Myosplint implant and shape-change procedure: intra- and peri-operative safety and feasibility

Mechanical Cardiac Support with an Implantable Direct Cardiac Compression Device: Proof of Concept

Purpose

We examined the hemodynamic effects of a new, implantable, direct cardiac assist device in an ovine heart failure model.

Description

The device, which encompasses both left and right ventricles, is inserted through the pericardial apex and self-expands to encompass the heart without suturing. The intact pericardium anchors the device in place. The device has 2 concentric chamber layers: an internal chamber layer filled with fluid to conform to the heart and an external chamber layer filled with air that provides external compression and negative pressure to aid relaxation.

Evaluation

The device was implanted in 7 sheep with heart failure induced by microsphere embolization. Cardiac performance was assessed for 6 to 8 hours. The cardiac assist device provided cardiac systolic and diastolic assistance, as shown by pressure tracings of the left ventricle and aorta, pulmonary artery flow, and +dP/dt. Central venous pressure decreased during cardiac assistance. No anatomic damage was noted postmortem.

Conclusions

Systolic and diastolic cardiac assistance can be achieved with this device that compresses and relaxes in synchrony with the native cardiac cycle.

Reversing Left Ventricular Remodeling in Chronic Heart Failure

Chronic heart failure (CHF) has become an epidemic in the United States, with approximately 550,000 new cases annually. With the evolution of pharmacotherapy targeting neurohormonal pathways, the annual mortality in subjects with New York Heart Association (NYHA) class IV CHF has dramatically improved from 52% in the seminal CONSENSUS trial to less than 20% in more recent trials. Suppression of the renin-angiotensin-aldosterone system remains the first line of neurohormonal blockade followed by the addition of selective beta-adrenoreceptor blockers. For patients with NYHA class I and II symptoms, mortality rates have decreased to approximately 5% or less per year with the use of angiotensin-converting enzyme inhibitors, beta-blockers and aldosterone receptor blockers. However, after achieving optimal doses of the indicated pharmacotherapy, and despite the additional benefits obtained with biventricular pacemakers, there are still many patients who continue to experience signs and symptoms of CHF. Recognizing the beneficial effects of the above treatments on left ventricular (LV) remodeling, strategies have been developed to surgically reshape the left ventricle in patients with LV dilation who have associated poor LV function. This review will discuss the techniques and recent developments regarding surgical reshaping of the dilated, dysfunctional, and remodeled left ventricle.

Effect of a Flexible Ventricular Restraint Device on Cardiac Remodeling after Acute Myocardial Infarction

The effects of a flexible ventricular restraint device on left ventricular (LV) dilatation and hypertrophy after transmural infarction are examined in an ovine model. Left ventricular remodeling and dilatation occurs after extensive myocardial infarction. A flexible ventricular restraint made from a nitinol mesh was evaluated in adult female sheep (n=14). Cardiac magnetic resonance imaging scans and hemodynamic measurements were completed before and 6 weeks after anterior myocardial infarction. Treatment animals (n=7) received passive ventricular restraint concurrently with LV infarction; the others (n=7) served as controls. Increases in LV end-diastolic volume index were significantly less in the restraint group than in controls (0.20+/-0.41 vs 0.83+/-0.50 ml/kg, p<0.03). End-systolic volumes increased less in treatment animals (0.43+/-0.28 vs 0.90+/-0.38 ml/kg, p<0.03). Control hearts showed an increase in LV mass after infraction, whereas LV mass decreased in restrained hearts (0.14+/-0.19 vs -0.25+/-0.36 g/kg, p<0.03). Hemodynamic studies showed similar changes after infarction for the control and the device group. Gross and microscopic examination showed no device-induced epicardial injury. A flexible ventricular restraint device attenuated remodeling after acute myocardial infarction in sheep.

