Silent myocardial ischemia: hemodynamic changes during dynamic exercise in patients with proven coronary artery disease despite absence of angina pectoris.

The hemodynamic changes during exercise occurring in 36 patients with proven coronary artery disease (10 without and 26 with previous myocardial infarction) who tolerated the stress test without angina were analyzed and compared with changes observed in a control group of 36 carefully matched patients whose exercise was limited by angina. All patients were exercised to the same extent, reaching a similar rate-pressure product at the end of the stress test (19,508 +/- 4,828 [SD] versus 19,247 +/- 4,117 beats/min X mm Hg [NS] in the study and control groups without prior infarction, and 19,665 +/- 3,950 versus 17,701 +/- 4,600 beats/min X mm Hg [NS] in the respective groups with infarction). In all groups left ventricular end-diastolic pressure increased from rest to exercise (from 18 +/- 4 to 36 +/- 11 and from 13 +/- 5 to 29 +/- 9 mm Hg, respectively, in the study and control groups without prior infarction and from 17 +/- 7 to 32 +/- 13 and from 19 +/- 7 to 36 +/- 9 mm Hg in the respective groups with prior infarction). Left ventricular ejection fraction decreased (from 59 +/- 7 to 50 +/- 15 and from 60 +/- 4 to 52 +/- 9% in the study and control groups without prior infarction and from 54 +/- 9 to 47 +/- 10 and 55 +/- 9 to 50 +/- 4% in the respective groups with prior infarction). Whereas the changes from rest to exercise were highly significant within each group, no significant differences were noted between the corresponding groups. Regional de novo hypokinesia appeared in all patients without prior infarction and in 25 and 22 patients, respectively, of the groups with prior infarction. Thus, under similar physical stress conditions, comparable hemodynamic changes indicative of ischemia are observed in patients with significant coronary artery lesions with or without previous myocardial infarction irrespective of the occurrence of angina. Therefore, angina pectoris cannot be considered a prerequisite for hemodynamically significant ischemia during exertion.

Left ventricular function before and after diltiazem in patients with coronary artery disease.

Left ventricular contraction, relaxation and diastolic mechanics were investigated before and after intravenous administration of 15 mg of diltiazem in 15 patients with coronary artery disease. High fidelity left ventricular pressure measurements were performed in all 15 patients, with simultaneous biplane cineangiography in 13. The time constant of left ventricular isovolumic pressure decay was calculated from the linear relation of left ventricular pressure and its rate of change with time (negative dP/dt). Frame by frame volume analysis through one cardiac cycle was completed to construct volume-time and pressure-volume curves before and after the administration of diltiazem. After diltiazem, left ventricular peak systolic pressure decreased from 124 to 113 mm Hg (p less than 0.001), while left ventricular end-diastolic pressure and heart rate were not altered. Maximal positive dP/dt also remained unchanged. End-diastolic volume was not changed after diltiazem, but end-systolic volume increased from 48 to 52 ml/m2 (p less than 0.025); as a result, ejection fraction decreased slightly from 57 to 55% (p less than 0.025). The time constant of left ventricular pressure decay and maximal negative dP/dt decreased from 58 to 54 ms (p less than 0.025) and from -1,404 to -1,321 mm Hg/s (p less than 0.025), respectively. Peak early diastolic filling rate increased from 621 to 752 ml/s (p less than 0.01) in association with an increase in filling volume during the first half of diastole from 60 to 68% (p less than 0.005). No consistent displacement of the diastolic pressure-volume curve was observed after diltiazem.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of progression of left ventricular hypertrophy on coronary artery dimensions in aortic valve disease.

