Results of the study to determine rotablator and transluminal angioplasty strategy (STRATAS).

Rotational atherectomy is used to debulk calcified or complex coronary stenoses. Whether aggressive burr sizing with minimal balloon dilation (<1 atm) to limit deep wall arterial injury improves results is unknown. Patients being considered for elective rotational atherectomy were randomized to either an "aggressive" strategy (n = 249) (maximum burr/artery >0.70 alone, or with adjunctive balloon inflation < or = 1 atm), or a "routine" strategy (n = 248) (maximum burr/artery < or =0.70 and routine balloon inflation > or =4 atm). Patient age was 62 +/- 11 years. Fifty-nine percent routine and 60% aggressive strategy patients had class III to IV angina. Fifteen percent routine and 16% aggressive strategy patients had a restenotic lesion treated; lesion length was 13.6 versus 13.7 mm. Reference vessel diameter was 2.64 mm. Maximum burr size (1.8 vs 2.1 mm), burr/artery ratio (0.71 vs 0.82), and number of burrs used (1.9 vs 2.7) were greater for the aggressive strategy, p <0.0001. Final minimum lumen diameter and residual stenosis were 1.97 mm and 26% for the routine strategy versus 1.95 mm and 27% for the aggressive strategy. Clinical success was 93.5% for the routine strategy and 93.9% for the aggressive strategy. Creatine kinase-myocardial band (CK-MB) was >5 times normal in 7% of the routine versus 11% of the aggressive group. CK-MB elevation was associated with a decrease in rpm of >5,000 from baseline for a cumulative time >5 seconds, p = 0.002. At 6 months, 22% of the routine patients versus 31% of the aggressive strategy patients had target lesion revascularization. Angiographic follow-up (77%) showed minimum lumen diameter to be 1.26 mm in the routine group versus 1.16 mm in the aggressive group, and the loss index 0.54 versus 0.62. Dichotomous restenosis was 52% for the routine strategy versus 58% for the aggressive strategy. Multivariable analysis indicated that left anterior descending location (odds ratio 1.67, p = 0.02) and operator-reported excessive speed decrease >5,000 rpm (odds ratio 1.74, p = 0.01) were significantly associated with restenosis. Thus, the aggressive rotational atherectomy strategy offers no advantage over more routine burr sizing plus routine angioplasty. Operator technique reflected by an rpm decrease of >5,000 from baseline is associated with CK-MB elevation and restenosis.

Long-term clinical follow-up of patients treated with the coronary rotablator: a single-center experience.

The acute angiographic and long-term clinical outcomes of a consecutive series of patients treated with the coronary rotablator at a single center are described. The patient population was a high-risk population, with significant instances of unstable angina or acute myocardial infarctions (MI) on presentation (75.5%), three-vessel coronary artery disease (27.5%), congestive heart failure (23.8%), and diabetes (39%). The coronary anatomy was also complex, with 79.3% of lesions treated being National Heart Lung and Blood Institute (NHLBI) class B or C. The maximum burr:artery ratio averaged 0.79+/-0.11. The maximum balloon:artery ratio averaged 1.19+/-0.17. Acute procedural success was 90%. The reference vessel diameter was 2.72 mm +/-0.54 mm. The average minimum luminal diameter (MLD) preprocedure was 0.87+/-0.31 mm. The average MLD postprocedure was 2.01+/-0.54 mm. The acute gain averaged 1.14+/-0.51 mm. Urgent coronary artery bypass grafting was required in 1% of patients. Subendocardial infarctions occurred in 8.5% of patients, and abrupt closure postprocedure while in hospital occurred in 1% of patients. Reinterventions or coronary artery bypass grafting (CABG) in hospital occurred in only 3.5% of patients; 96% of patients were available for a long-term clinical follow-up. Repeat coronary interventions for target lesion revascularizations were required in 17.4% of patients, coronary artery bypass grafting for target lesion revascularization was necessary in 9.5% of patients, and the combined target lesion revascularization rate was 25.3% at 1 year. Subsequent Q-wave myocardial infarctions or cardiac death occurred in 5.7% of patients at 1 year. Event-free survival was 75.1% at 6 months and 69.9% at 1 year. The strongest predictor of subsequent target lesion revascularization was lesion length (P=0.034) and not the postprocedure MLD (P=0.41). Most major adverse clinical events occurred within the first 4 months and greater than 90% of all major adverse clinical events occurred within the first 6 months. The coronary rotablator was able to achieve a high degree of clinical success in a high-risk patient population with complex anatomy. Most major adverse clinical events occurred early (<6 months) and were comprised principally of target lesion revascularizations. The overall target lesion revascularization rates and combined major adverse clinical event rates are favorable, given the complex anatomy and the high proportion of diabetics, females, and multivessel disease patients treated in this series.

