Improving heart failure care by using a telemedicine system

Heart failure constitutes the most frequent and expensive hospital discharge diagnosis in the United States, costing annually over $10 billion. Optimal care requires an understanding of their illness, participating in clinical decisions, and frequent communication. Current surveillance is labor intensive and expensive. Follow-up is often inadequate, incomplete, and inconsistent. To address these problems, we developed an Internet-based telemedicine system, consisting of a secure server and database. Patients send or receive data to or from their care provider via the Internet. The system optimizes function and minimizes cost (all hardware is off the shelf and FDA approved). This paper describes our initial experience with this system. We are currently using this telemedicine system in a prospective, randomized clinical trial, comparing Class III or IV heart failure patients with standard care versus standard care plus telemedicine.

Can latissimus dorsi muscle stimulation benefit heart during training period after vascular delay?

We hypothesized that a two-stage vascular delay procedure followed by 5 weeks of conditioning of the latissimus dorsi muscle (LDM) could benefit the heart during the training period and greatly increase cardiac assistance when examined with maximum potential. In mongrel dogs (n = 10), left ventricle (LV) dysfunction was induced by intracoronary injections of latex microspheres [90 +/- 2 micro diameter]. Vascular delay of the LDM was performed in one group (n = 6), whereas the other group (control, n = 4) did not undergo vascular delay. After 2 weeks, CMP was performed in all animals followed by LDM conditioning. After 5 weeks of muscle training, we examined left ventricular function at 20 Hz-4 volts, 33 Hz-4 volts, and 50 Hz-10 volts stimulation by assessing peak aortic pressure (AoP), left ventricular pressure (LVP), maximum LV +dP/dt, stroke volume (SV), stroke work (SW), stroke power (SP), and aortic flow. LDM assisted beats were compared with nonstimulated beats. LDM stimulation caused significant increases in pressure and flow in the vascular delay group. At 20 Hz-4 volts, absolute increases were LVP (10.2 +/- 0.6) mm Hg, AoP (9.8 +/- 1.7) mm Hg, SV (1.8 +/- 0.4) ml, SW (5.3 +/- 1.0) gm x m, SP (40.8 +/- 12.7) gm x m/sec, max LV dP/dt (104.8 +/- 53.2) mm Hg/sec, and peak aortic flow (0.9 +/- 0.3) L/min. At 33 Hz-4 volts, the absolute increases were LVP (13.6 +/- 1.3) mm Hg, AoP (12.1 +/- 2.4) mm Hg, SV (2.7 +/- 0.7) ml, SW (7.4 +/- 1.4) gm x m, SP (72.7 +/- 16.5) gm x m/sec, max LV dP/dt (294 +/- 19) mm Hg/sec, and peak aortic flow (1.8 +/- 0.5) L/min. At 50 Hz-10 volts, the absolute increases were LVP (17.7 +/- 0.7) mm Hg, AoP (21.1 +/- 1.9) mm Hg, SV (6.0 +/- 1.1) ml, SW (14.6 +/- 2.2) gm.m, SP (128.2 +/- 15.3) gm x m/sec, max LV dP/dt (352 +/- 62) mm Hg/sec, and peak aortic flow (3.3 +/- 0.4) l/min (p < 0.05). The percentage increases were significantly larger in the vascular delay group compared with controls at 50 Hz-10 volts LDM stimulation. By using a two-stage vascular delay procedure, LDM stimulation can provide meaningful cardiac assistance during training periods. Furthermore, brief periods of maximal potential benefit (demand cardiomyoplasty) can be achieved during the training period.

Vascular delay and intermittent stimulation: keys to successful latissimus dorsi muscle stimulation

BACKGROUND

The goal of this study was to obtain physiologically significant increases in peak left ventricular (LV) systolic pressure and stroke volume with latissimus dorsi muscle (LDM) stimulation in cardiomyoplasty (CMP). We hypothesized that preserving LDM integrity by vascular delay and intermittent stimulation would significantly increase LDM cardiac assistance.

METHODS

In 4 control dogs and 12 dogs that had undergone a vascular delay (VD) procedure, LV dysfunction was induced by intracoronary microsphere injections. Cardiomyoplasty surgery was performed 14 days later, followed by progressive LDM conditioning. In the control dogs and in 6 of the VD dogs, the LDM was stimulated 24 hours per day (VD plus constant stimulation [CS]). In the other 6 VD dogs, LDMs were stimulated on a daily schedule of 10 hours on and 14 hours off (VD plus interrupted stimulation [IS]). Latissimus dorsi muscle stimulated beats were compared with nonstimulated beats 9 weeks later.

RESULTS

In the control dogs, LDM stimulation had minimal effects. In VD + CS and VD + IS, LDM stimulation increased peak LV pressure, stroke volume, stroke work, and stroke power (p < 0.05). However, these changes were greater in the VD + IS group, in which LDM stimulation increased peak aortic pressure by 17.6 +/- 1.7 mm Hg, peak LV pressure by 19.7 +/- 1.1 mm Hg, peak positive LV dp/dt by 398 +/- 144 mm Hg per second, stroke volume by 5.1 +/- 0.7 mL, stroke work by 10.9 +/- 0.9 gm.m, and stroke power by 122.7 +/- 11.6 gm.m per second (p < 0.05 compared with VD + CS). Quantitative morphometric analysis showed minimal LDM degeneration in the VD + IS group (7.5% +/- 1.1%), and VD + CS group (10.5% +/- 4.5%) compared with the control group (29.5% +/- 4.5%, p < 0.05).

CONCLUSIONS

VD and IS considerably increased the LV assistance with LDM stimulation. Further studies of this combined approach to CMP should be planned.

Chemoreflexes: an experimental study

HYPOTHESIS

Transmyocardial laser revascularization (TMLR) will not denervate the heart, because it does not destroy all of the afferents. This study was designed to determine if stimulation of cardiac sympathetic and vagal afferents from an area of the left ventricle treated with TMLR could evoke reflex effects, and thus whether TMLR would denervate the heart.

METHODS

The effect of TMLR on reflexes evoked by chemically stimulating cardiac afferents was examined in 9 dogs. Bradykinin and capsaicin were applied topically or injected into the left anterior descending coronary artery before and after TMLR and after bilateral vagotomy and sympathectomy. Aortic (AoP) and left ventricular pressures (LVP) and electrocardiography were monitored. The first derivatives of LVP (dP/dt) were calculated.

RESULTS

Topical bradykinin elicited variable hemodynamic responses. Topical capsaicin evoked pressor responses, increasing mean (+/- SEM) AoP (105+/-9 to 115+/-9 mm Hg; P<.001) and positive dP/dt (+dP/dt) (1032+/-81 to 1159+/-10 mm Hg/s; P<.01) before TMLR. Intracoronary capsaicin evoked a depressor response before TMLR. Pressor responses remained intact after TMLR with increases in mean AoP and +dP/dt (115+/-6 to 128+/-5 mm Hg and 1039+/-98 to 1136+/-100 mm Hg/s, respectively; P<.01). Depressor responses also remained intact after TMLR (91+/-10 vs 101+/-11 mm Hg [P<.02], and 865+/-104 vs 931+/-104 mm Hg/s [P<.05], respectively). Hemodynamic responses were diminished after bilateral vagotomy and abolished after bilateral sympathectomy.

CONCLUSION

Since activation of cardiac afferent nerves and reflex responses remained intact after TMLR, but changed after vagotomy or sympathectomy, TMLR does not denervate the heart sufficiently to be the cause of improved angina after TMLR.

Evaluation of stimulation parameters on aortomyoplasty, using Latissimus Dorsi muscle in a goat model: an acute study

OBJECTIVE

Dynamic aortomyoplasty using Latissimus Dorsi muscle (LDM) has been shown to improve myocardial function. However, systematic examination of the effects of stimulation parameters on aortic wrap function has not been done. Thus, the present study measures the direct effect of stimulation voltage, pulse train duration, frequency of the pulses, and the duration of the stimulation delay from R wave on the aortic wrap function.

METHODS

In eight female goats, the left LDM was wrapped around the descending aorta. The muscle was then subjected to electrical stimulation, altering frequency of stimulation pulses (16.6, 20, 25, 33 and 50 Hz), amplitude (2, 4, 6, 8 and 10 V), and number of pulses (2, 4, 6, 8 and 10 pulses) in a train stimulation. Left ventricular, aortic pressure, and pressure generated by LDM on aorta (wrap pressure) was measured. The changes in hemodynamic parameters mentioned above were calculated and compared for different stimulation parameters during unassisted and assisted cardiac cycles.

RESULTS

Aortomyoplasty counterpulsation using LDM provided significant improvement in wrap pressure (78 mmHg +/- 2), aortic diastolic pressure, and changes in aortic diastolic pressure from 2 to 4 V (P < 0.05). Further increase in amplitude did not make any significant improvements of the above mentioned parameters. Significant augmentation of wrap pressure (82 mmHg +/- 2), aortic diastolic pressure (79 mmHg +/- 3) and changes in aortic diastolic pressure (12 mmHg +/- 1) occurred at 6 pulses (P < 0.05). Other changes in number of pulses did not show any significant improvements. Significant improvement of wrap pressure (80 mmHg +/- 2), aortic diastolic pressure (73 mmHg +/- 3) and changes in aortic diastolic pressure (12 mmHg +/- 1) was observed with a frequency of 33 Hz. To examine a wide range of delays from the onset of the QRS complex to LDM stimulation, stimulation was delivered randomly. The exact delay was determined from the ECG signal and superimposed LDM stimulation pulses.

CONCLUSIONS

In this study we present a new measurement, wrap pressure. We also present that in aortomyoplasty using LDM, the most significant improvement in wrap pressure, aortic diastolic pressure and changes in aortic diastolic pressure occurs when the stimulation consists of an amplitude of 4 V, a frequency of 33 Hz and a train stimulation of 6 pulses.