OBJECTIVES: The effect of progression of left ventricular hypertrophy on coronary artery dimensions was studied in patients with aortic valve disease. METHODS: Cross-sectional area of the left and right coronary arteries was determined by quantitative coronary arteriography in 12 control subjects and in 10 patients with aortic valve disease at baseline and after a follow-up period of 66 months. RESULTS: The cross-sectional area of the left coronary artery was larger in patients with aortic valve disease than in control subjects (left anterior descending artery 13 vs. 8 mm2, p < 0.001; left circumflex artery 13 vs. 6 mm2, p < 0.001). At the follow-up examination, cross-sectional area of the left coronary artery increased (left anterior descending artery 17 mm2, p < 0.01 vs. baseline; left circumflex artery 15 mm2, p < 0.01 vs. baseline). The cross-sectional area of the right coronary artery was not different in patients with aortic valve disease from that in control subjects. Left ventricular muscle mass was larger in patients with aortic valve disease both at baseline (269 g, p < 0.001) and after follow-up examination (339 g, p < 0.001) than in control subjects (136 g). The appropriateness of coronary artery size with respect to muscle mass was evaluated by normalizing cross-sectional area of the left coronary artery (left anterior descending plus left circumflex artery) per 100 g of left ventricular muscle mass (mm2/100 g). This index was 10.9 mm2/100 g in control subjects, and decreased in subjects with aortic valve disease from 10.3 mm2/100 g at baseline to 8.6 mm2/100 g at the follow-up measurement (p < 0.05 vs. control values). CONCLUSIONS: In patients with aortic valve disease, the progression of left ventricular hypertrophy is associated with an increase in left anterior descending and left circumflex coronary artery dimensions, whereas the size of the right coronary artery remains unchanged. Despite the enlargement of the left coronary artery, the cross-sectional area of the left coronary artery per 100 g of left ventricular muscle mass decreased. Hence, the increase in coronary artery size appears to be inadequate when the severity of left ventricular hypertrophy increases.

Pulsus alternans: its influence on systolic and diastolic function in aortic valve disease.

Left ventricular high fidelity pressure measurements and simultaneous biplane cineangiocardiography were performed in 12 patients with severe aortic valve disease (aortic stenosis in 10, aortic insufficiency in 1 and combined valve lesion in 1). Left ventricular contractility was estimated from maximal rate of left ventricular pressure rise (max dP/dt), peak measured velocity of contractile element shortening (Vpm) and mean circumferential fiber shortening velocity. Left ventricular relaxation was assessed in 12 patients from the time constant (T) of the decline in left ventricular pressure; this constant was calculated from a nonlinear regression analysis of pressure and time (method 1) and a linear regression analysis of pressure and negative dP/dt (method 2). Left ventricular diastolic function was evaluated in nine patients from simultaneous diastolic pressure-volume relations during the strong and weak beats. During pulsus alternans, heart rate and left ventricular end-diastolic pressure remained unchanged, whereas peak systolic pressure (220 versus 204 mm Hg, p less than 0.01) and end-systolic pressure (101 versus 95 mm Hg, p less than 0.01) were significantly higher during the strong beat than during the weak beat. Max dP/dt was alternating (2,162 versus 1,964 mm Hg, p less than 0.05), whereas the peak velocity of contractile element shortening remained unchanged (1.21 versus 1.18 ML/s). Systolic shortening of the left ventricular minor axis was significantly (p less than 0.02) greater during the strong (24%) than during the weak (19%) beat, but that of the left ventricular major axis remained essentially unchanged (8 versus 7%).(ABSTRACT TRUNCATED AT 250 WORDS)

Is there coronary vasoconstriction after intracoronary beta-adrenergic blockade in patients with coronary artery disease.

Vasomotility of normal and stenosed coronary arteries was studied at rest and during supine bicycle exercise in 10 patients with classical exercise-induced angina pectoris receiving 1 mg intracoronary propranolol before the exercise test (propranolol group). Normal and stenotic coronary lumen areas were determined from biplane coronary arteriograms using a computer-assisted system. Measurements were performed at rest, after 1 mg intracoronary propranolol, during supine exercise (89 W for 3.4 minutes) and 5 minutes after 1.6 mg sublingual nitroglycerin administered at the end of the exercise test. The results were compared with previously obtained data on the effect of dynamic exercise on coronary lumen area in 12 patients receiving no medication (control group) and in 6 patients receiving 0.1 mg intracoronary nitroglycerin before the exercise test (nitroglycerin group). In the control group, coronary stenosis area decreased during exercise to 71% of levels at rest (p less than 0.001) whereas normal coronary lumen area increased to 123% of control (p less than 0.01). In the propranolol group both normal (113%, p less than 0.05 versus rest) and stenotic coronary lumen area (122%, p less than 0.05 versus rest) increased during exercise. A similar increase in both normal and stenotic areas was observed during exercise after pretreatment with 0.1 mg intracoronary nitroglycerin (123%, p less than 0.01 and 114%, p = NS versus rest). Sublingual administration of 1.6 mg nitroglycerin at the end of exercise increased coronary stenosis area to 145% (p less than 0.01 versus rest) in the propranolol group and to 115% in the control group (p = NS versus rest). It is concluded that intracoronary administration of propranolol does not potentiate coronary vasoconstriction of the epicardial vessels at rest and during exercise. In contrast, intracoronary propranolol prevents exercise-induced stenosis narrowing either because of reduced myocardial oxygen demand with a lower coronary blood flow resulting in a smaller transstenotic pressure gradient and, thus, a smaller flow-induced fall in stenosis distending pressure; or because of "local" beta-receptor blockade with unopposed distal arteriolar alpha-receptor tone, resulting in a higher poststenotic pressure and, thus, in a greater stenosis distending pressure; or because of a local anesthetic effect of propranolol with a decrease in calcium influx to the coronary smooth musculature.