Drugs for left ventricular remodeling in heart failure

Left ventricular (LV) remodeling (ie, enlargement and functional deterioration occurring over time) is among the main mechanisms of progression in heart failure (HF). LV dilatation and dysfunction are major negative prognostic markers in patients with HF. Treatments that are effective in limiting or even reversing this process can be expected to provide clinical benefit. Changes in LV dimensions rather than in ejection fraction should be used to monitor remodeling. Ejection fraction can be influenced by transient loading conditions and by agents that stimulate contractility at the expense of increased oxygen demand, whereas dimensional changes probably reflect structural modifications occurring in the myocardium. The neurohormonal antagonists that have been demonstrated to reduce mortality and morbidity in HF (angiotensin-converting enzyme inhibitors [ACE], beta-blockers, angiotensin receptor blockers, and aldosterone antagonists) are also able to inhibit or reverse remodeling. In reverse remodeling, beta-blockers appear to be superior to the other classes of drugs, with a stronger correlation between dose and effect, but it must be remembered that they have been tested as an addition to background therapy that may include ACE inhibitors. With regard to nonpharmacologic strategies, biventricular pacing is associated with functional improvement and reverse remodeling in patients with advanced HF and electromechanical dyssynchrony, and it recently has been demonstrated to improve survival in a randomized clinical trial.

Surgical left ventricular remodeling in heart failure

The high mortality and morbidity of patients in terminal heart failure are a therapeutic challenge to modern medicine. Surgically, cardiac transplantation is an excellent treatment for many patients. However, lack of donors combined with an increasing number of patients has led to the search for other surgical strategies. Patients with symptomatic large left ventricular aneurysms have been treated with resection of the aneurysm and closure of the left ventricle either directly (linear closure, first reported by Cooley) or by implantation of a patch (endoventricular patch plasty or Dor procedure). Akinetic areas of the left ventricle have also been successfully treated by the latter method. According to the law of Laplace, large dilated ventricles have increased wall tension and thus increased oxygen consumption. Based on this fact, Batista and coworkers have reduced the volume of enlarged left ventricles in patients in terminal heart failure by removing a wedge of myocardium from the apex of the heart towards the base of the left ventricular free wall. Although a favorable outcome has been reported in selected patients, this method is currently not recommended for treatment of heart failure because of high surgical failure rates. The present paper reviews some of the relevant literature regarding surgical left ventricular remodeling in heart failure. Two new techniques (Myosplint and CorCap cardiac support device) are also briefly described.

Partial left ventriculectomy and mitral valve repair: favorable short-term results in carefully selected patients with advanced heart failure due to dilated cardiomyopathy

BACKGROUND

Because of the scarcity of donor hearts, surgical alternatives to heart transplantation, such as partial left ventriculectomy (PLV), were introduced for treatment of advanced heart failure. Here, we report our experience with this procedure performed in combination with mitral valve repair.

METHODS

Twelve patients with dilated cardiomyopathy (DCM), New York Heart Association (NYHA) class exceeding III on maximal medical therapy, cardiac index of 2.5 liter/min/m2 or less, VO2max of 14 ml/kg/min or less, left ventricular end-diastolic diameter (LVEDD) of 7.0 cm or more, and grade II or greater mitral incompetence, were selected for PLV and mitral valve reconstruction (MVR). Echocardiography, hemodynamics, spiroergometry, and clinical assessment were performed before and 1 year after the operation.

RESULTS

One-year survival was 83.3%. All 10 surviving patients were free from failure of the procedure 1 year post-operatively. From pre-operatively to 1 year post-operatively, NYHA functional class improved from 3.3 +/- 0.3 to 1.9 +/- 0.2 (p < 0.001), cardiac index increased from 2.0 +/- 0.2 liter/min/m2 to 2.9 +/- 0.2 liter/min/m2 (p < 0.001), stroke volume index from 25.9 +/- 4.8 ml/m2 to 40.3 +/- 7.3 ml/m2 (p = 0.008), and VO2max from 10.9 +/- 2.4 ml/kg/min to 16.0 +/- 3.6 ml/kg/min (p = 0.016), whereas LVEDD decreased from 8.4 +/- 0.6 cm to 6.6 +/- 0.3 cm (p < 0.001), left ventricular end-systolic diameter from 6.8 +/- 0.8 cm to 5.3 +/- 0.5 cm (p < 0.001), and mitral incompetence from 2.4 +/- 0.6 to 0.9 +/- 0.6 (p < 0.001). Pulmonary pressures and fractional shortening did not change significantly (p > 0.05). Four patients received an implantable cardioverter/defibrillator as a result of their pathologic electrophysiologic examination.

