Assessment of synchronized direct mechanical ventricular actuation in a canine model of left ventricular dysfunction.

Direct mechanical ventricular actuation (DMVA) is an experimental procedure that provides biventricular cardiac assistance by intracorporeal pneumatic compression of the heart. The advantages this technique has over other assist devices are biventricular assistance, no direct blood contact, pulsatile blood flow, and rapid, less complicated application. Prior studies of nonsynchronized DMVA support have demonstrated that a subject can be maintained for up to 7 days. The purpose of this study was to determine the acute hemodynamic effects of cardiac synchronized, partial DMVA support in a canine model (RVP) of left ventricular (LV) dysfunction. The study consisted of rapidly pacing seven dogs for 4 weeks to create LV dysfunction. At the conclusion of the pacing period, the DMVA device was positioned around the heart by means of a median sternotomy. The animals were then imaged in a 1.5 T whole body high speed clinical MR system, with simultaneous LV pressure recording. Left ventricular pressure-volume (PV) loops of the nonassisted and DMVA assisted heart were generated and demonstrated that DMVA assist shifted the loops leftward. In addition, assist significantly improved pressure dependent LV systolic parameters (left ventricular peak pressure and dp/dt max, p < 0.05), with no diastolic impairment. This study demonstrates that DMVA can provide synchronized partial assist, resulting in a decrease in the workload of the native heart, thus having a potential application for heart failure patients.

Heart muscle contraction oscillation.

van der Pol developed a mathematical model for self-sustained radio oscillations described by his non-linear differential equation D2X + epsilon(X2-1)DX + X = 0 in which X is a function of time T and D/DT the differential operator to T. For epsilon = 0, this is the differential equation for the harmonic oscillator which has sinusoidal solutions. For epsilon not equal to 0 the equation is non-linear. If epsilon > 1 van der Pol coined the name relaxation oscillations for its solutions. These are non-linear and quite different from simple sinusoidal oscillations. They are mathematical models for many physical and biological phenomena. van der Pol suggested that his equation is also a model for the heartbeat. However, biomedical oscillations, including the heartbeat, have a threshold which the mathematical model described by van der Pol's equation does not possess. It has, in addition to an unstable origin, only a stable limit cycle of Poincaré. In this paper, van der Pol's equation is extended in such a way that it has in addition to a stable origin and a stable limit cycle, an unstable limit cycle. Because it possesses such an unstable limit cycle, the extension obtained is a mathematical model for a threshold oscillation. It is also shown that an asymmetric analogy of the extended equation is a mathematical model for an isometric contraction of the mammalian cardiac muscle.

Electrophysiologic recovery in postischemic, stunned myocardium despite persistent systolic dysfunction.

Previous investigators have hypothesized that myocardial "stunning" may result either from a primary impairment in excitation or from electromechanical dissociation. Thrombolytic therapy and angioplasty have increased the importance of understanding the electrophysiologic effects of brief ischemia followed by reperfusion. We investigated the electrophysiologic properties of mechanically dysfunctional stunned myocardium in 18 dogs anesthetized with pentobarbital (30 mg/kg, intravenously administered). After thoracotomy, the proximal anterior descending coronary artery was occluded for 15 minutes, which was followed by 20 minutes of reperfusion. At baseline, peak ischemia, and 20 minutes of reperfusion, local electrogram durations, activation times, and refractory periods were measured from 12 standardized sites within the ischemic and border zones. Echocardiographic percentage of systolic wall thickening confirmed normal preischemic and markedly reduced postischemic function in the investigated region. Despite the marked electrophysiologic abnormalities observed in the ischemic zone during ischemia, mean electrogram duration, calculated conduction velocity, and mean effective refractory period after 20 minutes of reperfusion had returned almost to baseline values 39.2 +/- 11.5 msec versus 37.2 +/- 12.1 msec, 0.65 +/- 0.15 m/sec versus 0.68 +/- 0.15 m/sec, and 134 +/- 14 msec versus 131 +/- 8 msec, respectively. Corresponding mean values within the ischemic border zone were similarly close to baseline values after reperfusion. There was no significant difference in local heterogeneity (coefficient of variation) within the ischemic or border zone after reperfusion versus baseline values. Although the postischemic electrophysiologic status returned to normal, systolic thinning and dyskinesis persisted in the region of measurement. The contractile dysfunction that results from reperfusion-induced injury can thus occur in the setting of apparent excitation-contraction uncoupling.