Long-term follow-up of medical versus surgical therapy for hypertrophic cardiomyopathy: a retrospective study.

In a retrospective analysis 139 patients with hypertrophic cardiomyopathy were followed up for 8.9 years (range 1 to 28 years). Patients were divided into two groups: Group 1 consisted of 60 patients with medical therapy and Group 2 of 79 patients with surgical therapy (septal myectomy). Groups 1 and 2 were subdivided according to the medical treatment. Group 1a received propranolol, 160 mg/day (n = 20); Group 1b verapamil, 360 mg/day (n = 18); and Group 1c, no therapy (n = 22). Group 2a received verapamil, 120 to 360 mg/day, after septal myectomy (n = 17) and Group 2b had no medical therapy after surgery (n = 62). In Group 1, 19 patients died (annual mortality rate 3.6%) and in Group 2, 17 patients died (mortality rate 2.4%, p = NS). Of the patients who died, approximately one half to two thirds in both Groups 1 and 2 died suddenly and the other one half to one third died because of congestive heart failure. The 10 year cumulative survival rate was 67% in Group 1, significantly smaller than that in Group 2 (84%, p less than 0.05). In the subgroups, the 10 year survival rate was 67% in Group 1a, 80% in 1b (p less than 0.05 versus 1a) and 65% in 1c (p less than 0.05 versus 1b). The 10 year survival rate was 100% in Group 2a (p less than 0.05 versus 1a, 1b, 1c) and 78% in Group 2b (p less than 0.05 versus 2a). It is concluded that cumulative survival rate is significantly better in surgically than in medically treated patients.(ABSTRACT TRUNCATED AT 250 WORDS)

Prevention of coronary vasoconstriction by diltiazem during dynamic exercise in patients with coronary artery disease.

Whether exercise-induced vasoconstriction of coronary artery stenoses is modified by the administration of calcium antagonists was examined in 14 patients with classic angina pectoris. In this group the effect of intracoronary diltiazem (2 to 3 mg) on luminal area was evaluated in normal and stenotic segments of epicardial coronary arteries during symptom-limited supine exercise. The luminal area of a normal and a stenotic coronary artery segment was determined by quantitative coronary arteriography with a computer-assisted system. Patients were studied at rest, 6 min after 2 to 3 mg of intracoronary diltiazem, during supine bicycle exercise (96 W) and 5 min after sublingual administration of 1.6 mg nitroglycerin. Heart rate, mean pulmonary and aortic pressure as well as the percent change of both normal and stenotic luminal area were determined. Intracoronary administration of diltiazem was associated with mild dilation of both normal (19%, p less than 0.01) and stenotic coronary luminal area (11%, p less than 0.05). During subsequent exercise, luminal area of the stenotic vessel segment increased by 23% (p less than 0.001) and that of the normal vessel segment by 24% (p less than 0.001), whereas in a previously reported control group, luminal area of the stenotic vessel segment decreased by 29% during exercise. After sublingual administration of nitroglycerin, the luminal area of both the normal and the stenotic vessel segment increased further by 19% (p less than 0.01) and 22% (p less than 0.01), respectively, compared with the values after intracoronary administration of diltiazem.(ABSTRACT TRUNCATED AT 250 WORDS)

Left ventricular pressure-length relation during exercise-induced ischemia.