Two step cardiomyoplasty with vascular delay: effect of stimulation of latissimus dorsi muscle on diastolic function

A common concern in cardiomyoplasty is whether latissimus dorsi muscle (LDM) stimulation impairs diastolic function. This study determined the time course of left ventricular (LV) contraction and relaxation and their relationship to the diastolic function. Ten mongrel dogs underwent vascular delay of the left latissimus dorsi muscle 2 weeks before cardiomyoplasty. Fourteen to 18 days later, the effects of LDM stimulation were evaluated. Our study demonstrated that LDM stimulation significantly increased peak LV systolic pressure (131.3 +/- 7.5 to 152.0 +/- 7.5* mm Hg), +dP/dt (1585 +/- 151 to 2088 +/- 176 x mm Hg/s), stroke volume (10.8 +/- 1.5 to 13.8 +/- 1.9* ml), stroke work (17.2 +/- 2.7 to 25.6 +/- 3.8* gm x m), and peak aortic flow (4751 +/- 698 to 6712 +/- 926* ml/min), and significantly decreased the pre-ejection time (113.9 +/- 12.6 to 92.3 +/- 7.8* ms) and total systolic time (366.0 +/- 26.9 to 333.6 +/- 21.3* ms) (*p < 0.05). As for diastolic function, LDM stimulation decreased -dP/dt (-1462 +/- 116 to -1781 +/-116* mm Hg/s) and tau (64.0 +/- 6.1 to 52.1 +/- 2.9* ms). The diastolic filling time (Tdf) was significantly longer (177.9 +/- 17.6 to 213.7 +/- 18.7* ms) during the beat immediately after LDM stimulation. These changes reflected an overall stronger contraction and faster relaxation. Our results imply that with vascular delay, stimulation of LDM not only assists systolic function but also improves diastolic function in cardiomyoplasty.

Evaluation of the long-term effectiveness of extraluminal and intraluminal vasodilators in an in vitro porcine model of arterial graft spasm

OBJECTIVE

Postoperative graft spasm is a concern when arterial conduits are used because there may be insufficient arterial graft flow. Intraoperatively, vasodilators are used to increase flow and prevent spasm, but little is known about their duration of effectiveness.

METHODS

To examine this we attached porcine gastroepiploic and internal thoracic arteries (GEA, n = 48; ITA, n = 24, 10-12 cm long) to a computer-controlled perfusion system (constant inflow pressure 80 mm Hg) with a fixed outflow resistance. Norepinephrine (10(-9)-10(-5) M) was incrementally added to the perfusate at baseline (B), then immediately (h+0) and 2 h (h+2) after the vessels were treated with 30 min of extraluminal or intraluminal nitroglycerin, nitroprusside, verapamil or papaverine.

RESULTS

At (B), norepinephrine caused a dose-dependent decrease in flow in both the ITAs and GEAs. In the ITAs, at (h+0), both extraluminal and intraluminal papaverine and, to a lesser extent nitroprusside, increased initial flow and decreased graft sensitivity to norepinephrine. At (h+2), only extraluminal papaverine sustained this maximal effect (ED50 for extraluminal papaverine at (B) 2.6 E(-7) vs. (h+2) 1.3 E(-6), P = 0.01). For the GEAs, at (h+0), both extraluminal and intraluminal verapamil, papaverine, nitroprusside and nitroglycerin attenuated flow reduction due to norepinephrine. At (h+2), only extraluminal papaverine, extraluminal verapamil and intraluminal verapamil were effective in preventing norepinephrine-induced spasm (ED50 for extraluminal papaverine at (B) 1.0 E(-7) vs. (h+2) 6.4 E(-6) (P = 0.004); extraluminal verapamil at (B) 1.2 E(-7) vs. (h+2) 4.0 E(-6); intraluminal verapamil at (B) 5.8 E(-7) vs. (h+2) 5.7 E(-6), P = 0.005).

CONCLUSION

Verapamil-and papaverine-treated arteries have a greater duration of efficacy in resisting spasm than arteries treated with nitroglycerin and nitroprusside. In the ITA, extraluminal administration of papaverine is most efficacious, possibly due to the prolonged exposure afforded by this route of administration. The effects of verapamil and papaverine are more prolonged in the GEA when administered extraluminally, potentially due to absorption in the perivascular fat-pad and subsequent slow release. The results of this study suggest that extraluminally administered verapamil and papaverine appear to be the preferred vasodilators for preventing arterial graft spasm in the postoperative period. This may be especially important when multiple arterial grafts are used.

Vascular delay of the latissimus dorsi provides an early hemodynamic benefit in dynamic cardiomyoplasty

OBJECTIVES

Dynamic cardiomyoplasty (CMP) as a surgical treatment for chronic heart failure improves functional class status for most patients. However, significant hemodynamic improvement with latissimus dorsi muscle (LDM) stimulation has not been consistent. The current protocols do not allow early LDM stimulation after CMP surgery. We hypothesized that vascular delay of LDM would increase myocardial assistance after CMP and allow early (48-h) LDM stimulation after CMP.

METHODS

Mongrel dogs (n = 24) were divided in four groups: 1) controls (n = 6), single-stage CMP; 2) Group ES (n = 6), single-stage CMP with early LDM stimulation beginning 48 h, postoperatively; 3) Group VD (n = 6), vascular delay of the LDM followed by CMP without early LDM stimulation, and 4) Group VDES (n = 6), vascular delay of LDM (14-18 days), followed by CMP with early stimulation (48 h postoperatively). Two weeks after CMP, global cardiac dysfunction was induced by injecting microspheres into the left coronary artery. LDM-assisted (S) beats were compared with nonstimulated beats (NS) by measuring aortic pressure (AoP), LV pressure, aortic flow, and by calculating first derivative of LV contraction (+/-dP/dt), stroke volume (SV), and stroke work (SW).

RESULTS

In ES, LDM stimulation had no effect on the hemodynamic parameters. In the other groups, LDM stimulation significantly (p < 0.05) increased AoP, LVP, dP/dt, SV, and SW. However, these increases were much larger in VD and VDES. In VD, LDM stimulation increased peak AoP by 21.5+/-3.8 mm Hg, LVP by 22.1+/-4.1 mm Hg, dP/dt by 512+/-163 mm Hg/sec, SV by 10.4+/-2.3 mL, and SW by 22.1+/-5.4 g/m(-1). Similarly, in VDES, LDM stimulation increased peak AoP by 24.1+/-4.7 mm Hg, LVP by 26.2+/-4.3 mm Hg, dP/dt by 619+/-47 mm Hg/sec, SV by 6.5+/-0.7 mL, and SW by 16.7+/-4.1 g/m(-1).

CONCLUSIONS

In dogs with global LV dysfunction, CMP after vascular delay resulted in a significant improvement in hemodynamic function measured 2 weeks after surgery. This improvement was not provided by single-stage CMP with or without early stimulation. Vascular delay of the LDM before surgery may play an important role for early benefit after CMP, shorten the overall muscle training period, as well as increase hemodynamic response to LDM stimulation.

Estimation of oxygen delivery in newborns with a univentricular circulation

BACKGROUND

The management of neonates with complex congenital anomalies depends on careful interpretation of arterial blood gas values. Improved interpretation of these oxygen parameters may allow clinicians to avoid unexpected cardiovascular events. This study examined whether systemic oxygen delivery (DO2) can be maximized by the use of indices derived from oxygen saturation measurements in neonates with hypoplastic left heart syndrome.

METHODS AND RESULTS

For the single-ventricle heart with both circulations in parallel, we used a previously developed computer simulation to obtain DO2 as a function of systemic arterial (SaO2) and venous (SvO2) oxygen saturation, arteriovenous oxygen difference (Sa-vO2), or pulmonary-to-systemic flow ratio (Qp/Qs). We also examined the oxygen excess factor, SaO2/Sa-vO2 (Omega). We found that (1) slight increases in SaO2 may be associated with large decreases in DO2. (2) Low values for SvO2 indicate low values for DO2. (3) Curves for Sa-vO2 and Qp/Qs are redundant in the data provided. (Qp/Qs, however, provides these data in more physiologically relevant terms.) (4) High values for Qp/Qs (>4) are associated with low DO2. (5) Estimating Qp/Qs from oxygen saturation measurements may result in errors when pulmonary venous oxygen saturation is not available. (6) Maximizing DO2 is extremely difficult using SaO2, SvO2, and Qp/Qs. (7) A linear relationship exists between Omega and DO2, and this linear relationship is not altered by changes in cardiac output.

CONCLUSIONS

Patients with low SvO2 values require attention. Ideally, after reducing Qp/Qs to <1.5, Omega might be a better index to guide further therapy and maximize DO2. Interventions that increased Omega would be considered beneficial, whereas interventions that decreased Omega would be considered detrimental.

Preconditioning of the latissimus dorsi muscle in cardiomyoplasty: vascular delay or chronic electrical stimulation

OBJECTIVES

In standard single stage cardiomyoplasty (CMP), the latissimus dorsi muscle (LDM) is not preconditioned prior to surgery. We hypothesized that latissimus dorsi preconditioning by vascular delay or by chronic electrical stimulation would result in an improved LV hemodynamic function early (14 days) after CMP.

METHODS

Mongrel dogs had preconditioning of the latissimus dorsi by a vascular delay procedure followed by CMP 14-18 days later (group I VD). Dogs in group II underwent 4 weeks of chronic stimulation (CS) of the latissimus dorsi (2 V/30 Hz, six bursts/min) followed by CMP. The latissimus dorsi muscle was fully stimulated from 48 h after cardiomyoplasty in both groups (2 V/30 Hz, three bursts/min). Two weeks after myoplasty, injecting 2.0-3.0 x 10(5) 90 microm latex microspheres in the left main coronary artery induced global cardiac dysfunction. Hemodynamic function was then evaluated for latissimus dorsi muscle assisted (S) beats and non-stimulated beats (NS) in each group by measuring peak systolic aortic pressure (AOP), left ventricular pressure (LVP) and end diastolic pressure (LVEDP), and by calculating maximum and minimum dP/dt.

RESULTS

Dogs with vascular delay of the latissimus dorsi showed a marked increase for all hemodynamic indices (AOP: 23.9+/-2.5%, LVP: 23.5+/-2.2%, max dP/dt: 49.4+/-3.3%) for LDM assisted (S) beats compared to non-stimulated beats (P < 0.001). Animals with chronic electrical training did not demonstrate a significant increase in any hemodynamic parameter with LDM stimulation.

CONCLUSION

Preconditioning the LDM may play an important role in providing early cardiac assistance in CMP. Preconditioning the LDM with vascular delay resulted in improving performance of the LDM with consistent increases in LV hemodynamics. This was not observed after preconditioning with chronic electrical stimulation. Vascular delay of the latissimus dorsi can significantly improve muscle performance in CMP and could provide hemodynamic assistance early after surgery.

