Neil B. Ingels

Effect of Intrathoracic Pressure on Left Ventricular Performance

Left ventricular dysfunction is common in respiratory-distress syndrome, asthma and obstructive lung disease. To understand the contribution of intrathoracic pressure to this problem, we studied the effects of Valsalva and Müller maneuvers on left ventricular function in eight patients. Implantation of intramyocardial markers permitted beat-by-beat measurement of the velocity of fiber shortening (VCF) and left ventricular volume. During the Müller maneuver, VCF and ejection fraction decreased despite an increase in left ventricular volume and a decline in arterial pressure. In addition, when arterial pressure was corrected for changes in intrapleural pressure during either maneuver it correlated better with left ventricular end-systolic volumes than did uncorrected arterial pressures. These findings suggest that negative intrathoracic pressure affects left ventricular function by increasing left ventricular transmural pressures and thus afterload. We conclude that large intrathoracic-pressure changes, such as those that occur in acute pulmonary disease, can influence cardiac performance.

Measurement of midwall myocardial dynamics in intact man by radiography of surgically implanted markers.

Tiny radiopaque helices (0.85 × 1.5 mm) of pure tantalum wire were implanted by means of a simple insertor instrument into the left ventricular myocardium in 24 patients at the time of cardiac surgery. The markers were positioned in such a way as to outline the profile of the left ventricle when viewed in a 30° right anterior oblique projection. Biplane studies showed that all markers could be placed very nearly in a plane using the surface anatomy of the heart as a guide to implantation. Implantation of markers required approximately two minutes. No intraoperative or postoperative complications ascribable to the markers have occurred. They remain firmly in place and allow acquisition of a noninvasive ventriculogram at any time after surgery. The dynamic geometry of the left ventricle was determined by analysis of cineradiograms of these markers. Utilization of a single-plane (right anterior oblique) cineradiogram to obtain measurements of major transverse ventricular diameters, mean circumferential shortening, and circumferential shortening velocity results in underestimation of lengths by 1.4%, overestimation of shortening by 1.2% of end-diastolic length, and overestimation of velocity by 0.05 circ/sec, when compared with values obtained simultaneously from biplane cineradiograms.

Relation between longitudinal, circumferential, and oblique shortening and torsional deformation in the left ventricle of the transplanted human heart

The present study was designed to investigate the anisotropy of systolic chord shortening in the lateral, inferior, septal, and anterior regions of the human left ventricle. At the time of surgery, 12 miniature radlopaque markers were implanted into the left ventricular midwall of the donor heart in 15 cardiac transplant recipients. Postoperative biplane cineradiograms were computer-analyzed to yield the three-dimensional coordinates of these markers at 16.7-msec intervals. In each of the four left ventricular regions, chords were constructed from a central marker to outlying markers, and the percent systolic shortening of each chord was calculated. In each region, chord angles were measured with respect to the circumferential direction (positive angles counterclockwise) and each chord was assigned to one of four angular groups: I. oblique, -45±22.5° or 135±22.5°; II. circumferential, 0±22.5° or 180±22.5°; III. oblique, 45±22.5° or -135±22.5°; or IV. longitudinal, 90±22.5° or -90±22.5°. In the lateral, inferior, and septal regions, respectively, systolic shortening (mean± SD percent;) was significantly greater in Group I chords (19±5percent;, 17±5percent;, and 15±4percent;) than those in Group II (15±5percent;, 12±4percent;, and 11±4percent;), Group III (12±4percent;, 12±5percent;, and 11±4percent;), or Group IV (13±5percent;, 13±6percent;, and 12±5percent;). The anterior region was unique hi exhibiting equal shortening in both Group I and Group n chords (16±5percent;), although the shortening of these chords was significantly greater than that of Group III and Group IV (12±5percent;) in this region. A cylindrical mathematical model was developed to relate longitudinal, circumferential, and oblique systolic shortening to torsional deformation about the long axis of the left ventricle. Torsional deformations measured in these 15 hearts were of sufficient magnitude and correct sense to agree with model predictions. These data suggest that torsional deformations of the left ventricle are of fundamental importance in Unking the one-dimensional contraction of the helically wound myocytes to the three-dimensional anisotropic systolic shortening encountered in the transplanted human heart.

Alterations in left ventricular twist mechanics with inotropic stimulation and volume loading in human subjects.