The pressure-length relation in normal and ischemic segments was analyzed with use of left ventriculography and simultaneous micromanometry during supine exercise in 9 normal subjects and 12 patients with effort angina. Segmental analysis was done in the right anterior oblique projection using a long axis with three perpendicular, equidistant chords. The apical segment in the 12 patients with coronary artery disease represented the ischemic region. In 5 of the 12 patients with coronary artery disease, the basal segment that showed no exercise-induced deterioration in wall motion was used as an intrapatient control (nonischemic segment). In the 12 patients with coronary artery disease, left ventricular ejection fraction decreased (from 65% to 50%, p less than 0.001), end-diastolic pressure increased (from 24 to 40 mm Hg, p less than 0.001) and the lowest diastolic filling pressure increased (from 9 to 22 mm Hg, p less than 0.001) during exercise-induced ischemia. In normal subjects, ejection fraction increased (from 64% to 70%, p less than 0.01) with unchanged end-diastolic pressure, whereas the lowest diastolic filling pressure decreased during exercise (from 9 to 3 mm Hg, p less than 0.01). Global left ventricular diastolic pressure-volume curves showed an upward and rightward shift during exercise-induced ischemia. Regional pressure-length curves of both nonischemic (n = 5) and ischemic (n = 12) segments were shifted upward in early diastole, but moved to a higher portion of the rest pressure-length curve without an upward shift during mid- to end-diastole. In contrast, the apical segment in normal subjects showed a downward shift during exercise.(ABSTRACT TRUNCATED AT 250 WORDS)

Systolic function during exercise in patients with coronary artery disease.

Global and regional systolic function during exercise were studied at cardiac catheterization with biplane cineangiography and micromanometer pressures in three groups of patients: an ischemia group (n = 22) with exercise-induced asynergy from coronary artery disease, a control group with no or minimal cardiovascular disease (n = 5) and a "scar" group (n = 5) with prior infarction and no new asynergy with exercise. Ventricular emptying curves at rest did not distinguish patients with coronary artery disease from control subjects. During exercise, end-systolic volume increased in all patients in the ischemia group; ejection fraction decreased from 62 to 51% p less than 0.001) despite an increased end-diastolic volume. Stroke volume decreased from 65 to 58 ml/m2 (p less than 0.001) and limited the average increase in cardiac index to 65%. The scar group had no decrease in stroke volume, but end-systolic volume failed to decrease during exercise, as it did in all control subjects (35 to 28 ml/m2, p less than 0.05). An exercise-induced decrease in peak left ventricular pressure in five patients (23%) in the ischemia group was not accompanied by more severe or extensive ischemia as judged by ejection phase indexes. There was a tendency for maximal positive first derivative of left ventricular pressure (dP/dt) to be less (1,912 versus 2,446 mm Hg/s, difference not significant), suggesting an abnormality of pressure generation, not shortening. Global function during exercise in the ischemia group was determined, in part, by the extent of regional dysfunction. Those in whom between three and five regions of eight regions studied had abnormal fractional shortening during exercise had a 6% decrease in ejection fraction, while those with six to eight abnormal regions had a decrease in ejection fraction of 15% (p less than 0.05). In addition, function of nonischemic, noninfarcted myocardium was studied at the base of the left ventricle in those with exercise-induced anteroapical ischemia (n = 4) and those with anteroapical infarction (n = 4). Base fractional shortening and shortening velocity were greater at rest in those with infarction (39% and 1.6 circ/s, respectively) than in control subjects (31% and 1.0 circ/s, respectively, p less than 0.01), indicating a chronic augmentation of shortening. Base shortening velocity during exercise in those developing anteroapical ischemia increased from 1.1 to 1.4 circ/s (p less than 0.005), suggesting an acute augmentation of function balancing the deterioration of anteroapical function. Systolic function in coronary artery disease is determined by acute and chronic alterations in regional function. During exercise, there is an interplay between regional dysfunction from ischemia or infarction and regional hyperfunction of nonischemic myocardium which determines global performance.

Influence of collagen network on left ventricular systolic and diastolic function in aortic valve disease.