Remodeling after directional coronary atherectomy (with and without adjunct percutaneous transluminal coronary angioplasty): a serial angiographic and intravascular ultrasound analysis from the Optimal Atherectomy Restenosis Study.

OBJECTIVES: The intravascular ultrasound (IVUS) substudy of OARS (Optimal Atherectomy Restenosis Study) was designed to assess the mechanisms of restenosis after directional coronary atherectomy (DCA). BACKGROUND: Recent serial IVUS studies have indicated that late lumen loss after interventional procedures was determined primarily by the direction and magnitude of arterial remodeling, not by cellular proliferation. METHODS: Complete quantitative coronary angiography (QCA) and IVUS were obtained in 104 patients before and after intervention and during follow-up. All studies were performed after administration of 200 microg of intracoronary nitroglycerin. Angiographic measurements included minimum lumen diameter (MLD), interpolated reference diameter and diameter stenosis (DS). Intravascular ultrasound measurements included lesion and reference external elastic membrane (EEM), lumen and plaque+media cross-sectional area (CSA). The axial location of the lesion site was at the smallest follow-up lumen CSA; the reference segment was the most normal-looking cross section within 10 mm proximal to the lesion but distal to any major side branch. Results are reported as mean +/- one standard deviation. RESULTS: The QCA reference decreased from 3.51 +/- 0.46 mm to 3.22 +/- 0.44 mm; the MLD decreased from 3.22 +/- 0.47 mm to 2.03 +/- 0.72 mm; and the DS increased from 8 +/- 10% to 38 +/- 20%. On IVUS, the decrease in lumen CSA (from 8.8 +/- 2.5 mm2 to 5.5 +/- 4.0 mm2) was associated with a significant decrease in EEM (from 19.7 +/- 5.6 mm2 to 16.9 +/- 6.2 mm2); there was no significant increase in P+M (from 10.9 +/- 4.2 mm2 to 11.3 +/- 3.9 mm2). A change in lumen correlated with a change in EEM (r = 0.790, p < 0.0001), not with a change in P+M (r = 0.133, p = 0.2258). A decrease in reference EEM (from 19.1 +/- 7.7 mm2 to 17.6 +/- 8.0 mm2) also correlated with a decrease in lesion EEM (r = 0.665, p < 0.0001). Results in restenotic lesions were similar. CONCLUSION: Restenosis after optimal DCA is caused primarily by a decrease in EEM CSA that extends into contiguous reference segments.

'Optimal' directional coronary atherectomy: final results of the Optimal Atherectomy Restenosis Study (OARS).

BACKGROUND: Previous clinical trials of directional coronary atherectomy (DCA) have failed to show significant improvement in early or late outcomes compared with balloon angioplasty (PTCA). The present study tested the hypothesis that more aggressive "optimal" atherectomy could be performed safely to produce larger initial lumen diameters and a lower late restenosis rate. METHODS AND RESULTS: The present study was a prospective multicenter registry of consecutive patients undergoing optimal DCA of de novo or restenotic lesions in 3.0- to 4.5-mm native coronary arteries. Optimal DCA was defined as using a 7F atherectomy device and adjunctive PTCA if necessary to achieve a < 15% residual stenosis. Six-month angiographic and 1-year clinical follow-up was planned in all patients. A total of 199 patients with 213 lesions met eligibility criteria for enrollment. Short-term procedural success was achieved in 97.5%, with a major complication rate (death, emergency bypass surgery, or Q-wave myocardial infarction [MI]) of 2.5%. There were no early deaths. Non-Q-wave MI (CK-MB > 3 times normal) occurred in 14% of patients. Mean reference vessel diameter was 3.28 mm. Mean diameter stenosis was reduced from 63.5% to a final stenosis of 7%. Late 1-year clinical follow-up revealed one cardiac death and a target lesion revascularization rate of 17.8%. The angiographic restenosis rate at 6 months was 28.9%, with the major predictor of restenosis being a smaller postprocedure lumen diameter. CONCLUSIONS: Optimal DCA produced a low residual percent diameter stenosis and a lower restenosis rate than seen in previous trials without an increase in early or late major adverse events.

