Cardiac Gene Delivery Using Recirculating Devices.

Cardiac gene delivery has become an important issue following the emergence of gene therapy for the possible treatment of heart failure. Despite many advances in the management of heart failure (HF), treatment options for many patients with advanced HF remain limited. At a cellular and molecular level, many of the fundamental alterations that contribute to the pathogenesis of HF are becoming better understood and this has resulted in the discovery of new therapeutic targets in animal models of HF, in particular in the area of gene therapy.Numerous small animal and preclinical studies have examined the efficacy of delivering genes targeting various signaling pathways that are affected as the heart fails. However, the translation of this work into the clinic has been difficult due to the requirement for large scale targeted delivery of the gene. This methods chapter describes a percutaneous method of recirculation that we have employed to successfully deliver potential therapeutic agents, including genes, to the heart.

Percutaneous re-circulating isolated limb perfusion of gentamicin in a large animal model: targeted delivery of gentamicin to limb.

OBJECTIVE: We have developed a percutaneous recirculation system (V-Vascular, V-V) to enable delivery of high levels of antibiotic to the limb in an isolated and targeted manner for the treatment of limb infection. BACKGROUND: Chronic and acute limb infections are relatively commonplace in a variety of wound types. Infection can become refractory to existing treatment strategies and can cause complications associated with wound healing, lead to amputation and even death. METHODS: Gentamicin was delivered to the ovine hind limb (4 mg/kg) using the V-V system, a 'closed' recirculatory catheter system that draws blood from the venous system and returns it to the artery via an oxygenator, or via intra-venous (IV) infusion. Samples of muscle, bone and synovial fluid of the limb were collected at 30 and 60 min post administration of gentamicin. RESULTS: There was a significantly greater concentration of gentamicin observed in the bone and skeletal muscle of limbs receiving the antibiotic via V-V at 30 min post administration compared to IV delivery, (bone V-V 0.05 ± 0.04, I.V 0.004 ± 0.001 mg/L p<0.05; muscle V-V 0.005 ± 0.001, I.V 0.002 ± 0.0005 mg/L p<0.05) and bone and synovial fluid at 60 min post administration (bone V-V 0.06 ± 0.02, I.V 0.005 ± 0.001 mg/L p<0.05; synovial fluid V-V 34.58 ± 14.9, I.V 3.03 ± 0.59 mg/L p<0.05). CONCLUSIONS: These results suggest that the use of percutaneous recirculation is a safe and effective method for delivering a greater concentration of antibiotic to the limb without systemic implications.

Augmentation of left ventricular mechanics by recirculation-mediated AAV2/1-SERCA2a gene delivery in experimental heart failure.

AIMS: Down-regulation of sarcoplasmic reticulum calcium ATPase (SERCA2a) is a key molecular abnormality in heart failure (HF), which is not currently addressed by specific pharmacotherapy. We sought to evaluate, in detail, the impact of augmented SERCA2a expression on left ventricular (LV) mechanics in a large animal model of HF. METHODS AND RESULTS: Heart failure was induced in adult sheep by rapid pacing (180 b.p.m.) for 1 month, followed by delivery of adeno-associated virus (AAV) 2/1-SERCA, using a percutaneous, recirculating system for gene delivery over a 10 min period. Left ventricular mechanics was investigated by echocardiography and conductance catheter measurements in sheep receiving AAV2/1-SERCA2a after a further 4 weeks of pacing in comparison with untreated HF controls. Left ventricular function was significantly improved in the AAV2/1-SERCA2a-treated group, despite continued pacing, as measured by fractional shortening (delta absolute FS, control -4.2 ± 1.5% vs. treatment 4.4 ± 1.5%; P < 0.01) and conductance catheterization (delta Ees, control -1.22 ± 0.60 vs. treatment 0.65 ± 0.51; P < 0.05). Western blots showed an increase in SERCA protein in AAV2/1-SERCA2a-treated animals, and an analysis of gene delivery showed no evidence of regional myocardial heterogeneity in the distribution of AAV2/1-SERCA. CONCLUSION: In a large animal model, AAV2/1-mediated SERCA2a gene delivery using percutaneous, recirculating cardiac delivery leads to improved LV function.

Recirculating delivery improves myocardial cell engraftment.