OBJECTIVES: The purpose of this study was to evaluate left ventricular structure-function interplay in aortic valve disease. BACKGROUND: An increase in myocardial fibrosis has been demonstrated in aortic valve disease, but changes in the collagen network and their effect on ventricular function have not been defined. METHODS: Left ventricular structure was assessed from left ventricular endomyocardial biopsy specimens obtained in 32 patients with aortic valve disease (aortic stenosis in 25, aortic regurgitation in 7). Total collagen volume fraction, orthogonal collagen fiber meshwork (cross-hatching), endocardial fibrosis, muscle fiber diameter and volume fraction of myofibrils were determined by morphologic-morphometric evaluation. Control biopsy data were obtained from six donor hearts before transplantation. Eleven other patients with normal left ventricular function served as hemodynamic status control subjects. Left ventricular biplane cineangiography and high fidelity pressure measurements were carried out in all patients. Systolic function was assessed from ejection fraction. Diastolic function was evaluated by the time constant of relaxation, early and late peak filling rates and the constant of passive myocardial stiffness. Patients were assigned to three groups according to increasing severity of nonmyocyte tissue alterations. Group 1 comprised 10 patients with elevated total collagen volume fraction. Group 2 comprised 6 patients with normal total collagen volume fraction and the presence of increased cross-hatching or endocardial fibrosis, or both. Group 3 comprised 16 patients with elevated total collagen volume fraction and the presence of cross-hatching or endocardial fibrosis, or both. RESULTS: Muscle fiber diameter was increased in the three groups with aortic valve disease, whereas the volume fraction of myofibrils was comparable in all four study groups. Ejection fraction was depressed in groups 2 and 3 compared with the control group. The time constant of relaxation was prolonged in the three groups with aortic valve disease. No differences in early and late peak filling rate were observed in the four study groups, but the constant of myocardial stiffness increased in groups 2 and 3. CONCLUSIONS: In aortic valve disease, changes in collagen architecture are associated with altered systolic function and passive diastolic properties. The sole increase in total collagen volume fraction without a change in architecture leaves systolic and passive diastolic function unaltered.

Decreased concentration of myofibrils and myofiber hypertrophy are structural determinants of impaired left ventricular function in patients with chronic heart diseases: a multiple logistic regression analysis.

OBJECTIVES: The aim of this study was to perform a multiple logistic regression analysis to identify independent structural determinants of impaired left ventricular function. BACKGROUND: The association between contractile failure and structural alterations of the myocardium has been demonstrated in several studies, and multiple interactions between myocardial structure and cardiac performance are likely. METHODS: Morphometric data assessed from 130 left ventricular biopsy specimens were analyzed. The endomyocardial specimens were obtained from 57 patients with normal coronary arteries (17 with normal left ventricular ejection fraction and 40 with impaired left ventricular function [dilated cardiomyopathy]), 15 patients with hypertrophic cardiomyopathy and 32 patients with aortic valve disease. Transmural biopsy specimens were assessed in 6 donor hearts before heart transplantation and in 20 patients with left anterior descending coronary artery disease whose specimens were obtained from the left ventricular anterior wall during aortocoronary bypass surgery. Global or regional left ventricular function was evaluated from left cineventriculograms. The volume fraction of cardiac fibrous tissue, intracellular volume fraction of myofibrils, volume fraction of myofibrils related to myocardial tissue (including fibrosis) and myofiber diameters were determined from semithin sections of the biopsy specimens with the use of light microscopic morphometry. RESULTS: Multiple logistic regression analysis revealed decreased volume fraction of myofibrils (p < 0.005) and increased fiber diameter (p < 0.002) as independent determinants of impaired left ventricular function. CONCLUSIONS: These data indicate that, independent of the underlying heart disease, both decreased concentration of contractile proteins and myocyte hypertrophy are independently associated with impaired left ventricular function.

Effect of coronary occlusion during percutaneous transluminal angioplasty in humans on left ventricular chamber stiffness and regional diastolic pressure-radius relations.

The effect of repeated (3 to 10 second) and transient (15 to 75 second) abrupt coronary occlusion on the global and regional chamber stiffness was studied in nine patients undergoing angioplasty of a single proximal left anterior descending coronary artery stenosis. The left ventricular high fidelity pressure and volume relation was obtained before and after the procedure as well as during coronary occlusion, after 20 seconds (n = 9) and after 50 seconds (n = 5). During ischemia, there was an upward shift of the pressure-volume relation. The nonlinear simple elastic constant of chamber stiffness increased from 0.0273 +/- 0.017 before angioplasty (mean +/- SD) to 0.0621 +/- 0.026 after 20 seconds of occlusion (p less than 0.05) and 0.0605 +/- 0.015 after 50 seconds of occlusion (p less than 0.01). In five patients, the postangioplasty value remained higher than the control value, but at the group level the mean value (0.0529 +/- 0.037) was not statistically different. The regional stiffness was determined from the changes in the length of six segmental radii during diastole, from the lowest diastolic to the end-diastolic pressure. The regional constant of elastic stiffness was unaffected in the nonischemic zone. In the adjacent and ischemic zones, the regional stiffness was increased during occlusion (p less than 0.05). These regional abnormalities in diastolic function persisted at the time of postangioplasty measurements, 12 minutes after the end of the procedure. This suggests that recovery of normal diastolic function after repeated ischemic injuries is delayed after restoration of normal blood flow and systolic function.