BACKGROUND Left ventricular (LV) twist, the longitudinal gradient of circumferential rotation about the LV long axis, may play an important role in the storage of potential energy at end systole and its subsequent release as elastic recoil during early diastole; however, the effects of load and inotropic state on LV systolic twist and diastolic untwist in human subjects have not previously been characterized. METHODS AND RESULTS Six cardiac transplant recipients with 12 implanted radiopaque midwall LV myocardial markers were studied 1 year after transplantation. Biplane cinefluoroscopic marker images and LV pressure were recorded during control conditions and after afterload augmentation (methoxamine, 5 to 10 micrograms.kg-1 x min-1), inotropic stimulation (dobutamine, 5 micrograms.kg-1 x min-1), and preload augmentation (volume loading with normal saline). Systolic twist dynamics were assessed by maximum twist (Tmax[rad/cm]), peak negative twist rate (-dT/dtmin[rad.cm-1 x s-1]), and the slope of the twist normalized-ejection fraction relation (T-nEFR, Msys[rad/cm]) during systole. Diastolic untwist was assessed by the peak positive untwist rate (+dT/dtmax [rad.cm-1 x s-1]) and the slopes (rad/cm) of the T-nEFR during early diastole (Mear-dia) and mid diastole (Mmid-dia). Compared with control values, LV pressure and volume loading had no significant effect on Tmax, -dT/dtmin, or Msys; however, inotropic stimulation significantly increased all parameters describing systolic twist (Tmax: -0.10 +/- 0.03 versus -0.06 +/- 0.02 rad/cm, P < .001; -dT/dtmin: -0.72 +/- 0.19 versus -0.44 +/- 0.22 rad.cm-1 x s-1, P < .001; Msys: -0.10 +/- 0.03 versus -0.06 +/- 0.01 rad/cm, P < .001). Pressure loading had no effect on early diastolic untwisting; however, dobutamine significantly increased M(ear)-dia (-0.24 +/- 0.06 versus -0.13 +/- 0.04 rad/cm, P < .0001) and +dT/dtmax (0.78 +/- 0.24 versus 0.45 +/- 0.16 rad.cm-1 x s-1, P < .001). Conversely, volume loading significantly decreased M(ear)-dia (-0.08 +/- 0.04 versus -0.13 +/- 0.04 rad/cm, P < .05). M(ear)-dia correlated directly with LV contractile state (as assessed as maximum dP/dt, r = .60, P < .0001) and inversely with end-systolic volume (r = -.87, P < .0001) but was unrelated to stroke volume (r = .08, P = .30) or LV afterload (estimated as effective arterial elastance, r = .08, P = .29). Mmid-dia did not change during any intervention. CONCLUSIONS In conscious human transplant patients, (1) pressure and volume loading do not affect systolic LV twist; (2) dobutamine augments systolic twist and early diastolic untwisting, suggesting more end-systolic potential energy storage and early diastolic elastic recoil with enhanced inotropic state; (3) volume loading decreases early diastolic untwisting, possibly reflecting diminished recoil forces after preload augmentation associated with larger end-systolic volumes (ESV); and (4) M(ear)-dia correlates strongly with ESV (in an inverse fashion), and less strongly, but directly, with LV dP/dtmax.

Exercise response of the denervated heart in long-term cardiac transplant recipients

Abstract The left ventricular response to volume loading and graded supine bicycle exercise (3 minutes at 15, 45 and 90 watts) was assessed in nine long-term (more than 1 year) cardiac transplant recipients. Computer-aided fluoroscopy of radiopaque myocardial markers implanted in the left ventricle at the time of surgery was used to measure left ventricular dynamics. Pulmonary arterial and left ventricular pressures were monitored. Plasma norepinephrine was measured by radio-enzymatic assay at each level of exercise. Early in exercise mean end-diastolic volume (six patients) increased from a resting value of 125 to 138 ml (p

Evaluation of methods for quantitating left ventricular segmental wall motion in man using myocardial markers as a standard.