Theoretical optimization of pulmonary-to-systemic flow ratio after a bidirectional cavopulmonary anastomosis

A univentricle with parallel pulmonary and systemic circulations is inherently inefficient because mixing of pulmonary and systemic venous return occurs. Thus a cavopulmonary anastomosis is used as a staged palliative procedure to reduce volume overload in patients with cyanotic congenital heart disease. On the basis of oxygen uptake and consumption, an equation was derived that related cardiac output, pulmonary venous oxygen saturation, upper body oxygen consumption, and superior-to-inferior vena caval blood flow ratio (QSVC/QIVC) to oxygen delivery. The primary findings were as follows. 1) As QSVC/QIVC increases, total body oxygen delivery and arterial and superior vena caval oxygen saturations increase. 2) As QSVC/QIVC increases, lower body oxygen delivery and inferior vena caval oxygen saturation initially increase, then peak, and then decrease. 3) As the percentage of lower body oxygen consumption increases, oxygen delivery and saturation decrease. 4) A cavopulmonary anastomosis decreases the required cardiac output for a given oxygen delivery. Thus we concluded that a high systemic arterial oxygen saturation after cavopulmonary anastomosis requires a high percentage of upper body oxygen consumption and a high QSVC/QIVC and that the cavopulmonary anastomosis reduces the volume load on the single ventricle.

Can indices of left ventricular function be applied to the right ventricle?

This article compares conventional indices of contractile function in the right and left ventricles. The low operating pressures and left ventricles. The low operating pressures and complex geometry complicate evaluation of right ventricular function. However, when the characteristics of its vascular load are taken into account, the complex right ventricular chamber has pump properties that are similar to the high pressure left ventricular chamber.

Ventricular interdependence: significant left ventricular contributions to right ventricular systolic function

This article reviews diastolic and systolic ventricular interaction, and clinical pathophysiological conditions involving ventricular interaction. Diastolic ventricular interdependence is present on a moment-to-moment, beat-to-beat basis, and the interactions are large enough to be of physiological and pathophysiological importance. Although always present, ventricular interdependence is most apparent with sudden postural and respiratory changes in ventricular volume. Left ventricular function significantly affects right ventricular systolic function. Experimental studies have shown that about 20% to 40% of the right ventricular systolic pressure and volume outflow result from left ventricular contraction. This dependency of the right ventricle on the left ventricle helps to explain the right ventricular response to volume overload, pressure overload, and myocardial ischemia. The septum and its position are not the sole mechanism for ventricular interdependence. Ventricular interdependence causes overall ventricular deformation, and is probably best explained by the balance of forces at the interventricular sulcus, the material properties, and cardiac dimensions.

Effects of positive pressure ventilation and inspired oxygen on pulmonary vascular resistance and tissue oxygen delivery in neonatal pigs

Management of pulmonary vascular resistance in neonates with congenital heart disease is important for stabilization before and after surgical interventions. Thus, we determined which combination of positive end-expiratory pressure ventilation and fraction of oxygen in the inspired air increases pulmonary vascular resistance without compromising delivery of oxygen to the tissue. Eight piglets were anesthetized, intubated and ventilated. Pulmonary flow and pulmonary arterial and left atrial pressures were monitored continuously. At all levels of inspired oxygen (1.00, 0.21 and 0.15), ventilation at a pressure of 15 cm of water increased pulmonary vascular resistance. At all levels of positive pressure ventilation, a fraction of 0.15 of inspired oxygen increased pulmonary vascular resistance. The combination of a ventilatory pressure of 15 cm of water and inspired oxygen of 1.00, or ventilatory pressure at 5 cm of water and oxygen delivery of 0.15, produced similar changes in pulmonary vascular resistance (19.1 +/- 2.8 vs. 20.0 +/- 3.8 mmHg/(L/min)) and cardiac output (0.78 +/- 0.07 vs. 0.93 +/- 0.10 L/min) but, the higher level of positive pressure plus 1.00 inspired oxygen gave a significantly higher arterial oxygen saturation (0.99 +/- 0.03 vs. 0.72 +/- 0.19%) and delivery of oxygen to the tissues (13.7 +/- 2.9 vs. 7.4 +/- 1.5 ml O2/min, p < 0.05). Thus, both high positive pressure ventilation and hypoxia increase pulmonary vascular resistance. Only high pressure ventilation plus high concentrations of inspired oxygen, however, increased pulmonary vascular resistance without compromising delivery of oxygen, suggesting that this combination is a superior means of increasing pulmonary vascular resistance.

A versatile microprocessor-based multichannel stimulator for skeletal muscle cardiac assist

A versatile, microprocessor-based stimulator for skeletal muscle cardiac assist (SMCA) has been designed, constructed, and used in several studies. The stimulator uses multiple bipolar electrodes to deliver arbitrarily specified electrical stimulus sequences to three nerve branches of the latissimus dorsi muscle. The electrodes are electrically isolated to effect regional stimulation of the muscle. The width, amplitude, and interpulse interval of each pulse in the stimulus sequence are independently variable, and the three channels are independently programmable, allowing a wide variety of stimulus patterns. Battery powered units have been used in studies for up to one year. In this paper, the stimulator and sample applications in SMCA are described.

Variable effects of cardiomyoplasty on left ventricular function

Cardiomyoplasty (CMP) has been considered as a possible treatment for patients with heart failure. Symptomatic improvements occur almost uniformly among survivors with CMP, but changes in left peak ventricular systolic pressure (PVSP) and stroke volume vary in patients. This study examined whether there is variability present shortly after cardiomyoplasty surgery. Cardiomyoplasty was performed in 11 mongrel dogs with normal ventricular function. Nine to twelve days after CMP, left ventricular (LV) function was evaluated by simultaneously measuring LV volume (conductance catheter) and pressure (Millar catheter). The latissimus dorsi muscle (LDM) was stimulated synchronously with ventricular systole in a ratio of 1:4 to 1:7 to avoid muscle fatigue. Data were analyzed on a beat by beat basis. The PVSP, and maximum dP/dt (+dP/dt) increased, but the absolute value of minimum dP/dt (-dP/dt) decreased in stimulated beats in 7 dogs while 4 dogs did not respond. The net changes in stimulated beats versus nonstimulated beats of PVSP were 6.1 +/- 1.8 mm Hg (4.3%), of stroke work was 4.5 +/- 1.9 gm x m (29.5%), of +dP/dt was 185 +/- 47 mm Hg/s (8%), and of -dP/dt was 168 +/- 43 mm Hg/s (7.8%) (p < 0.05) for all these net changes in the responding group while these variations were not significant in the nonresponding group. From the results of our study, active LDM assist improves left ventricular systolic function, occurring in only 7 of 11 experiments. This improvement is inconsistent and varied individually. The integrity of the LDM, tightness of wrapping, and adhesions might contribute to the variability which is present early after surgery and before the LDM is converted into a fatigue resistance muscle.

Overcoming right ventricular failure with left ventricular assist devices

BACKGROUND

Right ventricular failure can lead to circulatory collapse while on left ventricular assist device support. By shunting blood from the femoral vein to the left ventricular assist device, cardiac output can be increased, but arterial oxygen saturation will decrease.

METHODS

To determine the effects on O2 delivery, a model was developed on the basis of O2 uptake in the lungs and whole body O2 consumption. An equation was derived that related cardiac output, pulmonary venous O2 saturation, O2 consumption, and the ratio of shunt-to-systemic blood flow to systemic O2 delivery.

RESULTS

When total cardiac output increases, the shunt will increase systemic O2 delivery while decreasing arterial O2 saturation and leaving systemic venous O2 saturation unaltered. When total output does not increase, the shunt will decrease systemic O2 delivery, arterial O2 saturation, and systemic venous O2 saturation.

CONCLUSIONS

The analysis suggests that measuring systemic venous oxygen saturation may be a useful way to monitor patient safety. A decrease in systemic venous O2 saturation when creating the shunt implies an inadequate increase in cardiac output.

Variable-frequency train stimulation of canine latissimus dorsi muscle during shortening contractions

In cardiomyoplasty, the latissimus dorsi muscle (LDM) is wrapped around the heart ventricles and electrically activated with a constant-frequency train (CFT). This study tested the hypotheses that increased mechanical performance from the LDM could be achieved by activating the muscle with variable-frequency trains (VFTs) of shorter duration or containing fewer stimulus pulses than the CFT now used. The mechanical performance of the canine LDM (n = 7) during shortening contractions was measured while the muscle was stimulated with 5- and 6-pulse CFTs (of duration 132 and 165 ms, respectively) and 5- and 6-pulse VFTs (of duration 104 and 143 ms, respectively) that were designed to take advantage of the catchlike property of skeletal muscle. Measurements were made from fresh and fatigued muscles. For the fresh muscles, the VFTs elicited significantly greater peak power than did the 6-pulse CFT. When the muscles were fatigued, VFT stimulation significantly improved both the peak and mean power produced compared with stimulation by CFTs. These results show that stimulation of the LDM with shorter duration VFTs is potentially useful for application in cardiomyoplasty.

Cardiomyoplasty: hemodynamic benefit to normal and depressed canine left ventricular function

This study examined the effects of cardiomyoplasty with vascular delay on canine normal and depressed left ventricular (LV) function. To improve viability of the latissimus dorsi muscle (LDM), vascular delay was performed 2 weeks before cardiomyoplasty in 10 mongrel dogs. Two weeks after cardiomyoplasty, LV function was evaluated by simultaneously measuring LV and aortic pressure, and aortic flow. The LDM was stimulated at a ratio of 1:4-1:7 synchronously with ventricular systole. Microspheres (90 mu) were sequentially injected into the left coronary artery to depress LV function. Data were acquired and analyzed on a beat to beat basis. Results were as follows: LDM stimulation significantly augmented LV systolic pressure (LVSP) from 138 +/- 2 to 161 +/- 2* mmHg, the peak rate of change of LV pressure (+dP/dt) from 1888 +/- 46 to 2584 +/- 43* mmHg/sec, aortic systolic pressure (AoSP) from 140 +/- 2 to 159 +/- 2* mmHg, stroke volume (SV) from 11.2 +/- 0.3 to 13.3 +/- 0.3* ml, stroke work (SW) from 19 +/- 1 to 26 +/- 1* gm.m, peak aortic flow (P Qa) from 5542 +/- 142 to 7190 +/- 161* ml/min, and decreased -dP/dt from -1683 +/- 31 to -1689 +/- 49* mmHg/sec (* = p < 0.05). Microsphere injections depressed LV function, but did not affect the magnitude of the net changes between stimulated and nonstimulated beats. However, the percent changes significantly increased. Preconditioning of LDM with vascular delay augments cardiac function in LDM assisted beats. This improved performance was present in both normal as well as depressed LV function groups. Thus, investigations of cardiomyoplasty may not necessarily require a model of severe myocardial dysfunction. Vascular delay offers an important preconditioning method of LDM to augment cardiac function in cardiomyoplasty.

What in-vitro method should surgeons use to evaluate the clinical behavior of arterial bypass conduits

Surgeons have traditionally relied on ring preparations to predict how arterial bypass conduits will behave in the postoperative circulation.