Dichloroacetate as metabolic therapy for myocardial ischemia and failure.

This article critically reviews the pharmacologic effects of the investigational drug dichloroacetate (DCA), which activates the mitochondrial pyruvate dehydrogenase enzyme complex in cardiac tissue and thus preferentially facilitates aerobic oxidation of carbohydrate over fatty acids. The pharmacologic effects of DCA are compared with other interventions, such as glucose plus insulin, inhibitors of long chain fatty acid oxidation and adenosine, that are also thought to exert their therapeutic effects by altering myocardial energy metabolism. Short-term clinical and laboratory experiments demonstrate that intravenous DCA rapidly stimulates pyruvate dehydrogenase enzyme complex activity and, therefore, aerobic glucose oxidation in myocardial cells. Typically these effects are associated with suppression of myocardial long chain fatty acid metabolism and increased left ventricular stroke work and cardiac output without changes in coronary blood flow or myocardial oxygen consumption. Although long-term studies are lacking, short-term parenteral administration of DCA appears to be safe and capable of significantly improving myocardial function in conditions of limited oxygen availability by increasing the efficient conversion of myocardial substrate fuels into energy.

Surgical management of instrumentation-induced coronary artery dissection.

The mechanism of instrument-induced coronary artery dissections (IICDs) is briefly presented. Depending on the coronary anatomy, three different situations that may occur are distinguished: (1) major coronary branches between the site of dissection and planned anastomosis; (2) no important collaterals at the same location; and (3) perforation of the coronary artery. Surgical methods applicable to each for the correction of these situations is presented.

Natural history and course of acquired lactic acidosis in adults. DCA-Lactic Acidosis Study Group.

STUDY OBJECTIVE: To determine the pathogenesis and clinical course of lactic acidosis in adults receiving standard medical care. DESIGN: Placebo arm of a 5-year prospective, randomized, blinded study comparing placebo and dichloroacetate as specific lactate-lowering therapy. Each patient received intravenous saline placebo in addition to conventional therapy. SETTING: Intensive care units of 10 tertiary care hospitals in North America. PATIENTS: One hundred twenty-six patients with lactic acidosis, defined as arterial blood lactate greater than or equal to 5 mmol/L and either arterial pH of less than or equal to 7.35 or base deficit greater than 6 mmol/L. Patients were followed for up to 6 months. MEASUREMENTS AND MAIN RESULTS: Mean +/- SD demographic entry data for 126 patients included: age 56 +/- 17 years, lactate 10.4 +/- 5.5 mmol/L, pH 7.24 +/- 0.14, calculated base deficit 14.1 +/- 5.4, arterial systolic blood pressure 103 +/- 29 mm Hg, Glasgow Coma score 7.9 +/- 4.9, and APACHE II score 19.2 +/- 8.1. Despite fluids and pressors, 32% of patients had systolic blood pressures of less than or equal to 90 mm Hg in association with sepsis (59%), cardiac failure (18%), or hemorrhage (18%). The most common causes of lactic acidosis in the absence of shock were sepsis (49%), liver disease (15%), and respiratory failure (12%). The median survival was 38.5 hours. Survival at 24 hours was 59%. Arterial pH predicted 24-hour survival better than base deficit or bicarbonate level. Percent survival was 41% at 3 days and 17% at 30 days. Only 21% of patients survived to leave the intensive care unit, and 17% were discharged from the hospital. In patients receiving sodium bicarbonate, neither acid-base nor hemodynamic status improved. CONCLUSIONS: In this first prospective study of the clinical course of acute lactic acidosis in adults, nearly all subjects had both hemodynamic and nonhemodynamic (metabolic) underlying causes, many of which independently predicted survival and most of which were refractory to standard care.

Improved hemodynamic function and mechanical efficiency in congestive heart failure with sodium dichloroacetate.

