg/h, while the remaining six individuals were infused at the approximate rate of 100 mg/kg/h. It has been found that stable lactate infused at rates approximating 160 mg/kg/h consistently produced a complete inhibition of endogenous lactate production. Infusion of lactate at 100 mg/kg/h caused a lesser and more variable inhibition of endogenous lactate production (12% to 64%). In conclusion, lactate infusion significantly inhibits endogenous lactate production.

Comparison of low osmolality ionic (ioxaglate) versus nonionic (iopamidol) contrast media in cardiac angiography.

A double-blind randomized study was performed in 60 patients to compare the electrocardiographic and hemodynamic changes induced during cardiac angiography by 2 contrast media with relatively low osmolality. Ioxaglate meglumine sodium, an ionic dimer contrast medium, was compared with iopamidol, a nonionic compound. Of the 30 patients who received ioxaglate, 13 (43%) experienced a mild to moderate adverse reaction to the contrast media, while only 2 of the 30 patients (7%) in the iopamidol group had similar side effects (p less than 0.005). Significant prolongations of the QT intervals occurred with the ioxaglate injections. The QT intervals increased from 402 +/- 46 to 442 +/- 59 ms (p less than 0.001) with the right coronary artery injection and similar changes were observed after the left coronary artery injection and left ventriculography. Significant ST-segment and T-wave amplitude changes also occurred in the ioxaglate group. With iopamidol injections, there were no significant changes in any of these parameters. After the left ventriculogram, there were similar decreases in the systolic arterial pressures in both groups (-14 +/- 10 mm Hg with ioxaglate and -21 +/- 9 mm Hg with iopamidol). The left ventricular end-diastolic pressures increased after the ventriculogram in both groups (5 +/- 5 vs 2 +/- 3 mm Hg with ioxaglate and iopamidol, respectively, 60 seconds after the injection). This report demonstrates that mild to moderate adverse reactions, QT-interval prolongations, ST and T-wave changes were significantly greater during coronary angiography with ioxaglate when compared with iopamidol.(ABSTRACT TRUNCATED AT 250 WORDS)

Myocardial substrate utilization during exercise in humans. Dual carbon-labeled carbohydrate isotope experiments.

The purpose of this study was to investigate myocardial substrate utilization during moderate intensity exercise in humans. Coronary sinus and arterial catheters were inserted in nine healthy trained male subjects (mean age, 25 +/- 6 (SD) years). Dual carbon-labeled isotopes were infused, and substrate oxidation was quantitated by measuring myocardial production of 14CO2. Supine cycle ergometer exercise was performed at 40% of the subject's maximal O2 uptake. With exercise there was a significant increase in the arterial lactate level (P less than 0.05). A highly significant positive correlation was observed between the lactate level and the isotopic lactate extraction (r = 0.93; P less than 0.001). The myocardial isotopic lactate uptake increased from 34.9 +/- 6.5 mumol/min at rest to 120.4 +/- 36.5 mumol/min at 5 min of exercise (P less than 0.005). The 14CO2 data demonstrated that 100.4 +/- 3.5% of the lactate extracted as determined by isotopic analysis underwent oxidative decarboxylation. Myocardial glucose uptake also increased significantly with exercise (P less than 0.04). The [14C]glucose data showed that only 26.0 +/- 8.5% of the glucose extracted underwent immediate oxidation at rest, and during exercise the percentage being oxidized increased to 52.6 +/- 7.3% (P less than 0.01). This study demonstrates for the first time in humans an increase in myocardial oxidation of exogenous glucose and lactate during moderate intensity exercise.

Glucose and lactate interrelations during moderate-intensity exercise in humans.

To evaluate circulating lactate and glucose kinetics during moderate-intensity exercise, we studied ten healthy endurance-trained men (aged 25 +/- 6 years) during 30 to 50 minutes of supine cycle ergometer exercise at 43% +/- 5% of maximal oxygen consumption (VO2 max) using isotopic tracer techniques. Seven subjects received [U-13C]-lactate and [6-14C]-glucose, and three received [1-14C]-lactate and [U-13C]-glucose. Arterial glucose and lactate concentrations were 94.0 +/- 4.1 and 5.66 +/- 0.87 mg/dL at rest, and 95.7 +/- 3.4 and 8.38 +/- 3.87 mg/dL, respectively, after 25 minutes of exercise. The rate of glucose disappearance (RdG) increased from 2.41 +/- 0.40 at rest to 3.38 +/- 0.77 mg x kg-1 x min-1 during exercise, compared with the much larger rise in the rate of lactate appearance (RaL), which increased from 1.25 +/- 0.20 to 3.47 +/- 0.79 mg x kg-1 x min-1. During exercise RaL was 103% of RdG, compared with only 52% at rest. The rate at which the blood was cleared of lactate increased from 22.7 +/- 2.2 at rest to 44.2 +/- 11.2 ml x kg-1 x min-1 after 25 minutes of exercise. From secondary labeling of lactate with glucose carbons, the rate of glucose conversion to lactate was estimated to be 0.65 +/- 0.16 mg x kg-1 x min-1 during exercise. Twenty percent of the glucose utilization went to lactate formation during exercise, and 20% of the blood lactate appearance came from blood glucose, with the balance presumably coming from muscle glycogen.(ABSTRACT TRUNCATED AT 250 WORDS)

Myocardial metabolism of free fatty acids. Studies with 14C-labeled substrates in humans.