OBJECTIVE

This study compared pharmacologic [norepinephrine (NE) challenge] and physiologic [arterial preload] responses of gastroepiploic (GEA) and internal thoracic (ITA) arteries in a standard static ring preparation and a dynamic perfusion system.

METHODS

Six GEAs (1.0-1.5 mm dia.) and six ITAs (1.5-2.0 mm dia.) 11 cm long were harvested from adult pigs and mounted on a computer controlled perfusion system. Inflow pressure was set at 80 mmHg and outflow resistance was adjusted to simulate high (80-90 ml/min) and low (15-20 ml/min) flow demands. NE response (10(-9)-10(-5) M) was measured under low flow conditions and at high flow conditions when distal arterial pressure (load) was reduced. NE response (10(-9)-10(-5) M) was also evaluated in arterial rings (ITA N = 6, GEA N = 6) with tensions adjusted to simulate the loads occurring at low flow (80 mmHg) and high flow (60 mmHg) situations.

RESULTS

In the static ring preparation, NE response [ED50] was similar for both GEA and ITA and was not affected by load. The dynamic preparation demonstrated that the GEAs were significantly more responsive to NE than the ITAs [ED50 high flow ITA 6.1 +/- 0.3**, GEA 7.2 +/- 0.3***; *P < 0.05 versus baseline, **P < 0.05 versus low flow values, ***P < 0.05 versus ITA]. Furthermore, in the dynamic preparation, NE response was profoundly affected by reduced load which occurs under high flow conditions [7.18 +/- 0.3 versus 6.1 +/- 0.3 under high flow and 5.8 +/- 0.1 versus no response under low flow conditions].

CONCLUSION

Static ring preparations do not discern differences between ITA and GEA susceptibility to spasm and fail to detect the effect of load. The dynamic preparation demonstrated significant differences between the GEA and ITA potential to spasm which is consistent with widespread clinical experience. Furthermore a dynamic preparation is highly sensitive to reduced load which occurs under high flow conditions. Although it is more demanding, the dynamic preparation provides superior information to the surgeon in predicting the behavior of arterial bypass grafts.

Preventing gastroepiploic artery spasm: papaverine vs calcium channel blockade

The gastroepiploic artery (GEA) is a highly vasoactive artery gaining wider acceptance as a conduit for coronary artery bypass surgery. A variety of agents are used to dilate the GEA prior to grafting; however, little is known about the duration of their effect in the immediate postoperative period. This study evaluated three calcium channel blockers and papaverine in preventing graft spasm.

METHODS

Porcine GEA segments (10-12 cm in length) were connected to a computer-controlled perfusion system with a constant in-flow pressure and distal resistance to simulate bypass flow (80-100 ml/min). Norepinephrine (NE; 10(-9) to 10(-5) M) was given in incremental doses at baseline before the vasodilator, immediately after (0 hr), and again at 2 hr after the vasodilator. Changes in flow and ED50 were recorded. Group INT (N = 25) received papaverine (PAP), diltiazem, nifedipine (NFP), or verapamil (VPL) intraluminally, while group EXT (N = 25) received the same dilators externally.

RESULTS

All arteries showed dose-dependent vasoconstriction to NE prior to treatment. Immediately after receiving the vasodilator, arteries in both groups (INT and EXT) showed initial protection against NE-induced spasm with the exception of arteries receiving NFD externally. However, at 2 hr, for group INT, only VPL and NFD prevented NE-induced graft spasm (VPL: 40.4 +/- 6.8 ml/min vs 17.9 +/- 3.3 ml/min and NFD: 27.0 +/- 6.5 ml/min vs 13.1 +/- 0.9 ml/min, P < 0.02). In group EXT, after 2 hr, only VPL- and PAP-treated grafts showed resistance to NE-induced vasospasm (VPL: 35.6 +/- 7.3 ml/min vs 15.0 +/- 6.9 ml/min and PAP: 47.4 +/- 15.1 ml/min vs 8.0 +/- 2.0 ml/min, P < 0.001).

CONCLUSIONS

Papaverine, a lipophilic vasodilator, when given externally on the perivascular fat of the GEA, prevented graft spasm for up to 2 hr. In contrast, intraluminally applied papaverine did not show graft protection against NE-induced spasm. Nifedipine prevented NE-induced spasm only when given intraluminally. Verapamil proved to be the most potent and versatile vasodilator with effective graft protection of up to 2 hr whether applied externally or internally and was the preferred agent for protecting against GEA spasm.

Cardiomyoplasty

Cardiomyoplasty is a new surgical treatment for heart failure in which skeletal muscle assists the heart. However, for the first 2 weeks postoperatively, the latissimus dorsi muscle (LDM) remains unstimulated, and during the next 2 weeks, the LDM is stimulated with only one pulse every other heart beat. Thus, for the initial 4 postoperative weeks, minimal systolic assistance is provided. The present study determined if the LDM is capable of providing early assistance. Cardiomyoplasty surgery involves severing the perforating intercostal arteries to the LDM, detaching the LDM from its distal insertion, and wrapping it around the heart. At each of these steps, we measured LDM force development, shortening, and blood flow in six dogs. At control, LDM shortening, work, and power decreased during a 2 min fatigue test: fatigue indices (final/ initial value) for shortening, work, and power were 47.6 +/- 6.9%, 47.5 +/- 7.1%, and 46.9 +/- 6.6%, respectively. Blood flow increased in the proximal (P), mid (M), and distal (D) LDM during the fatigue test. After partial vascular isolation, initial shortening, work, and power decreased by 29.4%, 32.5%, and 31.7% from their respective control values. During the fatigue test, fatigue indices for shortening, work, and power were 24.7 +/- 3.3%, 19.5 +/- 4.6%, and 22.2 +/- 4.7%, respectively, all significantly (p < 0.05) less than control values. Resting blood flows were unaltered. During exercise, flow to the P increased, whereas flow did not increase in M (p < 0.05). Loss of LDM function was most apparent after mobilizing and reattaching the muscle. Initial shortening, work, and power significantly decreased (p < 0.05) by 74.1%, 76.8%, and 74.4%, from their respective control values. During a fatigue test, final values for shortening, work, and power were all near zero. Resting blood flow decreased in the M and D (p < 0.05) and, during exercise, blood flow increased only in P. Thus, LDM function was severely depressed during the isolation procedure. This functional loss is associated with inadequate blood flow responses. Therefore, preconditioning and/or revascularization is needed if the LDM is to provide cardiac assistance shortly after cardiomyoplasty surgery.

Minimally invasive coronary artery bypass grafting: on the beating heart and via limited access

Minimally invasive coronary artery bypass grafting (MICABG) may be achieved by arterial grafting on the beating heart, without cardiopulmonary bypass, and by operations via limited access. The Second Utrecht MICABG Workshop held October 4-5, 1996, focused on beating-heart coronary immobilization, limited-access thoracoscopic and direct-vision mobilization of the internal mammary artery, limited-access left anterior descending coronary artery grafting, and, finally, facilitated distal anastomosis techniques. It has yielded 33 reports in this supplement. The combined, cumulative experience of a number of participants exceeded 3,000 beating-heart cases, including more than 1,000 with arterial grafting through limited access. The average number of anastomoses per patient ranged from 1.0 to 2.0. Therapeutic strategies are evolving, and dedicated instrumentation is being developed. Randomized clinical trials with angiographic follow-up are required to establish that the reduction in invasiveness of coronary bypass grafting is not achieved at the expense of suboptimal quality of the arterial graft and the distal anastomosis.

Intraoperative monitoring of IMA flow: what does it mean?

BACKGROUND

This study examines whether the measurement of internal thoracic artery (ITA) graft flow can determine the adequacy of the ITA-left anterior descending coronary artery (LAD) anastomosis.

METHODS

To study a wide range of clinical problems, we used a computer simulation of the cardiovascular system. The model included a time-varying elastance model of the heart, a systemic circulation represented by a multielement nonlinear model of the aorta and its major branches, a nonlinear model of the LAD circulation, and a model of the ITA bypass graft.

RESULTS

With a mild LAD stenosis, ITA graft flow was low and flow reversal occurred. As the percent stenosis increased, ITA flow and the percentage of ITA-to-total LAD flow increased. The ITA graft helped to maintain resting LAD blood flow. A partial obstruction (40%) at the ITA-LAD anastomosis reduced ITA graft flow at similar levels of LAD stenosis. However, overlap in flow values comparing a normal with a partially obstructed anastomosis occurred.

CONCLUSIONS

Flow patterns in the ITA are highly dependent on the degree of stenosis of the LAD as well as the integrity of the anastomosis. The predictive power of ITA flow measurement increases with severe stenosis or total occlusion of the proximal LAD and with high coronary blood flow demands.

Monitoring systemic venous oxygen saturations in the hypoplastic left heart syndrome

Although progress has been made in treating hypoplastic left heart syndrome, improvements in perioperative care may further decrease mortality. We present a case in which continuous monitoring of systemic venous oxygen saturation allowed stabilization and successful management of a critically ill infant. Systemic venous oxygen saturation may provide a more accurate representation of a child's clinical status, allowing more rapid intervention and better outcomes.

Animal model of the univentricular heart and single ventricular physiology

The univentricular heart complexes are a fairly common and potentially lethal set of congenital cardiac anomalies. Progress in developing new therapeutics has been hampered by a lack of suitable animal models. The authors developed a stable, closed heart preparation to systematically examine potential interventions. Using neonatal piglets (3.5-6.0 kg), a 6-mm PTFE graft was anastomosed end to end to the innominate artery and end to side to the pulmonary artery. An atrial septostomy was made, using a Rashkind septostomy catheter passed transvenously. With the same catheter, the tricuspid valve was rendered incompetent. Occlusion of the right ventricular outflow tract completed a univentricular circuit. All cardiac output exited from the left ventricle, and pulmonary blood flow was maintained via the innominate artery-to-pulmonary artery shunt. Pressure transducers measured central venous (mid inferior vena cava), aortic, and pulmonary arterial pressures. Oximetric probes recorded systemic venous and arterial oxygen saturations. Transit-time flow probes measured total cardiac output and pulmonary flows. Systemic flow was calculated by subtracting pulmonary flow from total cardiac output. This model has been completed in 30 animals. Minimal pressure drops have been recorded across the innominate-to-pulmonary artery graft. Pulmonary flows up to 700 +/- 52 mL/min were seen. Total cardiac outputs are as high as 1370 +/- 88 mL/min. Mean ratios of pulmonary to systemic flow (Qp/Qs ratio) range from 1.29 +/- 0.08 to 0.41 +/- 0.09. The model allows for full continuous monitoring of systemic and pulmonary pressures and flows and for accurate characterization of the physiological effects of respiratory and pharmacological interventions. In addition, mechanical constriction of the graft may allow direct alteration of the Qp/Qs ratio, with determination of an optimum value for this ratio.