CONCLUSIONS

In carefully selected patients, PLV combined with MVR achieves short-term results comparable to that after heart transplantation. However, long-term results and multicenter evaluation will be needed to define its place in the treatment of advanced heart failure.

Surgical ventricular restoration and other surgical approaches to heart failure

Historically, few patients with ischemic congestive heart failure (CHF) have been considered for cardiac surgical intervention unless there was an obvious need for coronary revascularization or valve repair. New surgical procedures and non-mechanical assist devices are being used and tested in patients with end-stage CHF. We report on The Ohio State University Medical Center's early involvement in the international and multi-institutional Surgical Treatment for Ischemic Heart Failure (STICH) trial, which is evaluating the value of coronary artery bypass in patients with ischemic CHF as compared to medical therapies alone, and whether surgical ventricular restoration (SVR) offers additional benefit to patients with dilated hearts undergoing revascularization. Beyond standard coronary revascularization and SVR, new surgically deployed devices that attempt to augment ventricular performance by direct restraint of left ventricular dilatation or by reducing ventricular wall stress through altering ventricular shape are reviewed. The growing clinical and experimental experience with cellular cardiomyoplasty (in particular, autologous skeletal myoblast and adult-derived stem transplantation) also is reviewed. This review is intended to express the institutional insights of the authors, who have been involved in clinical trials and basic science research in each of these areas.

Mitral Valve Repair without Cardiopulmonary Bypass or Atriotomy Using the Coapsys Device: Device Design and Implantation Procedure in Canine Functional Mitral Regurgitation Model

BACKGROUND

Myocor developed a unique system, the Coapsys annuloplasty system, to treat functional mitral regurgitation (MR) without cardiopulmonary bypass (CPB). This study was conducted to test the feasibility of the Coapsys implantation procedure in a canine functional MR model.

METHODS

Functional MR with heart failure was induced in 9 dogs by rapid ventricular pacing (230 beats/min for 30 +/- 4 days). The Coapsys device, which consists of anterior and posterior epicardial pads connected by a subvalvular chord, was then surgically implanted. Under epicardial echocardiographic guidance, we placed the Coapsys device across the left ventricular chamber using the delivery instrument and needle assembly. We sized the Coapsys device by drawing the posterior leaflet and annulus toward the anterior leaflet with the sizing instrument. Final device size was selected when MR was minimized or eliminated as assessed by 2-dimensional color Doppler echocardiography.

RESULTS

In all cases, we successfully implanted the Coapsys device without CPB or atriotomy. MR was reduced an average of 2 grades. No adverse events, such as hemodynamic compromise or structural valve damage, were noted.

CONCLUSION

Coapsys device implantation was feasible and safe on a beating canine heart. All accessory tools used for device implantation were found useful.

Ventricular reconstruction surgery for congestive heart failure

The significant increase in the prevalence of heart failure in the United States has made this disease a major health problem. The continued shortage of donor organs has prevented heart transplantation from becoming an effective solution for the treatment of end-stage heart failure, and as a result, surgical treatments for heart failure have been reexamined. Surgical therapies represent the evolution of conventional operations, such as coronary artery bypass surgery, and the application of the more novel left ventricular (LV) reconstruction operations which address the geometry of the LV, the important component in the failing heart.