In vitro inhibition of nitrogen mustard efficacy by postincubation of treated cells in serum protein.

Lettre-Ehrlich cells were loaded with sufficient HN2 to produce about a 98% cell kill. Postincubation of the HN2-loaded cells in PBS resulted in the loss of about 40% of their HN2 without changing the cytolytic effect, supporting the proposal that only bound drug was effective. Postincubation of the HN2-loaded cells in PBS which contained 2% bovine serum albumin or in cell-free mouse ascitic fluid (1.8% protein) resulted in the same relative cellular HN2 loss as well as a 79% decrease in the cell kill. The cytolytic effect of HN2 is believed to be dependent on the degree to which the drug crosslinks DNA in 2 sequential reactions. It seems likely that such crosslinking occurred in nearly all of the PBS-postincubated cells, as they were nearly all killed. By analogy, albumin postincubation apparently blocked the competition of such crosslinking.

Vector mapping of myocardial activation.

A custom-made probe, consisting of four electrodes arranged so that two orthogonal bipolar electrograms could be recorded from a single site, was used to record epicardial activity during atrial and ventricular pacing in five normal and five anesthetized open-chest mongrel dogs with myocardial infarction. Unfiltered bipolar electrograms recorded with a 2 mm interelectrode distance averaged 36 +/- 15 mV in amplitude and 16 +/- 5 msec in duration in normal areas and 14 +/- 11 mV and 23 +/- 12 msec in infarcted areas (p less than .01 infarct vs normal). The bipolar electrograms were vector summed so that a vector loop could be generated at each site. The direction of epicardial impulse propagation as determined by multipoint isochronal activation mapping was compared with that indicated by maximum x,y deflection of the vector loop. At 203 sites (141 normal and 62 infarcted) there was a median error of only 13 degrees and an excellent correlation by linear regression (r2 = .95). In normal myocardium vector loops were straight (60%), open (21%), or hooked (19%). In infarcted myocardium, notched and irregular loops were occasionally seen. However, a clear maximum x,y deflection was still obtained from 98% of infarcted sites. During ventricular pacing in normal dogs, uniform epicardial conduction was observed for up to 4 cm longitudinal to fiber orientation but only 1 cm transverse to it. At selected sites longitudinal to fiber orientation conduction velocity was 0.618 m/sec, electrogram duration 12 msec, and vector amplitude 76 mV compared with 0.304 m/sec, 18 msec, and 38 mV during conduction transverse to fiber orientation (p less than .05 for all comparisons). Vector mapping of epicardial activation was performed during ventricular tachycardia induced by programmed stimulation in two of five 2-week-old canine myocardial infarcts. Aside from minor irregularities caused by impulse spread around areas of block, vector loops indicated when impulses were spreading away from the area of early epicardial activity and thus directed mapping to the region of earliest activation. We conclude that vector loops generated by summing orthogonal local bipolar electrograms accurately represent the direction of epicardial activation in both normal and infarcted myocardium. Such loops may prove useful in mapping tachycardias and in clarifying details about cardiac activation processes.

The cellular electrophysiologic changes induced by high-energy electrical ablation in canine myocardium.

High-energy electrical ablation is a new experimental approach to control arrhythmias. In this study, the cellular electrophysiologic effects of high-energy shocks (5 to 40 J) delivered in vitro to 14 epicardial tissues from 11 dogs were studied in an attempt to understand the nature and extent of injury as well as potential arrhythmogenic mechanisms. In addition, this preparation was used to test the importance of cathode-anode configuration, current density, and fiber orientation in the induction of tissue injury in vitro. Electrophysiologic abnormalities were noted up to 10 mm from the electrode wall, and their extent was determined in part by current density and the cathode-anode orientation. A decrease in resting membrane potential, action potential amplitude, and dV/dT occurred in all tissues after high-energy shocks, which was worst nearest the cathode and of graded severity at increasing distances from the cathode. The most severe effects were noted with high current densities and in tissues located between the cathode and anode. In addition, impaired impulse conduction and abnormal repolarization were documented. Histologic study demonstrated contraction band necrosis immediately after delivery of high-energy shocks. The extent and distribution of the contraction bands was in part dependent on the energy delivered and the cathode-anode configuration. These findings suggest potential mechanisms for arrhythmogenesis and altered regional hemodynamic abnormalities that occur in vivo.