Effects of oxygen, positive end-expiratory pressure, and carbon dioxide on oxygen delivery in an animal model of the univentricular heart

OBJECTIVE

Respiratory manipulations are a mainstay of therapy for infants with a univentricular heart, but until recently little experimental information has been available to guide their use. We used an animal model of a univentricular heart to characterize the physiologic effects of a number of commonly used ventilatory treatments, including altering inspired oxygen tension, adding positive end-expiratory pressure, and adding supplemental carbon dioxide to the ventilator circuit.

RESULTS

Lowering inspired oxygen tension decreased the ratio of pulmonary to systemic flow. This ratio was 1.29 +/- 0.08 at an inspired oxygen tension of 100%, 0.61 +/- 0.09 at an inspired oxygen tension of 21%, and 0.42 +/- 0.09 at an inspired oxygen tension of 15% (p < 0.05 compared with an inspired oxygen tension of 100% and a positive end-expiratory pressure of 0 cm H2O). High-concentration supplemental carbon dioxide (carbon dioxide tension of 80 to 90 mm Hg) added to the ventilator circuit decreased inspired oxygen tension from 1.29 +/- 0.11 to 0.42 +/- 0.12 (p < 0.05 compared with baseline). A mixture of 95% oxygen and 5% carbon dioxide (carbon dioxide tension of 50 to 60 mm Hg) did not decrease the pulmonary/systemic flow ratio significantly. All three types of interventions influenced systemic oxygen delivery, which was a function of the pulmonary/systemic flow ratio. As the pulmonary/systemic flow ratio decreased from initially high levels (greater than 1), oxygen delivery first increased and reached an optimum at a flow ratio slightly less than 1. As the pulmonary/systemic flow ratio decreased further, below 0.7, oxygen delivery decreased. The ability of systemic arterial and venous oxygen saturations to predict the pulmonary/systemic flow ratio was examined. Venous oxygen saturation correlated well with both pulmonary/systemic flow ratio and systemic oxygen delivery, whereas arterial oxygen saturation did not accurately predict either pulmonary/systemic flow ratio or oxygen delivery.

CONCLUSION

This model demonstrated the value of estimating the pulmonary/systemic flow ratio before initiating therapy. When the initial ratio was greater than about 0.7, interventions that decreased the ratio increased oxygen delivery and were beneficial. When the initial pulmonary/systemic flow ratio was below 0.7, interventions that decreased the ratio decreased oxygen delivery and were detrimental. We conclude by presenting a framework to guide therapy based on the combination of arterial and venous oxygen saturations and the estimate of the pulmonary/systemic flow ratio that they provide.

Inotropes in the hypoplastic left heart syndrome: effects in an animal model

BACKGROUND

Despite substantial changes in the surgical treatment of children born with the hypoplastic left heart syndrome, overall mortality remains high. Although further improvements in outcomes appear to depend on more effective perioperative care, few experimental data exist to guide appropriate pharmacologic therapy in these infants. Because different inotropic agents may have different effects on the ratio of pulmonary to systemic flow (Qp/Qs), we hypothesize that they may not be equally effective at increasing oxygen delivery.

METHODS

In neonatal piglets (n = 6; 3.5 to 6.5 kg), we placed an innominate artery-to-pulmonary artery shunt, created an atrial septal defect, and then occluded right ventricular outflow. We examined the effects of a number of commonly used inotropic agents, administering high and low concentrations of dopamine (5 and 15 micrograms.kg-1 .min-1), dobutamine (5 and 15 micrograms.kg-1.min-1), and epinephrine (0.05 and 0.1 microgram /min).

RESULTS

Dobutamine at 15 micrograms.kg-1.min-1 increased the Qp/Qs ratio from 1.03 +/- 0.6 at baseline to 2.52 +/- 0.55 (p < 0.05) and decreased oxygen delivery from 50 +/- 4.3 to 36 +/- 1.7 mL/min (p < 0.1). The arterial-venous oxygen difference increased as oxygen delivery went down, going from 44% +/- 1% to 48% +/- 2% (p < 0.1). Epinephrine at 0.1 microgram.kg-1.min-1 decreased the Qp/Qs ratio from 1.23 +/- 0.21 to 0.82 +/- 0.08 (p < 0.05) and increased oxygen delivery from 40 +/- 9.7 to 56 +/- 1.7 mL/min (p < 0.05). Systemic venous oxygen saturation increased from 36% +/- 4.8% to 50% +/- 8.6% (p < 0.05). Although dopamine decreased the Qp/Qs ratio and increased oxygen delivery, these changes were not statistically significant.

CONCLUSIONS

Dopamine, dobutamine, and epinephrine all increased cardiac output but had substantially different effects on the Qp/Qs ratio and on oxygen delivery, possibly due to differential effects on systemic and pulmonary vascular resistances. This suggests that inotropic agents may not be equally beneficial in the clinical setting. Systemic venous oxygen saturation and the arteriovenous oxygen difference may help determine if a given inotrope improves oxygen delivery.

Examination of epimysial leads used to stimulate the latissimus dorsi muscle

Cardiomyoplasty is a new surgical treatment for heart failure in which the patient's latissimus dorsi muscle (LDM) is isolated, wrapped around the heart, and electrically stimulated to provide cardiac assistance. At present, long term stimulation of the LDM is achieved with intramuscular electrodes, which produce minimal nerve damage. This study examined the use of epimysial electrodes by measuring the epimysial lead characteristics during a four-week LDM training. Lead resistance started at 463 +/- 41 omega after implantation, decreased during the following week (251 +/- 16 omega), and remained less than the initial value during the last three weeks (weeks two: 282 +/- 19 omega and week four: 341 +/- 28 omega). The recruitment properties were similar to nervecuff electrodes: low threshold voltages (week one: 0.75 +/- 0.12, week two: 0.90 +/- 0.33, week four: 0.52 +/- 0.10 V) and a very steep recruitment curve with low saturation voltages. Histological examination revealed normal muscle fibers with no inflammatory response. Epimysial leads may be more convenient for most surgeons because the design does not require any free-dissection of the nerve nor guiding a needle around the nerve with the risk of perforating vessels or nerve branches. These results indicate that epimysial leads are worthy of further investigation.

Left ventricular contributions to right ventricular systolic function during LVAD support

BACKGROUND

In patients with postcardiotomy low cardiac output syndromes, right ventricular (RV) failure develops in approximately 25% of patients receiving left ventricular (LV) assist device support. Depressed RV function have been attributed to abnormalities of the RV myocardium, excessive load imposed on the RV during systole or diastole, or obstruction to RV inflow. However, recent studies also suggest that LV function may significantly affect RV function through ventricular interdependence.

METHODS

We reviewed the data showing the importance of systolic ventricular interaction. We then related these observations to the RV response during LV assist device support, and present our ideas regarding the mechanisms responsible for this RV failure.

RESULTS

Using an electrically isolated right heart preparation, Damiano observed double-peaked waveforms for RV pressure, and pulmonary artery blood flow occurred over a wide range (0 to 300 ms) of pacing intervals between the LV and RV. Numeric analysis indicated that RV systolic pressure and pulmonary artery blood flow were composed of both RV and LV components, with the LV component dominating (63.5% versus 36.5%).

CONCLUSIONS

The experimental studies indicate a very consistent RV response during LV assist device support: a decrease in RV afterload, increased compliance, and decreased contractility. In normal hearts, the net effect is an increase or no change in cardiac output. With a preexisting pathologic condition, the RV responses is qualitatively the same, but anatomic ventricular interaction is accentuated, leading to a greater decrease in RV contractility. The net effect is a decrease in cardiac output, which may require inotropic or RV mechanical support.

Arterial bypass graft spasm: an examination of the role of high flow demands and endothelial function in the porcine GEA

This study examined why an artery becomes vulnerable to spasm when used as a bypass graft. We hypothesized that high flow demands would decrease pressure distally in the conduit (afterload), thus increasing the sensitivity to vasoconstrictors. Furthermore, perioperative endothelial dysfunction would additionally sensitize the artery to constrictors. Six gastroepiploic arteries (GEA, 1.0-1.5 mm diameter, 11 cm length) were harvested from adult pigs (110-125 kg) and mounted on a computer-controlled perfusion system. The inflow pressure was set at 80 mmHg and outflow resistance was adjusted to simulate normal (in situ) or high (coronary bypass graft) flow demands. Gastroepiploic flow and distal pressures were measured at baseline [B] and after adding norepinephrine (NE, 10(-9) M to 10(-5) M). Under normal flow demand, a minimal pressure drop existed across the GEA and flow decreased only at high NE concentrations. High flow demand decreased distal GEA pressure and increased the sensitivity to NE. To block endothelial function N-Monomethyl-L-Arginine, Monoacetate (L-NMMA, 10(-5) M) was then added. Under high flow demand, blocking endothelial function resulted in an additional fivefold increase in sensitivity to NE (ED50 from 9.75 10(-8) M to 2.11 10(-8) M, P < 0.05). It was shown that in long narrow arterial grafts, high flow demands cause cumulative pressure losses. Even with normal endothelial function, these pressure losses render the artery responsive to vasoconstrictors. Endothelial dysfunction additionally increases the sensitivity of the artery. Anastomosis of a small arterial graft to a large myocardial perfusion bed may result in reduced distal conduit pressure and may predispose to the development of myocardial ischemia even when low doses of vasoconstrictors are used. Perioperative endothelial dysfunction may exacerbate this effect.