Echocardiographic assessment of regional ventricular function after device-based change of left ventricular shape

We assessed the effects of implantation of Myosplint (Myocor, Maple Grove, Minn), a device that changes left ventricular (LV) cross-sectional shape from circular to bilobar, on regional LV function. A total of 10 open-chest dogs with tachycardia-induced cardiomyopathy were studied before and after Myosplint implantation. LV cross-sectional epicardial echocardiography at the papillary muscle level was performed along with acquisition of hemodynamic data. LV normalized thickening, fractional thickening, end-diastolic thickness, and end-diastolic curvatures were calculated for 10 LV segments. Myosplint implantation did not affect LV hemodynamics, but decreased average end-diastolic curvature (P <.0001) and increased its segmental heterogeneity (P <.0001). There was no change in average fractional thickening, whereas normalized thickening increased (P =.05). In contrast, segmental heterogeneity of both normalized and fractional thickening increased (P =.02 and P =.01, respectively). Structural modeling confirmed that Myosplint implantation increases regional stress heterogeneity and curvature heterogeneity. LV cross-sectional shape markedly affects regional LV performance.

Reading tarot cards

In some patients acute myocardial infarction and/or infarct expansion induces progressive left ventricular dilatation that eventually leads to heart failure and death. The five year mortality after onset of heart failure is 50%. Chronically stretched viable myocardium adjacent to or remote from an expanding infarction initiates a myopathic process that leads to progressive myocyte apoptosis and adverse postinfarction remodeling. Revascularization of stunned or hibernating myocardium restores contractility and benefits patients in heart failure; however, revascularization does not restore contractility to myopathic, remodeling myocardium. Contemporary operations for heart failure temporarily reduce ventricular wall stress, but fail to reverse stretch induced myocyte apoptosis, which may not be reversible. Logically, prevention of this myopathic process after acute infarction seems required to extend survival. It follows that surgeons should operate before adverse postinfarction left ventricular remodeling occurs, using new operations, rather than afterwards.

Surgical management of heart failure

This article introduces the mechanisms and theories behind the surgical treatments for heart failure; however, heart failure is a complex problem and requires multiple solutions. Surgery offers treatment strategies that target underlying physiologic changes and may provide both quality of life and survival benefit to patients who have specific clinical characteristics consistent with the aims of the procedure. Nurses must include surgical treatment early in their hierarchy of treatment plans, especially when coronary artery occlusion, hibernating myocardium, or mitral valve regurgitation is the cause of heart failure. In addition, newer investigational surgical therapies must also be considered for patients with advanced heart failure who have already been optimized on medical and cardiac resynchronization therapies and who require a novel approach to potentially improve individual outcomes.

Left ventricular systolic performance in failing heart improved acutely by left ventricular reshaping

OBJECTIVE

If the geometric distortion during dilated heart failure could be corrected, the tension on the myocytes would be decreased, thereby leading to an improvement in left ventricular systolic function. We tested the effects of the CardioClasp (CardioClasp Inc, Pine Brook, NJ), a left ventricular reshaping device, on the failing heart, and our empirical data were compared with computationally derived data.

METHODS

Heart failure was induced by 4-week rapid cardiac pacing. At the terminal experiment, an isolated failing heart preparation (isovolumic contraction, n = 5) or an intact failing heart in vivo (n = 7) was used. The effects of the reshaping device on left ventricular performance were assessed by the slopes (Ees) of the left ventricular end-systolic pressure-volume relations, hemodynamics, and echocardiograph before and after placing the CardioClasp on the heart. The change in Ees as the result of left ventricular reshaping was also estimated from computed theoretical analysis and compared with empirical data.

RESULTS

There was a significant change in left ventricular dimension after placing the CardioClasp on the heart. In isolated heart preparation, Ees significantly increased from 1.40 +/- 0.44 mm Hg/mL to 2.42 +/- 0.63 mm Hg/mL after placing the device on the heart but returned to the baseline level (1.46 +/- 0.27 mm Hg) after removing it. Left ventricular developed pressure and left ventricular fractional area shortening were significantly increased as the result of left ventricular reshaping. Ees derived from computed theoretical analysis was highly correlated with confirming empirical data.

CONCLUSIONS

The CardioClasp can reshape the left ventricle and improve left ventricular systolic performance in failing hearts.