INTRODUCTION: Despite pharmacological advances for heart failure, morbidity and mortality remain unacceptably high. As a result, alternative approaches such as cell therapy have been suggested to hold potential promise. However, a major obstacle is the optimization of cell delivery to the heart. Therefore, we investigated the efficacy of a percutaneous recirculation system for the delivery of cells to the heart. METHODS: Ovine fibroblasts were delivered to the ovine heart (3 x 10(7) cells) using the V-Focus system, a "closed" recirculatory system that draws blood from the coronary sinus and returns it to the coronary artery via an oxygenator, or intracoronary (IC) infusion, followed by a 2-hour recovery period. Animals were euthanized and cardiac tissue collected to determine presence of cells. RESULTS: There was a significant difference (P < 0.05) in the number of cells delivered to the heart by the V-Focus compared to direct coronary infusion for left ventricular freewall (V-Focus 1.39 +/- 0.63/mm(2), IC 0.11 +/- 0.06/mm(2)), septum (V-Focus 3.18 +/- 0.88/mm(2), IC 0.38 +/- 0.19/mm(2)), and right ventricle (V-Focus 0.46 +/- 0.23/mm(2), IC 0.05 +/- 0.04/mm(2)). CONCLUSIONS: These results suggest that potential therapeutic cells are optimally delivered to the large animal heart using the V-Focus cardiac delivery system in an ovine heart.

Reversal of global apoptosis and regional stress kinase activation by cardiac resynchronization.

BACKGROUND: Cardiac dyssynchrony in the failing heart worsens global function and efficiency and generates regional loading disparities that may exacerbate stress-response molecular signaling and worsen cell survival. We hypothesized that cardiac resynchronization (CRT) from biventricular stimulation reverses such molecular abnormalities at the regional and global levels. METHODS AND RESULTS: Adult dogs (n=27) underwent left bundle-branch radiofrequency ablation, prolonging the QRS by 100%. Dogs were first subjected to 3 weeks of atrial tachypacing (200 bpm) to induce dyssynchronous heart failure (DHF) and then randomized to either 3 weeks of additional atrial tachypacing (DHF) or biventricular tachypacing (CRT). At 6 weeks, ejection fraction improved in CRT (2.8+/-1.8%) compared with DHF (-4.4+/-2.7; P=0.02 versus CRT) dogs, although both groups remained in failure with similarly elevated diastolic pressures and reduced dP/dtmax. In DHF, mitogen-activated kinase p38 and calcium-calmodulin-dependent kinase were disproportionally expressed/activated (50% to 150%), and tumor necrosis factor-alpha increased in the late-contracting (higher-stress) lateral versus septal wall. These disparities were absent with CRT. Apoptosis assessed by terminal deoxynucleotide transferase-mediated dUTP nick-end labeling staining, caspase-3 activity, and nuclear poly ADP-ribose polymerase cleavage was less in CRT than DHF hearts and was accompanied by increased Akt phosphorylation/activity. Bcl-2 and BAD protein diminished with DHF but were restored by CRT, accompanied by marked BAD phosphorylation, enhanced BAD-14-3-3 interaction, and reduced phosphatase PP1alpha, consistent with antiapoptotic effects. Other Akt-coupled modulators of apoptosis (FOXO-3alpha and GSK3beta) were more phosphorylated in DHF than CRT and thus less involved. CONCLUSIONS: CRT reverses regional and global molecular remodeling, generating more homogeneous activation of stress kinases and reducing apoptosis. Such changes are important benefits from CRT that likely improve cardiac performance and outcome.

Diminished left ventricular dyssynchrony and impact of resynchronization in failing hearts with right versus left bundle branch block.