OBJECTIVES: The purpose of this study was to determine whether sodium dichloroacetate improves hemodynamic performance and mechanical efficiency in congestive heart failure. BACKGROUND: Congestive heart failure is associated with impaired hemodynamic performance and reduced mechanical efficiency. Dichloroacetate stimulates pyruvate dehydrogenase activity by inhibition of pyruvate dehydrogenase kinase, which results in inhibition of free fatty acid metabolism and stimulation of high respiratory quotient glucose and lactate consumption by the heart. Facilitation of glucose and lactate consumption with dichloroacetate should improve mechanical efficiency of the failing ventricle. METHODS: Ten patients with New York Heart Association functional class III to IV congestive heart failure were studied. Dichloroacetate (50 mg/kg body weight) was administered intravenously for 30 min, with measurements of hemodynamic variables, coronary sinus blood flow and blood gas, glucose and lactate levels for 2 h. The same patients were also given dobutamine (5 to 12.5 micrograms/kg per min) for comparison. RESULTS: Therapeutic levels of dichloroacetate were achieved (100 to 160 micrograms/liter of plasma). Myocardial consumption of lactate was stimulated from 29% to 37.4%. Forward stroke volumes increased (+5.3 ml/beat, p < 0.02), as did left ventricular stroke work (+1.8 g-m/m2 per beat, p < 0.02) and left ventricular minute work (from 1.38 to 1.55 kg-m/m2 per min, p < 0.01). Myocardial oxygen consumption decreased (from 19.3 to 16.5 ml/min, p = 0.06) as left ventricular minute work increased. Left ventricular mechanical efficiency thus improved from 15.2% to 20.6% (p = 0.03). Dobutamine administration resulted in the opposite trend with respect to myocardial lactate extraction (from 34% to 15.3%, p < 0.02). Stroke volume increased (+7.4 ml/beat, p = NS vs. dichloroacetate), as did left ventricular minute work (from 1.29 to 1.59 g-m/m2 per min, p < 0.01 vs. dichloroacetate) and myocardial oxygen consumption (from 18.6 to 21.0 ml/min, p = 0.06 vs. dichloroacetate). Left ventricular mechanical efficiency did not change with dobutamine administration (from 16.4% to 15.8%, p = NS). CONCLUSIONS: Dichloroacetate administration stimulates myocardial lactate consumption and improves left ventricular mechanical efficiency. Forward stroke volume and left ventricular minute work increase significantly, with a simultaneous reduction in myocardial oxygen consumption. Dobutamine administration results in similar hemodynamic improvements but with no change in left ventricular mechanical efficiency and with opposite effects on lactate metabolism. The opposing metabolic actions, yet similar hemodynamic responses, of dichloroacetate and dobutamine suggest that these agents may be complementary in the treatment of congestive heart failure.

Mobile cardiac catheterization registry: report of the first 1,001 patients.

The purpose of this study was to evaluate prospectively the efficacy and safety of mobile cardiac catheterization. Mobile cardiac catheterization was introduced into clinical practice in 1989, but there has been no systematic study of its performance and safety. A registry was established in 1989 to monitor outcomes with mobile cardiac catheterization and is reported here. Patients were screened for eligibility for mobile cardiac catheterization using the joint AHA/ACC criteria for outpatient angiography. Eligible patients underwent mobile catheterization at eight hospitals within 120 miles of the base tertiary center. Helicopter evacuation services were available at each mobile site. The indications, findings, dispositions, and complications of mobile cardiac catheterization were recorded by means of a checklist, telephone follow-up and chart review. A total of 1,001 consecutive patients were entered into the registry in the first 20 months of operation, including 436 females and 565 males aged 22 to 84 years. Angina (Canadian Classes II-IV) was the most frequent primary indication for catheterization (46.4%), followed by atypical chest pain (36.9%), or a positive exercise stress test (25.6%). Infrequent indications for catheterization included a history of myocardial infarction (5.6%), congestive heart failure (7.1%), arrhythmias (4.1%), and valvular heart disease (0.7%). Catheterization was accomplished in 99.9% of patients. Angiographically normal studies were observed in 22.8%, and mild (< or = 50%) coronary artery disease in 13.6% of patients.(ABSTRACT TRUNCATED AT 250 WORDS)

Mobile cardiac catheterization: comparison with outpatient and inpatient catheterization at tertiary facilities.

The study group included 1,553 consecutive patients from areas serviced by our mobile catheterization laboratories: 719 procedures were performed in the mobile unit at their local hospitals, 277 were performed at a tertiary hospital with less than a 24 hr hospital stay, and 557 were performed at a tertiary hospital as inpatients. The indications for mobile catheterization were predominantly atypical chest pain, angina pectoris, or positive treadmill stress test, whereas patients with less than 24 hr hospitalization at the tertiary center had their catheterization performed for additional reasons. The majority of the inpatient indications were for recent myocardial infarction or unstable angina. Using the American College of Cardiology/American Heart Association (ACC/AHA) criteria for outpatient catheterization, the mobile catheterizations were performed safely with a complication rate of only 0.7% compared to a complication rate of 3.1% for inpatients demonstrating that a low risk group of patients can be prospectively identified and catheterized safely in the mobile setting. An extremely high risk group of patients with ongoing unstable angina and recent myocardial infarction was also identified which should undergo catheterization only at a tertiary center.