Left ventricular systolic series elastic properties in aortic stenosis before and after valve replacement.

In seven patients with aortic valve disease the time course of an auxotonic beat was compared with that of an isovolumetric beat produced by aortic cross clamping during open heart surgery. The rate of systolic stress rise (dS/dt; g.cm-2) of the isovolumetric beat at peak meridional wall stress (Sp; g.cm-2) of the auxotonic beat was determined by tipmanometry and simultaneous sonomicrometry and was found to be 87% of maximum dS/dt. In the second part of the study the stiffness index (k) was calculated in patients undergoing cardiac catheterisation according to: k = 0.87.(max.dS/dt)/Sp.Vcf, where Vcf = normalised midwall circumferential fibre shortening velocity (circ.s-1). In 22 patients, 10 controls and 12 patients with aortic stenosis before (pre) and after (post) valve replacement the systolic stiffness index k (circ-1) was determined using tipmanometry and frame by frame angiocardiography. Muscle fibre diameter and interstitial fibrosis were assessed from left ventricular endomyocardial biopsies. The systolic stiffness index k was 15 circ-1 in controls, 14 in preoperative patients with aortic stenosis and 12 (p less than 0.01 v controls) in postoperative patients. There was a significant correlation between k and muscle fibre diameter (r = 0.55; p less than 0.01) but not between k and interstitial fibrosis or ejection fraction. We conclude that systolic stiffness index k is normal despite marked left ventricular hypertrophy in preoperative patients with aortic stenosis. Following successful valve replacement systolic stiffness index decreased and was significantly lower than in controls. Series elasticity appears to be determined by structures related to the muscle cell rather than to interstitial fibrosis.

Fluorescence spectroscopy for identification of atherosclerotic tissue.

OBJECTIVE: Vessel perforation and limited steerability of the laser light are the major limitations of laser angioplasty. To improve steerability fluorescence spectroscopy has been proposed for identification of atherosclerotic plaques. The aim was to investigate this. METHODS: Fluorescence spectroscopy with three different excitation wavelengths (325 nm, 380 nm, 450 nm) was tested in an emission range of 400 nm to 600 nm. Intensity ratios at 480/420 nm were determined in different types of blood vessels. Necropsy material from 40 patients (punch biopsies of 4 mm diameter from the coronary and carotid artery as well as from the ascending and descending aorta) was studied spectroscopically. Histological alterations of the vessel wall were assessed by a semiquantitative score (0 to 10 points): (a) normal tissue, 0 to 2 points (mean = 0.25; n = 38); (b) mild atherosclerotic lesions, 3 to 5 points (mean = 3.35; n = 39); (c) severe atherosclerotic lesions, greater than or equal to 6 points (mean = 6.75; n = 43). RESULTS: Best spectroscopic results were obtained with an excitation wavelength of 325 nm. In samples with severe atherosclerotic lesions the fluorescence spectra showed a significant reduction of the emitted wavelength intensities when compared to normal tissue. There was a clear separation of the fluorescence spectra between normal and mild as well as between normal and severe atherosclerotic lesions; normal tissue showed an increased intensity in the range from 420 nm to 540 nm, whereas atherosclerotic lesions had no or only a small peak at 480 nm. There was a significant correlation between the semiquantitative score (n = 120) and the fluorescence ratio at 480/420 nm (excitation wavelength 325 nm) with a correlation coefficient of 0.87. The spectroscopic results showed no differences between the samples taken from different types of vessels. CONCLUSIONS: Fluorescence spectroscopy allows a reliable identification of normal and atherosclerotic lesions. The close correlation between the emitted light intensity ratio at 480/420 nm and the histological alterations of the vessel wall suggests a relationship between vessel wall fluorescence and the atherosclerotic alterations of the wall.

On whether there is a true increase in myocardial stiffness during myocardial ischemia.