OBJECTIVES: We compared mechanical dyssynchrony and the impact of cardiac resynchronization therapy (CRT) in failing hearts with a pure right (RBBB) versus left bundle branch block (LBBB). BACKGROUND: Cardiac resynchronization therapy is effective for treating failing hearts with conduction delay and discoordinate contraction. Most data pertain to LBBB delays. With RBBB, the lateral wall contracts early so that biventricular (BiV) pre-excitation may not be needed. Furthermore, the magnitude of dyssynchrony and impact of CRT in pure RBBB versus LBBB remains largely unknown. METHODS: Dogs with tachypacing-induced heart failure combined with right or left bundle branch radiofrequency ablation were studied. Basal dyssynchrony and effects of single and BiV CRT on left ventricular (LV) function were assessed by pressure-volume catheter and tagged magnetic resonance imaging, respectively. RESULTS: Left bundle branch block and RBBB induced similar QRS widening, and LV function (ejection fraction, maximum time derivative of LV pressure [dP/dt(max)]) was similarly depressed in failing hearts with both conduction delays. Despite this, mechanical dyssynchrony was less in RBBB (circumferential uniformity ratio estimate [CURE] index: 0.80 +/- 0.03 vs. 0.58 +/- 0.09 for LBBB, p < 0.04; CURE 0-->1 is dyssynchronous-->synchronous). Cardiac resynchronization therapy had correspondingly less effect on hearts with RBBB than those with LBBB (i.e., 5.5 +/- 1.1% vs. 29.5 +/- 5.0% increase in dP/dt(max), p < 0.005), despite similar baselines. Furthermore, right ventricular-only pacing enhanced function and synchrony in RBBB as well or better than did BiV, whereas LV-only pacing worsened function. CONCLUSIONS: Less mechanical dyssynchrony is induced by RBBB than LBBB in failing hearts, and the corresponding impact of CRT on the former is reduced. Right ventricular-only pacing may be equally efficacious as BiV CRT in hearts with pure right bundle branch conduction delay.

Efficacy of the Acorn Cardiac Support Device in animals with heart failure secondary to high rate pacing.

AIM: To utilise an ovine model of tachycardia induced progressive dilated cardiomyopathy and heart failure to investigate the efficacy of passive ventricular constraint with the Acorn cardiac support device as a heart failure treatment. METHODS: (a) Moderate heart failure was produced in 16 sheep by pacing for 3 weeks. Half were implanted and half sham implanted with the CSD. Pacing continued at a higher rate for an additional 3 weeks. Cardiac function was assessed by echocardiography and manometry. (b) Moderate heart failure was produced (as above) in 27 sheep, 9 were implanted with CSD, pacing was restarted for 4 weeks, the initial CSD implants were terminated and another 9 animals were CSD implanted (severe heart failure), pacing was restarted in the remaining 18 animals for an additional 4 weeks (total 12 weeks) and then all animals were terminated. Cardiac function was assessed using echocardiography and treadmill exercise testing. RESULTS: (a) After 6 weeks of rapid pacing CSD implant animals had significantly better cardiac function both when compared with pre implant values and with non-implanted animals at termination. (b) CSD implantation at both moderate and severe failure resulted in significant improvements in cardiac function both when compared with pre implant values and with non-implanted animals at termination. When compared to pre implant values the improvement was greatest in severe implant animals. CONCLUSION: In this ovine model of tachycardia induced progressive heart failure, CSD implantation in either moderate or severe heart failure resulted in improved cardiac function, reduced left ventricular volume and mitral regurgitation both when compared with function at time of implant and with non implanted control animals.

Percutaneous mitral annular reduction provides continued benefit in an ovine model of dilated cardiomyopathy.

BACKGROUND: Functional mitral valve regurgitation plays a key role in the symptomatic severity and progression of heart failure. In an ovine model of dilated cardiomyopathy, we examined the chronic functional consequences of mitral regurgitation reduction using a recently developed novel percutaneous mitral annular reduction (PMAR) device. METHODS AND RESULTS: Fourteen adult sheep were paced right ventricularly at 180 to 190 bpm for 5 weeks, leading to the development of moderate mitral valve regurgitation. After echocardiographic, hemodynamic, and neurohormonal analysis, 9 animals underwent PMAR. All animals were subsequently paced for another 28 days, and a final echocardiographic and hemodynamic study was conducted. Animals that had undergone PMAR showed significantly increased negative and positive dP/dt, whereas pulmonary capillary wedge pressure and mitral valve regurgitation were significantly reduced compared with those at device implant despite continued pacing. In conjunction, significant improvements in plasma norepinephrine and brain natriuretic peptide were apparent. CONCLUSIONS: The application of PMAR in animals with pacing-induced dilated cardiomyopathy and functional mitral valve regurgitation resulted in continued improvements in hemodynamic and neurohormonal parameters.

Ventricular constraint in severe heart failure halts decline in cardiovascular function associated with experimental dilated cardiomyopathy.