Importance of oxygen-haemoglobin binding to oxygen transport in congestive heart failure.

OBJECTIVE: To assess the importance of 2,3-diphosphoglycerate (2,3-DPG) and oxygen-haemoglobin binding to oxygen transport in patients with congestive heart failure. METHODS: In 30 patients with severe congestive heart failure, arterial, mixed venous, and coronary sinus venous blood concentrations of 2,3-DPG were measured and systemic output and coronary sinus blood flow were measured by a thermodilution technique. Oxygen-haemoglobin affinity was expressed as the oxygen tension in mm Hg at which blood is 50% saturated with oxygen (P50). RESULTS: Compared with normal values, 2,3-DPG was high in arterial blood (2.58 mumol/ml, p = 0.01; 20.8 mumol/g haemoglobin, p < 0.0001). Significant gradients between arterial, mixed venous, and coronary sinus blood 2,3-DPG concentrations were also found (mixed venous = 2.40 mumol/ml, p = 0.05 v arterial blood; coronary sinus venous blood = 2.23 mumol/ml, p < 0.04 v arterial blood). P50 was correspondingly high compared with the accepted normal value (mean 29.7 mm Hg, normal 26.6 mm Hg, p < 0.001). Systemic oxygen transport (351 ml O2/min/m2) varied directly with the forward cardiac index (r = 0.89, p < 0.0001). There was no relation between systemic oxygen transport and arterial oxygen content. Similarly, myocardial oxygen transport was found to vary directly with coronary sinus blood flow. Calculations of changes in cardiac index and coronary sinus blood flow at normal oxygen-haemoglobin binding indicate that a considerable increase in cardiac index and coronary blood flow would be required to maintain similar systemic and myocardial oxygen transport. CONCLUSIONS: In patients with severe heart failure increased 2,3-DPG and reduced oxygen-haemoglobin binding may be compensatory mechanisms that maintain adequate systemic and delivery of oxygen to myocardial tissue.

Balloon rupture during peripheral stent implantation: a new technique for balloon retrieval.

Balloon rupture is a known technical problem with implantation of vascular stents. In most cases, the ruptured balloon can be retrieved with simple maneuvers. In this case report, a peripheral balloon became trapped within an undeployed peripheral vascular stent and could not be removed by application of standard maneuvers. A novel approach to balloon retrieval was devised and undertaken with success.

A controlled clinical trial of dichloroacetate for treatment of lactic acidosis in adults. The Dichloroacetate-Lactic Acidosis Study Group.

BACKGROUND: Mortality is very high in lactic acidosis, and there is no satisfactory treatment other than treatment of the underlying cause. Uncontrolled studies have suggested that dichloroacetate, which stimulates the oxidation of lactate to acetyl-coenzyme A and carbon dioxide, might reduce morbidity and improve survival among patients with this condition. METHODS: We conducted a placebo-controlled, randomized trial of intravenous sodium dichloroacetate therapy in 252 patients with lactic acidosis; 126 were assigned to receive dichloroacetate and 126 to receive placebo. The entry criteria included an arterial-blood lactate concentration of > or = 5.0 mmol per liter and either an arterial-blood pH of < or = 7.35 or a base deficit of > or = 6 mmol per liter. The mean (+/- SD) arterial-blood lactate concentrations before treatment were 11.6 +/- 7.0 mmol per liter in the dichloroacetate-treated patients and 10.4 +/- 5.5 mmol per liter in the placebo group, and the mean initial arterial-blood pH values were 7.24 +/- 0.12 and 7.24 +/- 0.13, respectively. Eighty-six percent of the patients required mechanical ventilation, and 74 percent required pressor agents, inotropic drugs, or both because of hypotension. RESULTS: The arterial-blood lactate concentration decreased 20 percent or more in 83 (66 percent) of the 126 patients who received dichloroacetate and 45 (36 percent) of the 126 patients who received placebo (P = 0.001). The arterial-blood pH also increased more in the dichloroacetate-treated patients (P = 0.005). The absolute magnitude of the differences was small, however, and they were not associated with improvement in hemodynamics or survival. Only 12 percent of the dichloroacetate-treated patients and 17 percent of the placebo patients survived to be discharged from the hospital. CONCLUSIONS: Dichloroacetate treatment of patients with severe lactic acidosis results in statistically significant but clinically unimportant changes in arterial-blood lactate concentrations and pH and fails to alter either hemodynamics or survival.