High flow demand on small arterial coronary bypass conduits promotes graft spasm

Despite the superior long-term patency of arterial grafts, surgeons are often reluctant to use arterial grafts on coronary vessels that supply large areas of myocardium because postoperative shock may occur. We hypothesized that supramaximal flow through small arterial conduits would decrease distal intraluminal pressure, thereby reducing afterload on the smooth muscle and rendering the arterial graft vulnerable to spasm. Fourteen internal thoracic and eight gastroepiploic arteries were harvested from adult pigs (220 to 250 pounds). Arteries were mounted on a computer-controlled perfusion system with inflow pressure at 80 mm Hg and outflow resistance adjusted to simulate normal (in situ) or supramaximal (coronary artery bypass graft) flow demands. Artery pressures and flow rates were measured at baseline and after norepinephrine was added to the system. Internal thoracic arteries had no hemodynamic response to norepinephrine at normal flow. Under supramaximal flow demands, large internal thoracic arteries (2.5 to 3.0 mm) had no hemodynamic response to norepinephrine. However, for small internal thoracic arteries (2.1 to 2.9 mm), norepinephrine reduced distal internal thoracic arterial pressure (63.2 +/- 2.2 to 27.0 +/- 1.9 mm Hg) and flow rate (99.4 +/- 5.0 to 45.4 +/- 2.7 ml/min, median effective dose = 9.12 x 10(-9) mol/L). Under normal flow demands, the flow rate in gastroepiploic arteries (1.0 to 2.0 mm diameter) decreased (14.1 +/- 0.5 to 4.8 +/- 0.8 ml/min, p < 0.05) only at high concentrations of norepinephrine (median effective dose = 1.26 x 10(-6) mol/L). Supramaximal flow demands reduced distal gastroepiploic arterial pressure (77.5 +/- 0.5 to 49.5 +/- 3.8 mm Hg, p < 0.05), which resulted in a greater decrease in flow rate (80.0 +/- 3.7 to 6.8 +/- 1.6 ml/min, p < 0.05) at lower concentrations of norepinephrine, (median effective dose = 3.24 x 10(-8) mol/L, p < 0.05). In four studies in internal thoracic arteries and eight in gastroepiploic arteries, arteries were cut in half, reattached, and reperfused. The proximal half of the internal thoracic artery did not respond to norepinephrine, but the distal half had a 53% +/- 7% decrease in flow. Both gastroepiploic artery halves reacted and flow rate decreased by 88% +/- 2% (proximal half) and 89% +/- 3% (distal half). In conclusion, small arterial conduits develop large transconduit pressure gradients under supramaximal flow demands. Under these conditions, arteries are very sensitive to vasoconstrictors and flow may cease with higher drug concentrations.(ABSTRACT TRUNCATED AT 400 WORDS)

Balancing the circulation in hypoplastic left heart syndrome

A mathematical model based on oxygen flow was developed to study the effects of pulmonary to systemic flow ratios (QP/QS) on systemic oxygen availability. The model suggests that QP/QS = 1 is the safest ratio that would provide the largest safety margin in either low cardiac output or low pulmonary oxygenation conditions. The optimal value of QP/QS that will result in maximum oxygen availability is smaller than unity and depends on several circulatory parameters such as cardiac output, maximal oxygen capacity, level of pulmonary oxygenation, and oxygen consumption. The values of these parameters also dictate the permissible range of QP/QS beyond which abrupt oxygen deficiency ensues. Decreased pulmonary resistance resulting in increased pulmonary flow may eventually result in QP/QS that is beyond the vital range.

Buffering of respiratory variations in venous return by right ventricle: a theoretical analysis

The role of the right ventricle (RV) in buffering systemic venous return, thereby dampening respiratory-induced variations, left ventricular (LV) stroke volume, and systemic arterial pressure variations was examined using a computer model of the cardiovascular system. Respiration was simulated by cyclical variations in intrathoracic and abdominal pressures (cycle time 5 heartbeats), causing a 43-ml fluctuation in venous return per heartbeat (mean 71 ml) compared with fluctuations of 19 ml in RV stroke volume, 6 ml in pulmonary venous flow, and only 3 ml in LV stroke volume. On a percentage basis, the RV provided 56% of the total buffering of systemic venous return, the lungs another 30%, whereas the LV only 7%. A 10-fold increase in RV diastolic compliance increased the RV stroke volume variations from 26 to 57% of the venous return variations; a 10-fold increase in RV elastance increased them from 24 to 60%, whereas decreasing pulmonary arterial pressure from 28 to 10 mmHg increased them from 28 to 56%. The results also suggest that an underrecognized function of the RV is to buffer systemic venous return and thereby keep LV stroke volume relatively constant.

Balancing the circulation: theoretic optimization of pulmonary/systemic flow ratio in hypoplastic left heart syndrome

OBJECTIVES

This study examined the effects of the pulmonary (QP)/systemic (QS) blood flow ratio (QP/QS) on systemic oxygen availability in neonates with hypoplastic left heart syndrome.

BACKGROUND

The management of neonates with hypoplastic left heart syndrome is complex and controversial. Both before and after surgical palliation and before heart transplantation, a univentricle with parallel pulmonary and systemic circulations exists. It is generally assumed that balancing pulmonary and systemic blood flow is best to stabilize the circulation.

METHODS

We developed a mathematical model that was based on the simple flow of oxygen uptake in the lungs and whole-body oxygen consumption to study the effect of varying the QP/QS ratio. An equation was derived that related the key variables of cardiac output, pulmonary venous oxygen saturation and the QP/QS ratio to systemic oxygen availability.

RESULTS

The key findings are 1) as the QP/QS ratio increases, systemic oxygen availability increases initially, reaches a maximum and then decreases; 2) for maximal systemic oxygen availability, the optimal QP/QS ratio is < or = 1; 3) the optimal QP/QS ratio decreases as cardiac output or percent pulmonary venous oxygen saturation, or both, increase; 4) the critical range of QP/QS, where oxygen supply exceeds basal oxygen consumption, decreases as cardiac output and percent pulmonary venous oxygen saturation decrease; 5) the relation between oxygen availability and QP/QS is very steep when QP/QS approaches this critical value; and 6) the percent oxygen saturation of systemic venous blood is very low outside the critical range of QP/QS and high within the critical range.

CONCLUSIONS

This analysis provides a theoretic basis for balancing both the pulmonary and systemic circulation and suggests that evaluating both systemic arterial and venous oxygen saturation may be a useful way to determine the relative pulmonary and systemic flows. When high systemic arterial and low systemic venous oxygen saturation are present, pulmonary blood flow should be decreased; conversely, when both low systemic arterial and venous oxygen saturation are present, more flow should be directed to the pulmonary circulation.

Autoregulation in the stenosed coronary circulation

Coronary vessel stenosis increases vascular resistance and limits the dynamic range of autoregulation. In this study, the limitation imposed by stenosed vessels on oxygen delivery to the myocardium was investigated using a theoretical model. For different degrees of stenosis and for different levels of arteriovenous oxygen content difference, the model predicted the limits of the contractility range for which ventricular oxygen balance is positive. The model also predicted the existence of an optimal contractility level which minimizes the cost of arterial pressure generation and provides the largest coronary oxygen reserve. With severe stenosis, myocardial oxygen balance is extremely sensitive to changes in the level of stenosis. The range of contractility in which the coronary circulation can meet the myocardial oxygen needs is dramatically reduced by small increases in stenosis severity or small decreases in arteriovenous oxygen difference. When the optimal contractility level is maintained, the heart can tolerate these detrimental changes to a greater extent.

Venous collapse and the respiratory variability in systemic venous return

OBJECTIVE

Venous collapse limits systemic venous return, but its effects on beat to beat respiratory venous return variations are less well known. The aim of this study was to investigate the effects of venous collapse on respiratory variations in venous return.

METHODS

A model of venous collapse which included both an increase in haemodynamic resistance to flow and an increase in vessel compliance was incorporated in a previously described cardiovascular model. Respiration was simulated by 5 mm Hg swings of intrathoracic pressure (PTH) at different mean pressures such that the abdominal vena cava and jugular vein were either fully collapsed (mean PTH -11 mm Hg), in the transition zone between collapse and distension (mean PTH -6 mm Hg), or fully distended (mean PTH 9 mm Hg). The mean and standard deviations over each respiratory cycle of the venous return volume (flow integral over heart cycle) and the abdominal vena caval volume were recorded.

RESULTS

Different venous return volume variabilities in the three operating zones of the vena cava were identified: (1) reduced variability in the collapsed zone associated with the increased haemodynamic resistance [venous return 93(SD 6) ml, abdominal vena caval volume 30(3) ml. absolute right atrial pressure -6.3(1.1) mm Hg]; (2) increased variability in the transition zone [venous return 86(24) ml, abdominal vena caval volume 81(15) ml, right atrial pressure -2.2(0.8) mm Hg]; (3) low variability in the distended zone [venous return 42(11) ml, abdominal vena caval volume 120(2) ml, right atrial pressure 10.1(1.1) mm Hg]. The greater the change in compliance with collapse the greater the increase in flow variability in the transition zone; with no change in compliance there was no increased flow variability in the transition zone.

CONCLUSIONS

The results suggest that venous collapse increases the respiratory variations in venous return in the transition zone. As venous return variations contribute to arterial pressure variations, the collapsible nature of the great veins may influence respiratory variations in systemic arterial pressure.

Ventricular interaction is described by three coupling coefficients

Previous studies of ventricular interaction have quantified interaction by making small pressure or volume changes in one ventricle and measuring the resulting pressure or volume changes in the opposite ventricle. The ratios between the pressure and volume changes in opposite ventricles have been used as coupling coefficients or measures of ventricular interaction. This method of calculating coupling coefficients implicitly uses mathematical relationships that have useful features not generally appreciated. Starting from the definition of coupling coefficients we show that, without making any assumptions about ventricular interaction, all 24 possible coupling coefficients can be derived from a smaller set of four coupling coefficients. Furthermore, by making the single assumption that the ventricles behave elastically, we show that the set of four coefficients can be reduced to a set of three. Thus only three indexes are required to describe interaction, but these may vary with changes in ventricular volumes and pressures around which the indexes are measured. Furthermore, when comparisons between experimental studies are made, it is necessary to normalize the indexes with respect to ventricular volume.

Disassociation of intrinsic and haemodynamic responses in stenotic arteries

OBJECTIVE

In stenotic arteries, constriction can decrease intraluminal pressure, which in turn can further decrease vessel size. Because of these pressure changes, the hypothesis that haemodynamic responses may be significantly different from intrinsic smooth muscle responses in stenotic arteries was tested.

METHODS

In rabbits (n = 16), one iliac artery was denuded (stenotic), and the other iliac artery was untouched (hypercholesterolaemic). The rabbits were placed on a 2% cholesterol diet for three weeks. Iliac arteries from these and normal (n = 8) rabbits were removed and studied as rings or perfused segments.