BACKGROUND: We have shown that passive ventricular constraint during moderate heart failure can halt progressive deterioration in cardiac function in an experimental model of ovine pacing induced heart failure (HF). We report on ventricular constraint in severe heart failure. METHODS: Eighteen adult merino sheep were used. Severe heart failure was induced in two stages, ie, high rate ventricular pacing for 21 days to produce moderate HF and then for 42 days to induce severe HF. A custom-made polyester mesh cardiac support device ([CSD] Acorn Cardiovascular, St Paul, MN) was implanted snugly around both ventricles through a lower partial sternotomy in 9 sheep (group 1). Rapid ventricular pacing was continued for a further 28 days in all animals to induce advanced HF. Cardiovascular functional indicators were determined using echocardiography and a submaximal treadmill exercise protocol at base line, moderate, severe, and advanced stages. The 9 sheep in group 2 were used as controls. RESULTS: Cardiovascular function was significantly depressed in all animals in advanced heart failure compared with base line, with left ventricular ejection fraction (LVEF) falling from 50% to 25% (p < 0.05) and LV +dp/dt((max)) declining from 1,777 to 1,243 (p < 0.05). However after CSD implantation cardiovascular function during exercise improved significantly despite ongoing rapid pacing, with LVEF increasing to 30% and LV +dp/dt to 1,499 (p < 0.05) in group 1. There were no significant changes in left ventricular long axis area (157 to 151 cm(2)) and short axis (6.8 to 6.1 cm) dimensions at the termination of pacing compared with those at time of CSD implant. Mitral regurgitation improved slightly from 2.5 to 2.19 after containment (p < 0.05) in group 1 but increased to 2.83 in group 2. CONCLUSIONS: Ventricular constraint in advanced heart failure with a custom-made polyester mesh device halted the decline in cardiac function seen in untreated animals with this pacing-induced animal model of heart failure. These results indicate potential clinical implications for ventricular containment in the treatment of end-stage heart failure.

An ovine model of tachycardia-induced degenerative dilated cardiomyopathy and heart failure with prolonged onset.

BACKGROUND: The aim of this study was to develop a model of long-term progressive heart failure (HF). METHODS AND RESULTS: A cardiac output flowprobe was implanted on the pulmonary artery of 9 adult sheep weighing 40 to 50 kg. Rapid ventricular pacing for 21 days at 160 to 190 bpm (rate A) resulted in moderate HF. Animals were then paced at 205 to 215 bpm (rate B) for 42 days (severe HF) and for 28 days at rate B (advanced HF). Data were collected at baseline and moderate, severe, and advanced HF during submaximal exercise testing and by transthoracic echocardiography in sinus rhythm. There were marked increases in left ventricular (LV) area, mitral valve regurgitation, and LV end-diastolic pressure and decreases in LV wall thickness, LV ejection fraction, positive and negative dP/dt(max), and positive (dP/dt(max))/P throughout the pacing protocol. CONCLUSIONS: This ovine HF model incorporates the progressive nature of human HF and allows examination of both structural changes and hemodynamic parameters of HF during and after exercise challenge.

Electrical remodeling of the atrium in an anatomic model of atrial flutter: relationship between substrate and triggers for conversion to atrial fibrillation.

BACKGROUND: Atrial flutter (AFL) and atrial fibrillation (AF) frequently coexist, yet the specific relationship between these arrhythmias, and particularly whether sustained AFL leads to AF, is unknown. METHODS AND RESULTS: We investigated the electrophysiological consequences of chronic AFL using an ovine anatomic right atrial Y-lesion model. AFL was induced in 7 animals, and 4 remained in sinus rhythm (controls). Sheep were monitored for spontaneous conversion of AFL to AF. Six of 7 sheep sustained AFL for 28 days. In 1 of 7 sheep, spontaneous conversion of AFL to AF occurred on day 5. AFL produced a highly significant fall in right and left atrial refractoriness (AERP, P<0.001), with 74+/-10% of the reduction occurring by day 3. Right atrial conduction velocity also fell significantly (baseline 89+/-9 cm/s versus day 28 64+/-14 cm/s, P<0.001) but over a slower time course. AERP and conduction velocity changes coincided with a characteristic biphasic decrease and increase in the AFL cycle length. The excitable gap (percent of AFL cycle length) increased from 13+/-3% at baseline to 46+/-8% by day 28 (P<0.001). Sustained AF (>30 seconds) was not inducible at baseline but after 28 days of AFL could be induced in 6 of 6 sheep by critically timed single or multiple extrastimuli delivered either in sinus rhythm or AFL. There was no significant change in any parameter in control sheep. CONCLUSIONS: In this model, AFL produced electrical remodeling and the substrate for sustained AF. However, spontaneous conversion to AF was uncommon, and the development of AF was dependent on specific triggers.