Metabolic and hemodynamic consequences of sodium bicarbonate administration in patients with heart disease.

PURPOSE: The use of sodium bicarbonate (NaHCO3) in cardiopulmonary arrest has been questioned, but the effects of NaHCO3 in patients with heart disease are not known. We therefore prospectively evaluated the effects of NaHCO3 in patients with congestive heart failure. PATIENTS AND METHODS: Ten patients received NaHCO3 and control infusions of equimolar sodium chloride (NaCl). Measurements were made of blood gases, 2,3-diphosphoglyceric acid (2,3-DPG), glucose, lactate, cardiac hemodynamics, and oxygen consumption. RESULTS: The arterial oxygen tension (pO2) fell an average of 10 mm Hg after NaHCO3 administration in patients with congestive heart failure, whereas it rose with NaCl (p less than 0.005). Myocardial oxygen consumption decreased by 17% (p less than 0.002) without an accompanying change in oxygen demand. Systemic oxygen consumption fell by 21%. Red blood cell 2,3-DPG levels were elevated at baseline, but did not change with NaHCO3 administration. The oxygen pressure at 50% hemoglobin saturation (P50) was correspondingly elevated at baseline in these patients and decreased significantly with NaHCO3 (Bohr effect) (p less than 0.003). The arterial and mixed venous carbon dioxide tensions increased with NaHCO3 but decreased with NaCl administration (p less than 0.05). Blood glucose concentrations fell by 1.7 mmol/L with NaHCO3 (p less than 0.003) and blood lactate concentrations increased uniformly (p less than 0.001). Three patients developed net myocardial lactate generation during NaHCO3 administration; two of these three developed symptoms of angina. Coronary blood flow did not change with NaHCO3 but increased with NaCl (p less than 0.04). Two patients developed transient pump failure. CONCLUSION: These data demonstrate that NaHCO3 impairs arterial oxygenation and reduces systemic and myocardial oxygen consumption. The decrease in oxygen utilization is associated with anaerobic metabolism, enhanced glycolysis, and elevation of the blood lactate level, and may lead to transient myocardial ischemia in some patients. Thus, the use of NaHCO3 in such patients warrants re-evaluation.

Improved hemodynamic function during hypoxia with Carbicarb, a new agent for the management of acidosis.

Carbicarb is a mixture of Na2CO3/NaHCO3 that buffers similarly to NaHCO3, but without net generation of CO2. We studied the effects of carbicarb in an animal preparation of hypoxic lactic acidosis (HLA). HLA was induced by ventilating dogs with an hypoxic gas mixture (8% O2/92% N2). Dogs with HLA (n = 28) were then treated with 2.5 meq/kg of either NaHCO3 or carbicarb over 1 hr. Measurements were made, after 1 hr of hypoxia and 1 hr of therapy, of: cardiac hemodynamics, blood gases, liver intracellular pH (pHi), oxygen consumption, and regional lactate production. After therapy, the arterial pH rose with carbicarb (7.22 to 7.27, p less than .01), and fell with NaHCO3 (7.18 to 7.13, p less than .01). Mixed venous PCO2 did not change with carbicarb but increased with NaHCO3 (p less than .05). Arterial lactates stabilized with carbicarb but rose with NaHCO3 (by 3.1 mmol/liter, p less than .005). Lactate use by muscle, gut, and liver all improved with carbicarb and decreased with NaHCO3. The liver pHi (normal = 6.99, hypoxia = 6.80) improved with carbicarb (to 6.92), but decreased further with NaHCO3 (to 6.40). Muscle O2 consumption rose with carbicarb, whereas it decreased with NaHCO3. Arterial pressure fell less with carbicarb (-12 vs -46 mm Hg, p less than .006) and the cardiac output was stable with carbicarb but decreased with NaHCO3 (from 143 to 98 ml/kg/min, p less than .004). Stroke volume also improved with carbicarb but there was no change in pulmonary capillary wedge pressure, suggesting that carbicarb had a beneficial effect on myocardial contractility.(ABSTRACT TRUNCATED AT 250 WORDS)