RESULTS

In arterial rings, maximal isometric tension in response to noradrenaline was significantly (p < 0.05) greater in hypercholesterolaemic [0.59(SEM 0.03) x 10(6) dynes.cm-2] and normal arteries 0.63(0.04) compared with stenotic arteries [0.28(0.04)]. Normal [EC50 = 6.99(0.07), -log(M)] and hypercholesterolaemic [EC50 = 7.00(0.12)] rings were more sensitive (p < 0.05) to noradrenaline than stenotic rings [EC50 = 6.49(0.24)]. All arterial rings vasodilated in response to glyceryl trinitrate, and changes in isometric tension occurred over a 1000-fold change in noradrenaline or glyceryl trinitrate concentration. In normal and hypercholesterolaemic arteries, flow was unaltered even at the highest noradrenaline concentration. In stenotic arteries, noradrenaline decreased distal pressure from 76.9(5.4) to 24.3(7.3) mm Hg (p < 0.05) and flow from 17.9(1.6) to 6.4(1.8) ml.min-1 (p < 0.05). After noradrenaline decreased flow, glyceryl trinitrate did not always successfully vasodilate the stenotic arteries and thereby re-establish flow. Lastly, in stenotic arteries, most of the haemodynamic response occurred at one incremental dose of noradrenaline or glyceryl trinitrate.

CONCLUSION

Fundamentally different haemodynamic responses occur in stenotic v normal and hypercholesterolaemic arteries. As the intrinsic smooth muscle responses (from the stenotic rings) are weaker, the augmented responses in whole stenotic segments are probably related to the intraluminal pressure changes.

Ventricular coupling via the pericardium: normal versus tamponade

OBJECTIVE

The aim was to examine how regional variations in pericardial pressure affect the mechanical coupling between the ventricles.

METHODS

Canine hearts from 14 dogs (14.5-18 kg) were removed and placed in cold cardioplegia solution. Balloons were inserted into the left and right ventricles and the atria. Pericardial pressure over the left ventricle (Pclv) and the right ventricle (Pcrv) was measured with thin balloon catheters. Ventricular and pericardial pressures were measured, and ventricular and pericardial coupling was calculated, under control conditions and with increases in pericardial tension and fluid.

RESULTS

At baseline, regional differences in pericardial pressure occurred [Pclv > Pcrv, 4.0(SD 0.9) v 2.9(0.6) mm Hg, p < 0.05]. Ventricular coupling via the pericardium was defined as delta Pclv/delta Pcrv for right ventricular volume increases and delta Pcrv/delta Pclv for left ventricular volume increases. This ratio increased more after increasing right ventricular volume than after increasing left ventricular volume [delta Pclv/delta Pcrv > delta Pcrv/delta Pclv, 1.14(0.33) v 0.51(0.15), p < 0.05]. Increasing the pericardial tension by clamping the pericardium increased pericardial pressures, yet did not alter the regional variations in pressure [Pclv > Pcrv, 8.4(2.2) v 6.4(2.5) mm Hg, p < 0.05] or pericardial coupling [delta Pclv/delta Pcrv > delta Pclv/delta Pcrv, 1.18(0.46) v 0.54(0.16), p < 0.05]. In contrast, creating a mild tamponade increased pericardial pressures, eliminated regional differences in pressure, and altered the coupling between ventricles [delta Pclv/delta Pcrv approximately delta Pclv/delta Pcrv, 0.95(0.11) v 1.05(0.08), p = NS]. These regional differences in pericardial pressure might have a geometrical basis. In four in vivo canine experiments using cine magnetic resonance, the short axis radius of curvature for the right ventricle was greater than for the left ventricle [38.3(4.4) mm v 29.2(3.8) mm, p < 0.05].

CONCLUSIONS

The pericardium partially protects right ventricular filling: regional differences in pericardial pressure normally occurred with lower pericardial pressure over the right ventricle, and left to right ventricular coupling was less. This protection of right ventricular filling was lost with even a small pericardial effusion.

Acute alterations in systolic ventricular interdependence-mechanical dependence of right ventricle on left ventricle following acute alteration of right ventricular free wall

The purpose of the study was to examine whether systolic ventricular interdependence can be acutely altered by changes in the mechanical properties of the ventricular wall. In eight acute canine studies, we released an aortic constriction during diastole. We measured right ventricular (RV) pressure changes (dPr) caused by sudden changes in left ventricular (LV) pressure (dPl). Measurements were obtained during control, 10 min after right coronary artery occlusion, and then 15 min after injecting glutaraldehyde into the RV free wall. By superimposing the pressure tracings of the beats immediately before and after the aortic release, the instantaneous pressure difference ratio (dPr/dPl) was calculated during systole. Maximal value of the pressure difference ratio decreased from control 0.11 +/- 0.04 to ischemia 0.08 +/- 0.03; (p < 0.05) and increased with glutaraldehyde 0.15 +/- 0.06; (p < 0.05). Thus, acute ischemia in RV free wall decreased the magnitude of systolic ventricular interdependence from LV to RV, while glutaraldehyde, which stiffens the RV free wall, increased the magnitude.

The order of dilator-constrictor administration affects stenotic hemodynamic responses

This study tested the hypothesis that, due to intraluminal pressure changes, the order of constrictor-dilator administration alters stenotic hemodynamic responses. Canine carotid arteries were perfused with a physiologic salt solution under constant pressure (100 mm Hg). An intraluminal stenosis partially obstructed the arteries. Pressures proximal and distal to the artery and the flow were continually recorded as norepinephrine (10(-9)-10(-6) M) was added to the perfusate. Adding diltiazem (10(-7) M) before norepinephrine shifted the effective half maximum dose (ED50) of the norepinephrine flow curve from 7.35 +/- 0.66 X 10(-8) M to 6.39 +/- 0.72 X 10(-7) M (p < 0.05). More important, adding 10(-7) M diltiazem after norepinephrine-induced constriction did not reestablish stenotic pressure or flow: A 30-fold increase in diltiazem concentration (3.16 X 10(-6)M) was required to reestablish stenotic pressure (62.6 +/- 4.4 mm Hg) and flow (25.4 +/- 3.2 ml/min). Similarly, adding nitroglycerin (10(-7) M) before norepinephrine shifted the ED50 from 7.21 +/- 0.58 X 10(-8) to 5.94 +/- 0.78 X 10(-6) (p < 0.05). Adding 10(-7) M nitroglycerin after norepinephrine did not reestablish stenotic pressure or flow: 3.16 X 10(-6) M nitroglycerin was required to reestablish stenotic pressure (59.2 +/- 4.8 mm Hg) and flow (23.2 +/- 2.7 mL/min). This constrictor-dilation history did not occur in isolated arterial rings (norepinephrine + nitroglycerin = 38.1 +/- 13.9 g/cm2; nitroglycerin + norepinephrine = 42.2 +/- 9.4 g/cm2; p = not significant [NS]) or in normal arteries (norepinephrine + nitroglycerin = 4.89 +/- 0.14 mm [external diameter]; nitroglycerin + norepinephrine = 4.92 +/- 0.23 mm; p = NS). In stenotic arteries, intraluminal pressure influenced the order of constrictor-dilator administration on hemodynamic response, which was not observed in isolated arterial rings or in normal arteries. This pressure-dependent sensitivity affects vasomotor tone and may be important in the pathophysiology of ischemia.

Estimation of left ventricular elastance without altering preload or afterload in the conscious dog

OBJECTIVE

The aim was to determine the slope (EES) of the left ventricular end systolic pressure-volume line (ESPVL) without altering preload or afterload in conscious dogs.

METHODS

Dogs (n = 10) were instrumented to determine left ventricular volume from ultrasonic left ventricular internal dimensions, and to measure left ventricular pressure using a micromanometer. Studies were performed one to two weeks after instrumentation while the animals were conscious. ESPVL was determined from variably loaded left ventricular pressure-volume (P-V) loops generated by the vena caval occlusion. Contractile state was increased by intravenous dobutamine (8 micrograms.kg-1 x min-1) and decreased by intravenous verapamil (10 mg) given after autonomic blockade. From a single normally ejecting beat, we calculated EES-single beat (mm Hg.ml-1) as peak isovolumetric pressure (Pmax) minus end systolic pressure divided by stroke volume. Sunagawa's technique was used to estimate Pmax by fitting the pressure during the isovolumetric contraction and relaxation as: P(t) = 1/2 X Piso[1-cos(omega t+c)]+LVEDP, where Piso = peak isovolumetric developed pressure, LVEDP = left ventricular end diastolic pressure, c = constant accounting for variations in phase angle, and omega = 2 pi/T in which T is duration of contraction.

RESULTS

After dobutamine, EES increased, from 8.9(SEM 0.8) to 12.5(1.0) mm Hg.ml-1 (p < 0.05), and EES-single beat increased from 9.1(0.9) to 12.0(1.4) mm Hg.ml-1 (p < 0.05). Conversely, after verapamil, EES decreased, from 11.1(1.2) to 6.3(1.1) mm Hg.ml-1, (p < 0.05), and EES-single beat also decreased, from 9.6(1.0) to 7.3(1.2) mm Hg.ml-1, (p < 0.05).

CONCLUSIONS

EES calculated from one beat is similar to EES determined from variably loaded left ventricular loops and responds appropriately to inotropic stimulation. This technique provides a reasonable method to calculate EES from left ventricular pressure and stroke volume without altering preload or afterload.

Collateral perfusion through overlapping vessels reduces canine right ventricular ischemic injury from positive end-expiratory pressure

OBJECTIVE

To test, in a canine model of right ventricular ischemia with 15 cm H2O positive end-expiratory pressure, whether collateral perfusion through overlapping vessels from the left ventricle to the right ventricular free wall can reduce infarct size.

DESIGN

Randomized, prospective, controlled, experimental study in dogs.

SETTING

Anesthesia research laboratory of an academic medical center.

SUBJECTS

Twenty microfilaria-free mongrel dogs.

INTERVENTIONS

Anesthetized, closed-chest dogs were managed with the application of 15 cm H2O positive end-expiratory pressure. The right coronary artery was ligated (90 mins) with occlusion (n = 10) and without occlusion (n = 10) of overlapping vessels.

MEASUREMENTS AND MAIN RESULTS

Myocardial blood flow (using radioactive microspheres) was measured in the area at risk (gentian violet) and in the area of necrosis (triphenyltetrazolium chloride). With right coronary and overlapping vessel occlusion, blood flow in the area at risk decreased from 80.1 +/- 14.0 to 9.0 +/- 1.7 mL/min/100 g after 5 mins of ischemia (p = .0001) and remained depressed at 8.7 +/- 1.8 mL/min/100 g after 75 mins of ischemia. With right coronary occlusion alone, blood flow decreased after 5 mins of ischemia from 64.8 +/- 5.4 to 14.3 +/- 1.9 mL/min/100 g (p = .0001 compared with baseline), which was 60% greater than the group with occluded collateral vessels (p = .0055). Moreover, after 75 mins of ischemia, blood flow in the area at risk increased further to 28.9 +/- 5.4 mL/min/100 g with patent overlapping vessels (p = .0001 compared with 5-min value). The patency of overlapping vessels during right ventricular free wall ischemia reduced the area at risk from 68.5 +/- 2.4% to 38.6 +/- 5.1% (p = .0001) and the area of necrosis/area at risk from 58.1 +/- 8.4% to 16.9 +/- 3.6% (p = .0007).