In the experimental animal, acute ischemia by interruption of coronary blood supply is accompanied by a steepening of the slope of the left ventricular pressure-volume and pressure-segment length relations. This increase in chamber stiffness is associated with an increase in myocardial stiffness assessed from the slope of the diastolic stress-strain relation. Supply-type ischemia in humans brought about by balloon inflation during coronary angioplasty leads to an upward shift of the pressure-length relation of the ischemic and the adjacent segment combined with a steepening of the slope. In demand ischemia produced by rapid pacing in patients with coronary artery disease, an increased radial stiffness modulus at any level of radial stress was present when compared with that during the resting state. These alterations of the stress-strain relation suggest that the physical properties of the myocardium change during both supply and demand ischemia. The increased diastolic myocardial stiffness appears to result, at least in part, from increased residual interaction between actin and myosin filaments.

Use of apexcardiography to evaluate left ventricular diastolic compliance in human beings.

The relation between various relative amplitude measurements of the left apexcardiogram and internally derived indexes of diastolic compliance of the left ventricle was studied in 29 patients. Simultaneous high fidelity recordings of the left apex tracing and left ventricular pressure were obtained in 11 patients without left ventricular disease (group I) and 18 patients with congestive cardiomyopathy (group II). In 204 normal subjects the ratio of the A wave amplitude to the total diastolic deflection (A/D ratio) of the left apexcardiogram was 31.4 +/- 11.4 (mean +/- standard deviation) percent, the ratio of the A wave amplitude to the total height (A/H ratio) 8.9 +/- 4.3 percent and the D/H ratio 30.4 +/- 14.7 percent. The A/D and A/H ratios were significantly (P less than 0.001 and P less than 0.005) increased in group II (69.2 +/- 12.2 percent and 16.8 +/- 8.2 percent, respectively); they were within normal limits in group I. In contrast, the D/H ratio was within normal limits in both groups of patients. The A/D ratio correlated significantly better with specific compliance (deltaV/deltaP.V) (r = -0.87) than did the A/H ratio (r = -0.53), whereas similar correlations were obtained with end-diastolic volume compliance (dV/dPV) (r = -0.61 and r = - 0.64, respectively). In contrast, the D/H ratio correlated significantly only with end-diastolic distensibility index (dV/dP) (r = -0.52). It is concluded that A wave amplitude/total diastolic deflection (A/D) ratio and, to a lesser degree, the A wave amplitude/total height (A/H) ratio of the left apexcardiogram correspond best to diastolic compliance and are useful noninvasive measurements of this property of the left ventricle.

Abnormal segmental contraction velocity in coronary artery disease produced by isometric exercise and atrial pacing.

Since isometric exercise by sustained handgrip leads to a sizable increase in aortic pressure this maneuver was used in addition to atrial pacing to increase the imbalance between oxygen demand and supply in two groups of patients. Both groups were studied by left heart catheterization and cineangiography in the right anterior oblique projection, at rest, during atrial pacing and during combined pacing and handgrip exercise. Group 1, the control group, consisted of 10 patients without coronary artery disease having an ejection fraction of 0.61 to 0.82. Group 2 was composed of 10 patients with definite obstructive disease of one or more of the three main coronary arteries. At rest, ejection fraction was normal or nearly normal (range 0.54 to 0.78). Regional myocardial contraction performance was assessed by determining mean segmental shortening velocities at the basal (VSB), middle (VSM) and apical (VSA) short ventricular axes. Whereas at rest there was no significant difference between the two groups or any of the three velocities, during pacing, VSM and VSA were significantly smaller in Group 2 than in Group 1 (P smaller than 0.02). During pacing combined with handgrip exercise the difference between the two groups was clearly accentuated, all three velocities being highly significantly decreased in Group 2 (VSB, P smaller than 0.01; VSM and VSA, P smaller than 0.001). When evaluated individually the patients of Group 2 had in 9 segments during pacing values for VSB, VSM and VSA that were below the range of the normal subjects. During pacing combined with handgrip a newly abnormal shortening velocity was observed in 12 segments (VSB abnormal in 3 of 7, VSM in 4 of 7 and VSA in 5 of 7 instances). In conclusion, the combination of atrial pacing and handgrip exercise appears to be a useful stress maneuver to identify temporarily dysfunctioning segments in patients with coronary artery disease in whom atrial pacing alone is not sufficient to induce ischemic contraction disorders.

Prediction of postoperative performance in aortic valve disease.