Free fatty acids are considered to be the major energy source for the myocardium. To investigate the metabolic fate of this substrate in humans, 24 subjects underwent coronary sinus and arterial catheterization. 13 subjects were healthy volunteers and 11 subjects had symptoms of ischemic heart disease. [1-14C]oleate or [1-14C]palmitate bound to albumin was infused at a constant rate of 25 microCi/h. Oxidation was determined by measuring the 14CO2 production. The data demonstrated that a high percentage (84 +/- 17%) of the palmitate and oleate extracted by the myocardium underwent rapid oxidation. A highly significant correlation was present between the arterial level and the amount oxidized (r = 0.82, P less than 0.001 for palmitate; r = 0.77, P less than 0.001 for oleate). The isotope extraction ratio was greater than the chemical extraction ratio. This difference of 6 +/- 2 nmol/ml of blood in the young normal subjects was significantly less than the 12 +/- 4 nmol/ml observed in the ischemic heart disease patients (P less than 0.001).

Lactate extraction during net lactate release in legs of humans during exercise.

Lactate metabolism was studied in six normal males using a primed continuous infusion of lactate tracer during continuous graded supine cycle ergometer exercise. Subjects exercised at 49, 98, 147, and 196 W for 6 min at each work load. Blood was sampled from the brachial artery, the iliac vein, and the brachial vein. Arteriovenous differences were determined for chemical lactate concentration and L-[1-14C]-lactate. Tracer-measured lactate extraction was determined from the decrease in lactate radioactivity per volume of blood perfusing the tissue bed. Net lactate release was determined from the change in lactate concentration across the tissue bed. Total lactate release was taken as the sum of tracer-measured lactate extraction and net (chemical) release. At rest the arms and legs showed tracer-measured lactate extraction, as determined from the isotope extraction, despite net chemical release. Exercise elicited an increase in both net lactate release and tracer-measured lactate extraction by the legs. For the legs the total lactate release (net lactate release + tracer-measured lactate extraction) was roughly equal to twice the net lactate release under all conditions. The tracer-measured lactate extraction by the exercising legs was positively correlated to arterial lactate concentration (r = 0.81, P less than 0.001) at the lower two power outputs. The arms showed net lactate extraction during exercise, which was correlated to the arterial concentration (r = 0.86). The results demonstrate that exercising skeletal muscle extracts a significant amount of lactate during net lactate release and that the working skeletal muscle appears to be a major site of blood lactate removal during exercise.

Systemic lactate kinetics during graded exercise in man.

To investigate the relationships between oxygen consumption (VO2) and the rates of systemic lactate appearance (Ra) and disappearance (Rd), six healthy males were studied at rest and during continuous graded exercise using a primed continuous infusion of lactate tracer. Subjects exercised for 6 min at 300, 600, 900, and 1,200 kg . m . min-1. L-(+)-[1-14C]lactate was infused intravenously, and arterial samples were drawn at rest and every 2 min throughout the exercise period. Ra and Rd were calculated using nonsteady-state equations. At rest Ra and Rd were 14.4 +/- 1.8 and 15.1 +/- 2.2 mumol . kg-1 . min-1, respectively. Near steady-state values were observed toward the end of the first two work loads. Ra and Rd values were 32.8 +/- 2.3 and 37.4 +/- 1.3 mumol . kg-1 . min-1 during min 5 and 6 at 300 kg . m . min-1 and were 59.1 +/- 2.6 and 55.4 +/- 2.3 mumol . kg-1 . min-1 during min 5 and 6 at 600 kg . m . min-1. Ra was significantly greater than Rd at both 900 and 1,200 kg . m . min-1. Ra and Rd averaged 145.4 +/- 10.5 and 110.2 +/- 5.6 mumol . kg-1 . min-1, respectively, during the last 2 min at 900 kg . m . min-1, and 309.4 +/- 20.8 and 169.7 +/- 10.6 mumol . kg-1 . min-1, respectively, at 1,200 kg . m . min-1.(ABSTRACT TRUNCATED AT 250 WORDS)

Metabolic fate of extracted glucose in normal human myocardium.