Device-based left ventricular geometry change for heart failure treatment: developmental work and current status

BACKGROUND

Device-based left ventricular (LV) geometry change is a new concept in the treatment of heart failure that reduces LV wall stress and improves cardiac function by reducing effective LV radius. Ventricular geometry change is achieved by placement of three Myosplint devices to bisect the LV and to create two smaller LV chambers.

METHODS AND RESULTS

Since the first animal experiment in June 1997, the Myosplint has been tested extensively in a series of animal studies using a pacing-induced, canine dilated cardiomyopathy model. Device-based LV geometry change decreased LV wall stress, improved systolic function, and maintained diastolic function, resulting in an improvement in myocardial energetics. An acute human feasibility study during heart transplant surgery was started in July 1999. While awaiting the arrival of the donor heart, the Myosplint was implanted in the recipient LV in 5 patients. The device was easily applied on a beating heart without complications related to the device or the procedure in any of the patients. LV wall stress was significantly decreased after tightening of the device. Clinical safety studies with chronic Myosplint implantation were begun in Germany in June 2000 and in the United States in February 2001. There have been a total of 21 patients receiving the implant without evidence of bleeding, muscle tearing, severe arrhythmia, or thrombus formation associated with the implant.

CONCLUSIONS

Device-based geometry change has been demonstrated to be practical, effective, and safe.

CardioClasp changes left ventricular shape acutely in enlarged canine heart

BACKGROUND

In dilated cardiomyopathy (DCM), eliminating or reducing extra-geometric burden to the myocardial cells would directly reduce myocardial wall stress leading to improved LV systolic performance. In acute experiments, we tested whether a passive non-blood contacting CardioClasp device, which employs two indenting bars to reshape the left ventricle (LV), could reduce extra-geometric burden, LV wall stress (LVWS) and improve LV systolic function and contractility without decreasing arterial blood pressure.

METHODS

In mongrel dogs (n = 5), 4 weeks of right ventricular pacing (210-220-230-240 ppm) induced DCM with severe heart failure. After placing the CardioClasp device, LV performance was evaluated immediately by measuring hemodynamics, echocardiography, and Sonometrics crystal data. Eleven sonometric crystals were placed into endocardial positions (8 in anterior, posterior, mid-anterior, mid-posterior, apex, base, free and septal wall) and in myocardial (2 as regional) and epicardial (1) positions to assess the LV end-systolic pressure-segment length relationships (ESPSR) and cross-sectional area (ESPAR) relationship.

RESULTS

CardioClasp decreased the LV end-diastolic anterior-posterior (A-P) dimensions at two levels (15% and 25%). With CardioClasp, LVWS decreased from 93.1 +/- 7.2 to 59.1 +/- 3.2 g/cm2 (P < 0.05) and fractional area of contraction (FAC) increased from 27.6 +/- 3.8 to 33.1 +/- 3.7% (P < 0.01). Peak LV and arterial pressures, LV +dP/dt, LV -dP/dt, and cardiac output were unaltered with CardioClasp. CardioClasp placement significantly increased the slopes of LV pressure versus anterior-posterior segment relationship from 7.3 +/- 0.6 to 15.8 +/- 1.8 mmHg/mm and septal-free wall segment relationship from 6.3 +/- 0.9 to 9.8 +/- 0.5 mmHg/mm. At both 15% and 25% LV A-P dimension reductions, the slopes of ESPAR showed significant steepening and increased from 10.1 +/- 0.7 (baseline) to 15.5 +/- 1.7 (15% reduction) and 19.0 +/- 1.4 mmHg/cm2 (25% reduction). The larger the reduction, the greater was the steepening of the slopes of ESPSR and ESPAR.

CONCLUSIONS

CardioClasp reduced LV diameter and thereby decreased LVWS and increased FAC. CardioClasp was able to reshape the left ventricle, while preserving the contractile mass, which increased the slopes of ESPSR and ESPAR. This reshaping was associated with maintained systolic pressures, cardiac output, and increased contractility.