Radiopaque markers were implanted in the left ventricular myocardial midwall in 58 patients and studied in the 30° right anterior oblique projection by computer-aided fluoroscopy. Marker motion was used as a standard of segmental wall motion against which the accuracy of five methods for measuring left ventricular wall motion was assessed: two methods using hemiaxial measurements in rectangular coordinates, two using radial measurements in polar coordinates (all with frame-by-frame axial reindexing) and one using radial measuremehts in fixed external polar coordinates. The latter method showed significantly les error (25.9%, p < 10–6) in measuring midwall marker motion than the other four methods (range 42.5–47.5%) in the group as a whole and in subgroups that had abnormalities of posterior, apical and anterior wall motion. This method also had the best correlation of marker motion and motion of adjacent endocardial border (of the overall left ventricle and the posterior, apical, and anterior walls separately) as visualized by ventriculography in 29 patients. The bulk of the reduction in error using this method was due to the use of a fixed external reference system, with a small additional increment of error removed by proper selection of the polar origin at a point 69% of the distance from the anterolateral edge of the aortic valve to the ventricular apex at endsystole.

Geometric Distortions of the Mitral Valvular-Ventricular Complex in Chronic Ischemic Mitral Regurgitation

Background—Better understanding of the precise 3-dimensional geometric changes of the mitral valvular-ventricular complex in chronic ischemic mitral regurgitation (CIMR) is needed in order to devise better surgical repair techniques. We hypothesized that changes after inferior myocardial infarction would be different in hearts that developed CIMR compared with those that did not. Methods and Results—Twenty-four sheep underwent coronary snare and marker placement (annulus, papillary muscles, and anterior and posterior leaflets). After 8 days, cinefluoroscopy provided 3-dimensional marker data, and snare occlusion of obtuse marginal branches created inferior myocardial infarction, including the posterior papillary muscle. After 7 weeks, the 16 surviving animals were studied again and grouped by mitral regurgitation grade (≥ 2+, n=10 versus ≤ 1+, n=6). End-systolic mitral annulus dimensions, components of papillary muscle and leaflet displacement, were calculated. After inferior myocardial infarction, total displacement of the posterior papillary muscle from the midseptal annulus (“saddle horn”) was greater in CIMR(+) animals: 6.5±3.2 versus 3.1±2.7 (P =0.02), with the posterior papillary muscle moving more laterally (6.8±3.4 versus 2.5±3.5 mm, P =0.01). Increase in mitral annular septal-lateral diameter was greater in animals with CIMR (4.9±2.7 versus 2.3±2.0, P =0.02), and apical displacement of the posterior leaflet (PL) margin was also greater in the CIMR(+) group (1.7±1.0 versus 0.3±0.5, P =0.01). Conclusions—The CIMR(+) group had greater septal-lateral annular dilatation, lateral posterior papillary muscle displacement, and apical PL restriction, indicating that these associated geometric alterations may be important in the pathogenesis of CIMR. Treatment of CIMR should address both annular septal-lateral dilatation and lateral displacement of the posterior papillary muscle.

Alterations in left ventricular diastolic twist mechanics during acute human cardiac allograft rejection.

BACKGROUND Contraction of obliquely oriented left ventricular (LV) fibers results in a twisting motion of the left ventricle. The purpose of this study was to assess the effects of acute human cardiac allograft rejection on LV twist pattern and the twist-volume relation. METHODS AND RESULTS Tantalum markers were implanted into the LV midwall in 15 transplant recipients to measure time-varying, three-dimensional chamber twist using computer-assisted analysis of biplane cinefluoroscopic images. Twist was defined as the mean longitudinal gradient of circumferential rotation about the LV long axis. When plotted against normalized percent ejection fraction (%EF), the resulting twist-normalized %EF relation could be divided into three phases. In systole, LV twist was linearly related to ejection of blood. In contrast, diastolic untwist was characterized by early rapid recoil with little change in LV volume, followed by more gradual untwisting when the bulk of diastolic filling occurred. During 10 acute rejection episodes in 10 patients, maximum twist, peak systolic twist rate, and the slope of the systolic twist-normalized %EF relation did not change. In contrast, the slope of the early (first 15% of filling) diastolic twist-normalized %EF relation (M(early-dia)) decreased significantly (-0.194 +/- 0.062 [prerejection] versus -0.103 +/- 0.054 rad/cm [rejection], p = 0.0003), resulting in a prolonged tau 1/2 (time required to untwist by 50% [20 +/- 5% versus 28 +/- 5% of diastole], p = 0.0003) and decrease in percent untwisting at 15% diastolic LV filling (62 +/- 11% versus 36 +/- 13%, p = 0.0003). Therefore, a greater proportion of LV untwisting occurred later in diastole during rejection, as reflected by an increase in the slope (M(mid-dia)) of the middle to late (from 15 to 90% filling) diastolic twist-normalized %EF relation (-0.018 +/- 0.009 versus -0.030 +/- 0.010 rad/cm, p = 0.0015). Peak rate of untwist was not affected. With resolution of rejection, M(early-dia) and percent untwist during early diastole returned to baseline levels (p = NS versus baseline). There was also a trend for M(mid-dia) to return toward prerejection values (p = NS versus baseline), but this change did not reach statistical significance compared with rejection values. CONCLUSION Acute cardiac allograft rejection is associated with altered diastolic twist mechanics in the absence of any demonstratable systolic abnormalities. During rejection, myocardial edema and other factors may result in intrinsic changes of the elastic properties of the myocardium, thereby leading to modification of recoil forces responsible for the early, rapid unwinding of the deformed ventricle.