CONCLUSIONS

Despite 15 cm H2O positive end-expiratory pressure, perfusion through overlapping vessels improved peri-ischemic blood flow in the area at risk, thereby reducing the size of the risk area and the amount of right ventricular free wall necrosis.

Contribution of each wall to biventricular function

OBJECTIVE

Common muscle fibres encircle both ventricles and the ventricles share a common septal wall. This close anatomical association suggests that regional ischaemia and structural integrity may alter systolic function in both the right and the left ventricle. To examine this possibility, we investigated the contribution of each wall to biventricular function.

METHODS

Isolated hearts, obtained from anaesthetised rabbits, were perfused with physiological salt solution under constant pressure. Balloons were placed in the right and left ventricles to measure isovolumetric pressure, and pressure-volume curves were obtained. In separate sets of experiments, the left ventricular free wall, right ventricular free wall, or septum was made ischaemic, incised, or injected with glutaraldehyde, respectively. Pressure-volume curves were obtained again.

RESULTS

After left ventricular free wall ischaemia (n = 11), right ventricular developed pressure decreased significantly from 27.9(SD 8.9) to 14.1(6.6) mm Hg (p < 0.05), and remained depressed when the left ventricular free wall was further damaged by glutaraldehyde. Cutting the left ventricular free wall (n = 6) decreased right ventricular developed pressure from 28.9(8.6) to 17.8(4.8) mm Hg (p < 0.05), while reapproximating the left ventricular free wall by suturing re-established right ventricular developed pressure. After right ventricular free wall ischaemia (n = 7), right ventricular developed pressure decreased from 26.8(6.6) to 24.1(5.7) mm Hg (NS) and left ventricular developed pressure was unaltered. Cutting the right ventricular free wall (n = 7) had no effect on left ventricular developed pressure. Cutting the septum (n = 7) had no obvious influence on right ventricular developed pressure, but dramatically decreased left ventricular developed pressure from 79.2(55.2) to 43.7(32.2) mm Hg (p < 0.05). Injecting glutaraldehyde into the septum (n = 7) decreased both right and left ventricular developed pressures from 22.1(8.5) to 14.0(8.8) and from 78.2(50.5) to 47.9(37.9), respectively.

CONCLUSIONS

The results show that the heart should be viewed as a mechanical syncytium. The left ventricular free wall plays a critical role in right ventricular systolic function and may help to explain the right ventricular response to left ventricular ischaemia. On the other hand, in the isolated heart preparation, right ventricular free wall ischaemia has only a minimal effect on left ventricular systolic developed pressure. Altering ventricular septal function affects both right and left ventricular systolic function.

Effects of cardiomyoplasty on biventricular function in canine chronic heart failure

Dynamic cardiomyoplasty, the use of skeletal muscle to assist the heart, is a new therapy for the treatment of heart failure. However, the effects of cardiomyoplasty on biventricular function and the synchrony of ventricular contraction are not fully known. We assessed the efficacy of latissimus dorsi muscle (LDM) dynamic cardiomyoplasty in a chronic model of biventricular failure. Five dogs received doxorubicin (1 mg.kg-1.wk-1) for up to 12 weeks to induce heart failure and then underwent a biventricular cardiomyoplasty. After operation, the muscle was progressively stimulated according to an established protocol. When training was complete (10 weeks), radionuclide ventriculographic and catheterization data were obtained. Peak left ventricular (LV) systolic pressure and its first derivative were unchanged, whereas LV end-diastolic pressure decreased slightly with LDM assistance (11.0 +/- 1.6 to 9.6 +/- 1.5 mm Hg; p < 0.05). Right ventricular (RV) systolic pressure increased significantly with LDM assistance from 21 +/- 2 to 26 +/- 3 mm Hg (p < 0.05), whereas its first derivative and RV end-diastolic pressure were unchanged. Dynamic cardiomyoplasty significantly improved LV ejection fraction from 0.18 +/- 0.07 without LDM assistance to 0.31 +/- 0.05 with LDM assistance (p < 0.05); similarly RV ejection fraction increased from 0.32 +/- 0.07 to 0.45 +/- 0.06 with LDM assistance (p < 0.05). The temporal sequence of LV wall motion was assessed by phase analysis of the radionuclide ventriculograms. With skeletal muscle assistance, standard deviation ("spread") decreased from 31.6 +/- 17.4 to 20.0 +/- 15.4 degrees (p < 0.06), whereas skewness ("symmetry") was unchanged. Dynamic cardiomyoplasty improved both LV and RV ejection fractions without increasing diastolic pressure.(ABSTRACT TRUNCATED AT 250 WORDS)

The left ventricle affects the duration of right ventricular ejection

OBJECTIVE

The aim was to determine if rapid changes in left ventricular pressure can acutely alter right ventricular systolic pressure and thus influence the length of right ventricular ejection.

METHODS

The experiments were performed in six open chest anaesthetised dogs, weight 18-25.5 kg. Left and right ventricular pressures and pulmonary blood flow were recorded continuously as left ventricular pressure was abruptly decreased by opening a shunt in systole. From these data, the pressure and flow changes and the duration of right ventricular ejection were determined.

RESULTS

Opening the left ventricular shunt caused left ventricular pressure to fall from 94.1(SD 10.5) to 62.6(11.3) mm Hg (p < 0.01), right ventricular pressure to fall from 30.3(4.6) to 27.0(3.6) mm Hg (p < 0.01), and pulmonary flow to fall from 69.5(14.2) to 57.5(13.9) ml.s-1. The duration of right ventricular ejection, determined from pulmonary flow, also decreased from 192.7(22.7) to 157.2(18.7) ms (p < 0.05) and was significantly related to the length of left ventricular systole. Time between end diastole and peak negative dP/dt decreased for both left and right ventricle. Left and right ventricular time intervals were related before (r = 0.99) and after (r = 0.75) opening the shunt.

CONCLUSIONS

The duration of right ventricular ejection was decreased by a sudden decrease in left ventricular afterload and was significantly related to the length of left ventricular systole. The duration of right ventricular ejection may be coupled with left ventricular contraction through ventricular interdependence.

Dynamic cardiomyoplasty acutely impairs left ventricular diastolic function

In patients with congestive heart failure, medical treatment has a high rate of mortality and morbidity, and transplantation is limited by the availability of donor hearts. Dynamic cardiomyoplasty is being investigated as surgical therapy to improve left ventricular function in these patients. To evaluate the early postoperative effects of this procedure on left ventricular diastolic function, we studied seven dogs through the use of sonomicrometry and micromanometry in a canine model of dynamic cardiomyoplasty. Left ventricular diastolic parameters were determined before wrapping the latissimus dorsi muscle (baseline), after latissimus dorsi muscle wrap but without stimulation, and with synchronous left ventricular contraction-latissimus dorsi muscle stimulation. End-diastolic pressure was increased in both conditions after latissimus dorsi muscle wrap (without stimulation, 5 +/- 1; with stimulation, 6 +/- 2 mm Hg; p < 0.05) compared with baseline (3 +/- 2 mm Hg). The peak rate of diastolic pressure decay was greater at baseline (1560 +/- 370 mm Hg/sec) than after latissimus dorsi muscle wrap, both without (1260 +/- 330 mm Hg/sec, p < 0.01) and with (1120 +/- 420 mm Hg/sec, p < 0.01) stimulation. The constant of pressure decay was prolonged both without (53 +/- 10 seconds, p < 0.05) and with (62 +/- 11 seconds, p < 0.01) latissimus dorsi muscle stimulation compared with the baseline (38 +/- 5 seconds). Compared with baseline (0.2 +/- 0.2 cm-2), the constant of passive chamber stiffness increased after the latissimus dorsi muscle was wrapped around the heart (1.6 +/- 0.7 cm-2, p < 0.05) and with stimulation (2.1 +/- 1.0 cm-2, p < 0.01). The maximal diastolic filling rate (baseline, 18.1 +/- 6.7; without stimulation, 16.6 +/- 8.9; with stimulation, 16.6 +/- 4.1 cm2/sec, not significant) and end-diastolic short-axis area (baseline, 7.3 +/- 2.3; without stimulation, 7.4 +/- 2.1; with stimulation, 7.5 +/- 2.3 cm2, not significant) were similar among the three conditions. The latissimus dorsi muscle wrap prolonged relaxation and increased left ventricular passive stiffness. Synchronous latissimus dorsi muscle stimulation with left ventricular contraction did not improve diastolic function in this model. The results suggest that in the early postoperative period, dynamic cardiomyoplasty impairs diastolic function.

Voltage-dependent performance of skeletal muscle pouches: implications for cardiomyoplasty

Cardiomyoplasty, a new therapy for heart failure, uses autologous skeletal muscle to mechanically assist the heart. The success of dynamic cardiomyoplasty is critically dependent on the contraction strength of the assisting skeletal muscle. Unlike cardiac muscle, skeletal muscle contracts in a graded response to electrical stimulation. However, in current cardiomyoplasty practice, no systematic technique exists to set the stimulating voltage effecting skeletal muscle contraction. The stimulating voltage is simply set to some multiple of the "threshold" voltage. Furthermore, researchers do not consider the role of stimulating voltage when they determine the amount of assistance afforded during cardiomyoplasty. To more accurately assess the value of this heuristic voltage-setting technique, we investigated the role of stimulating voltage on the strength of contraction of the latissimus dorsi muscle. Six New Zealand white rabbits had isovolumic hydraulic pouches constructed from the latissimus dorsi muscle. The muscles were wrapped around a compliant balloon in which isovolumic pressure development was measured during tetany-inducing burst (pulse-train) stimulation. The tetanic plateau of the pouch pressure record was used to measure the effects of stimulating voltage on skeletal muscle contraction. Results indicated that (1) increasing stimulating voltage from two to four times the "threshold" voltage increased normalized pouch pressure from 0.38 +/- 0.21 to 0.78 +/- 0.12 (mean +/- SD) (p < 0.05); (2) the threshold-normalized voltage necessary to cause maximal muscle contraction varied widely (5.7 +/- 2.0, mean +/- SD; range, 3.1 to 9.3); and (3) the current achieving maximal pressure development varied from 5.6 to 31.4 mA (19.9 +/- 10.4 mA).(ABSTRACT TRUNCATED AT 250 WORDS)