A new direct method has been developed for predicting postoperative performance in patients undergoing aortic valve replacement. Employing micromanometry and cineangiography, a number of conventional hemodynamic and angiographic variables, including the peak value of the first derivative of ventricular pressure divided by ventricular pressure (dP/dt/P)max, were evaluated in 171 patients studied preoperatively and in 44 patients studied pre- and postoperatively with an additional 14 patients serving as control subjects. Normal contractile state relations (dP/dt/P)max versus end-diastolic pressure (over a range of 125 mm Hg or less to more than 15 mm Hg) were derived from patients whose preoperative ejection fraction and peak wall stress were equal to or more than control mean--2 standard deviations. Postoperative function was predicted to be abnormal (ejection fraction less than control mean--2 standard deviations) if preoperative values of (dP/dt/P)max and end-diastolic pressure fell below the 95 percent confidence bands of these contractile state relations. The method accurately predicted postoperative function in 40 of 44 patients with a sensitivity of 100 percent. This result was confirmed by a discriminant function analysis (based on preoperative ejection fraction, end-diastolic pressure and [dP/dt/P]max) that yielded correct classifications in 42 of 44 patients. These studies indicate that the preoperative contractile state of the myocardium is the major determinant of postoperative performance in aortic valve disease.

Effects of ischemia, bypass surgery and past infarction on myocardial contraction, relaxation and compliance during exercise.

Abnormalities of left ventricular function during ischemia have been described in animal models and in humans. Exercise, while a physiologic means of inducing ischemia, has a complex effect on left ventricular function by itself. In addition, patients with coronary artery disease have a diversity of chronic changes in myocardial structure and function. Therefore, with use of micromanometer left ventricular pressure measurements and ventricular volumes, calculated from biplane cineangiograms, left ventricular function at rest and during exercise was studied in 57 patients. Exercise-induced ischemia produced a decrease in ejection fraction, an increase in end-systolic volume, dramatic increases in diastolic pressures and an upward shift in the diastolic pressure-volume relation. Central to these changes was abnormal myocardial contraction and relaxation, with reduced regional shortening and impaired left ventricular pressure decay. However, nonischemic areas were capable of augmented shortening, and global pressure decay did accelerate slightly. These findings demonstrate that exercise-induced adjustments in contraction and relaxation are intertwined with ischemia-related abnormalities. Exercise studies in patients after bypass surgery and in patients with scars from distant myocardial infarction were useful in clarifying confounding factors. For example, asynchrony of contraction and relaxation, and chronic changes in passive chamber properties, also compromise systolic and diastolic function during exercise. In patients with coronary artery disease without ischemia during exercise, left ventricular end-diastolic pressure, but not early diastolic pressure, increased during exercise. The increase in pressure was appropriate for a slight increase in end-diastolic volume in a ventricle with a steep pressure-volume relation. Furthermore, end-systolic volume, while maintained during exercise, was not reduced, as occurs normally.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of aortic valve stenosis (pressure overload) and regurgitation (volume overload) on left ventricular systolic and diastolic function.

In secondary hypertrophy from chronic pressure or volume overload, or both, systolic as well as diastolic abnormalities of left ventricular (LV) function have been described, but their relation has not been defined. In 58 patients with aortic valve disease (28 with aortic valve stenosis, and 30 with aortic regurgitation) and in 11 control subjects, LV biplane cineangiography was performed simultaneously with LV high-fidelity pressure measurements. LV ejection performance was assessed by ejection fraction, and diastolic function by the time constant of LV pressure decay, the early and late peak filling rates, and the constants of chamber (pressure-volume relation) and myocardial stiffness (stress-strain relation). In the entire cohort (n = 69), ejection fraction was inversely related to the time constant of LV relaxation (r = -0.58, p less than 0.001) and to the constant of myocardial stiffness (r = -0.62, p less than 0.001). Despite preserved systolic contractile function (as evaluated from the ejection fraction-mean systolic stress relation), abnormalities in LV diastolic function were present in 9 of 18 patients with pressure overload and 20 of 22 with volume overload. None of the 58 patients with aortic valve disease had a reduced early peak filling rate, whereas a reduction in late peak filling rate was observed in 3 with aortic stenosis, but in none with aortic regurgitation. This, it appears that abnormalities of relaxation and passive diastolic myocardial stiffness precede alterations in myocardial contractility. Assessment of peak filling rates is not helpful to detect diastolic dysfunction in patients with aortic valve disease.