Torsional deformation of the left ventricular midwall in human hearts with intramyocardial markers: regional heterogeneity and sensitivity to the inotropic effects of abrupt rate changes

The spiral orientation of left ventricular (LV) fibers suggests that twisting about the ventricular long axis of the apex with respect to the base, i.e., torsional deformation, may be characteristic of LV contraction. To demonstrate this twisting motion, 10 orthotopic human cardiac allograft recipients were studied with biplane cineradiography of tantalum helices implanted within the LV midwall at 12 specific sites. Counterclockwise twisting about the LV long axis (as reviewed from apex to base) accompanied ventricular ejection in all patients. Torsional deformation angles, measured relative to a reference minor axis at the base, were substantially smaller in the anteroapical wall, as compared with counterparts in the apical third of the inferior and lateral walls (anterior = 13.3 ±6.0±, inferior =18.7±6.3±, and lateral = 23.4±10.7±). Torsional angles at the midventricular level were roughly half as much and exhibited similar regional variabilities (anterior = 7.6 ±3.3±, inferior = 9.0±3.3±, lateral = 10.7 ±5.2±, and septal = 8.8±3.8±). Comparison of control beats and the initial beat after abrupt cessation of rapid atrial pacing (126 ± 10 beats/min) with return to the control heart rate (96 ±9 beats/min) permitted the mild positive inotropic effect of tachycardia to be assessed at similar levels of ventricular load. Torsional deformation of the anteroapical and inferoaplcal sites increased significantly (p < 0.05) over control values to 15.6 ±7.5± and 21.2 ±5.5±, respectively. In contrast, torsional deformation of the lateral wall was essentially unchanged. These data provide direct evidence for torsional deformation of the left ventricle in humans, demonstrate that torsion of the LV chamber is nonuniform, and suggest a dependence of LV torsion upon contractile strength that is attenuated in the lateral wall.

Restricted posterior leaflet motion after mitral ring annuloplasty

BACKGROUND The effects of ring annuloplasty on mitral leaflet motion are incompletely known. The three-dimensional dynamics of the mitral valve in vivo were examined to determine how two types of annuloplasty rings affect leaflet motion during valve closure. METHODS Miniature radiopaque markers on the mitral leaflets, annulus, and left ventricle were implanted in three groups of sheep. One group served as control (n = 7); other sheep were randomly assigned to receive either a flexible Duran (n = 6) or a semirigid Carpentier-Edwards Physio ring (n = 6). After recovery, three-dimensional marker coordinates were computed from simultaneous (60 Hz) biplane videofluoroscopic marker images. RESULTS Both types of rings immobilized the middle scallop of the posterior leaflet without affecting anterior leaflet motion. The excursion of the anterior leaflet edge from maximally open to fully closed was not different between the groups (control, 13+/-2 mm; Duran 13+/-1 mm; Physio ring, 14+/-1 mm; p > 0.05), but posterior leaflet edge excursion was restricted (control, 7.4+/-0.4 mm; 2.3+/-0.3 mm [p < 0.001]; Physio, 2.7+/-0.2 mm [p < 0.001]) by both rings. CONCLUSIONS Mitral annuloplasty with either ring type markedly reduced the mobility of the central posterior leaflet in normal ovine hearts such that valve closure became essentially a single (anterior) leaflet process with the frozen posterior leaflet serving only as a buttress for closing.