Glucose is an important substrate for myocardial metabolism. This study was designed to determine the effect of circulating metabolic substrates on myocardial glucose extraction and to determine the metabolic fate of glucose in normal human myocardium. Coronary sinus and arterial catheters were placed in 23 healthy male volunteers. [6-14C]Glucose was infused as a tracer in 10 subjects. [6-14C]Glucose and [U-13C]lactate were simultaneously infused in the other 13 subjects. Simultaneous blood samples were obtained for chemical analyses of glucose, lactate, and free fatty acids and for the the isotopic analyses of glucose and lactate. Glucose oxidation was assessed by measuring myocardial 14CO2 production. The amount of glucose extracted and oxidized by the myocardium was inversely correlated with the arterial level of free fatty acids (r = -0.71; P less than 0.0001). 20% (range, 0-63%) of the glucose extraction underwent immediate oxidation. Chemical lactate analysis showed a net extraction of 26.0 +/- 16.4%. However, isotopic analysis demonstrated that lactate was being released by the myocardium. In the 13 subjects receiving the dual-carbon-labeled isotopes, the lactate released was 0.09 +/- 0.04 mumol/ml and 49.5 +/- 29.5% of this lactate was from exogenous glucose. This study demonstrates that the circulating level of free fatty acids plays a major role in determining the amount of glucose extracted and oxidized by the normal human myocardium. Only 20.1 +/- 19.4% of the glucose extracted underwent oxidation, and 13.0 +/- 9.0% of the glucose extracted was metabolized to lactate and released by the myocardium. Thus, 60-70% of the glucose extracted by the normal myocardium is probably stored as glycogen in the fasting, resting state.

Potentiation by nifedipine and diltiazem of the hypotensive response after contrast angiography.

Arterial hypotension has been demonstrated after left ventriculography using currently available ionic contrast agents. This adverse hemodynamic response is significantly decreased with the newer nonionic contrast agents. Calcium channel antagonists also produce a hypotensive response. The potentially accentuated hypotensive response after bolus contrast angiography in patients receiving the calcium antagonists nifedipine and diltiazem was evaluated. Three contrast agents were compared: two ionic agents (Renografin-76 and Hypaque-76) and a nonionic agent (iopamidol). The hemodynamic response after left ventriculography was assessed in 125 patients, 65 receiving nifedipine or diltiazem and 60 not receiving these drugs. Baseline clinical characteristics were similar in all patient groups. The hypotensive response was significantly greater after left ventriculography with the ionic agents than with the nonionic agent. In those patients receiving nifedipine or diltiazem, the hypotensive response after bolus contrast angiography using the ionic agents occurred earlier after contrast injection (4.2 +/- 3.1 versus 12.9 +/- 6.0 seconds, p less than 0.0001), was more profound (maximal decrease in systolic arterial pressure, 48.5 +/- 13.9 versus 36.9 +/- 13.1 mm Hg, p less than 0.001) and was more prolonged (62.3 +/- 11.0 versus 36.4 +/- 12.0 seconds, p less than 0.0001) than in patients not receiving these drugs. A comparison of the two ionic contrast agents showed no significant difference in the hypotensive response. There was no difference in the hemodynamic response after angiography among patients receiving iopamidol alone and those receiving iopamidol and calcium antagonists. Thus, patients receiving the calcium antagonists diltiazem and nifedipine and undergoing left ventriculography with ionic contrast agents are at added risk for accentuation and prolongation of the hypotensive response.

Noise mode response at peak exercise in a DDD pacemaker.

The noise sampling period has been recognized as a cause of apparent sensing malfunction in demand pacemakers. Physiologic signals as well as external electromagnetic interference can cause certain demand pacemakers to remain refractory and escape asynchronously at a specified rate. In this case, noise mode reversion pacing at the programmed lower rate limit of a Cordis 415A DDD pacemaker was observed during exercise when P-waves fell within the noise sampling period.

Absence of myocardial biochemical toxicity with a nonionic contrast agent (iopamidol).

To evaluate the myocardial metabolic effects of a new nonionic contrast agent, iopamidol, a randomized, double-blind study was performed comparing iopamidol with sodium meglumine diatrizoate (Renografin-76) in 23 patients with ischemic heart disease. Coronary sinus and arterial metabolic samples were obtained prior to and during the 20-minute period following the contrast left ventriculogram. Ten patients received iopamidol and 13 received Renografin-76. The chemical lactate extraction in the iopamidol group was 13 +/- 9% prior to left ventriculography and 17 +/- 12% following the contrast injection (p less than 0.005). In the Renografin-76 group, the lactate extraction was 23 +/- 13% and decreased significantly to 12 +/- 24% following the ventriculogram (p less than 0.01). In a subset of these patients (n = 10), [1-(14)C] lactate was infused as a tracer to quantitate the amount of lactate released by the myocardium. [1-(14)C] lactate analysis demonstrated that the fall in lactate extraction ratio following Renografin-76 was due to an increase in myocardial lactate release. In the Renografin-76 group there was a 53 +/- 37% increase in lactate release at 10 minutes after contrast agent injection (p less than 0.005), while in the iopamidol patients there was no significant change in lactate release following contrast ventriculography. The increase in lactate release in the Renografin-76 group suggests that myocardial ischemia is induced with this ionic contrast agent. In comparison, the nonionic contrast agent is less toxic to the myocardium and is not associated with the biochemical changes of cellular ischemia.