The cardiac support device and the myosplint: treating heart failure by targeting left ventricular size and shape

Left ventricular (LV) remodeling occurs in patients with heart failure and is associated with poor long-term outcome. Two important components of this remodeling process are progressive LV dilation and LV shape changes, the latter manifested by increased LV chamber sphericity. This brief review describes two passive mechanical devices that were developed to prevent the progressive LV dilation and shape changes that occur during the evolution of heart failure. One such device is the Cardiac Support Device ([CSD] CorCap; Acorn Cardiovascular, St Paul, MN) and the other is the Myosplint (Myocor, Maple Grove, MN). Studies in dogs with coronary microembolization-induced heart failure have shown that the CSD prevents progressive LV dilation, increases LV ejection fraction, lowers LV wall stress, and attenuates LV chamber sphericity. Safety and feasibility studies in patients with heart failure have shown that the CSD is safe. The same studies have provided strong efficacy trends that are consistent with those seen in experimental animals. Studies in dogs with rapid pacing induced heart failure showed that the Myosplint device can reshape the LV leading to reduced LV volumes, increased ejection fraction, and reduced wall stress. Safety and feasibility studies of the Myosplint device in humans are limited and trends are not as yet easily discerned. Final conclusions on the clinical effectiveness of these devices must await completion of randomized clinical trials. These trials should provide the first tests in humans of the hypothesis that limiting LV remodeling alone can improve long-term outcome and quality of life in patients with heart failure.

Passive ventricular constraint

Heart failure (HF) is a progressive degenerative and malignant syndrome with a large number of aetiologies including coronary artery disease, chronic hypertension, exposure to toxins, bacteria and viruses and in a significant percentage of HF patients, the causal mechanism is unclear. The HF trail of morbidity and mortality is well documented and is characterised by step-like periods of relative symptomatic stability, compensation, separated by decompensatory episodes. The homeostatic response to the decline in cardiac function is diverse and involves most organs. There is an increase in resting rate, intra-cardiac hormone production (catecholamines, aldosterone, etc.) and in particular structural changes occur with increased mass and dilatation (dilated cardiomyopathy, DCM). DCM is associated with decreased cardiac output, contractility and energy efficiency and an increase in pro-arrhythmia and conduction defects. Kass et al. (Circulation 91(9) (1995) 2314) first demonstrated in patients who had undergone a dynamic cardio-myoplasty procedure, that, preventing further dilatation in DCM was beneficial and that the improved cardiovascular status was largely independent of muscle stimulation. We hypothesised that this outcome could be achieved by implanting a fabric cardiac support device around both ventricles to the AV junction. Subsequently, it was shown by us and others (Kass et al., 1995) (Cardiovasc. Res. 44(3) (1999) 549); (Ann. Thorac. Surg. 70(4) (2000) 1275) (in different animal models of DCM) that passive ventricular constraint prevented further dilatation, initiated left ventricular volume reduction and reversed the decline in ejection fraction, mitral valve integrity and left ventricular contractility, when compared with untreated controls. Subsequent European and North American clinical trials in patients with DCM of varying aetiologies have shown equal promise and an absence of device related complications (Circulation 104(12 Suppl. 1) (2001) I270); (Ann. Thorac. Cardiovasc. Surg. 7(5) (2001) 278). The mechanisms behind this improvement have yet to be fully clarified however the support generated by the device upon the right and ventricular freewall would lower wall tension. Not only is passive ventricular constraint a very promising treatment modality for heart failure and DCM it should provide a useful research tool for the study of the role of ventricular dilatation in the progression of heart failure.

New surgical therapies for heart failure

A growing number of patients present with heart failure. Some of them may qualify for surgical correction of their cardiac condition. Since heart transplantation will always be available to only a small number of patients, several new surgical techniques have been developed for approval in heart failure patients. Classic interventions such as revascularization, valve repair, or valve replacement have been improved and modified to meet the need of heart failure patients. Several of these techniques are currently under investigation in large clinical trials. These trials will definitely have an impact on the development of surgical treatment of patients with heart failure.