Recombinant human collagen-based microspheres mitigate cardiac conduction slowing induced by adipose tissue-derived stromal cells

Background Stem cell therapy to improve cardiac function after myocardial infarction is hampered by poor cell retention, while it may also increase the risk of arrhythmias by providing an arrhythmogenic substrate. We previously showed that porcine adipose tissue-derived-stromal cells (pASC) induce conduction slowing through paracrine actions, whereas rat ASC (rASC) and human ASC (hASC) induce conduction slowing by direct coupling. We postulate that biomaterial microspheres mitigate the conduction slowing influence of pASC by interacting with paracrine signaling. Aim To investigate the modulation of ASC-loaded recombinant human collagen-based microspheres, on the electrophysiological behavior of neonatal rat ventricular myocytes (NRVM). Method Unipolar extracellular electrograms, derived from microelectrode arrays (8x8 electrodes) containing NRVM, co-cultured with ASC or ASC loaded microspheres, were used to determine conduction velocity (CV) and conduction heterogeneity. Conditioned medium (Cme) of (co)cultures was used to assess paracrine mechanisms. Results Microspheres did not affect CV in control (NRVM) monolayers. In co-cultures of NRVM and rASC, hASC or pASC, CV was lower than in controls (14.4+/-1.0, 13.0+/-0.6 and 9.0+/-1.0 vs. 19.5+/-0.5 cm/s respectively, p Conclusion The application of recombinant human collagen-based microspheres mitigates indirect paracrine conduction slowing through interference with a secondary autocrine myocardial factor

Value of Serial Heart Rate Variability Measurement for Prediction of Appropriate ICD Discharge in Patients with Heart Failure

HRV and Appropriate ICD Shock in Heart Failure Introduction Decreased heart rate variability (HRV) is associated with adverse outcomes in patients with heart failure. Our objective was to examine whether decreased HRV predicts appropriate implantable cardioverter defibrillator (ICD) shocks. Methods and Results In 105 patients with a Boston Scientific Contak Renewal, Cognis or Energen device implanted for either primary (73.3%) or secondary prevention (26.7%), time domain HRV variables standard deviation of averages of normal beat-to-beat interval (SDANN) and footprint percentage (FPP) were collected at baseline and during follow-up. In case of appropriate shock, HRV before shock was assessed. Using time-dependent Cox regression models, the relation between median-based dichotomized SDANN or FFP and appropriate shock was investigated. Baseline characteristics between patients with or without shocks were similar, with exception of secondary prevention patients using more often antiarrhythmic drugs. During follow-up (median 451, IQR 202-1,460 days), appropriate shocks occurred in 20 (19%) patients. SDANN and FPP did not differ significantly at baseline between patients with or without shocks (respectively, P = 0.18 and P = 0.78). However, time-dependent Cox regression analysis showed a trend that patients were at lower risk for appropriate shock (SDANN: HR 0.43, 95% CI [0.18-1.05], P = 0.06 and FPP: HR 0.49, 95% CI [0.20-1.20], P = 0.12) when HRV values were above median baseline value during follow-up. Conclusions These results imply that HRV could be an independent predictor for appropriate shocks. Therefore, low HRV could be of additional use in predicting imminent appropriate shocks and could possibly guide concomitant medical therap

Differential Mechanisms of Myocardial Conduction Slowing by Adipose Tissue-Derived Stromal Cells Derived From Different Species

: Stem cell therapy is a promising therapeutic option to treat patients after myocardial infarction. However, the intramyocardial administration of large amounts of stem cells might generate a proarrhythmic substrate. Proarrhythmic effects can be explained by electrotonic and/or paracrine mechanisms. The narrow therapeutic time window for cell therapy and the presence of comorbidities limit the application of autologous cell therapy. The use of allogeneic or xenogeneic stem cells is a potential alternative to autologous cells, but differences in the proarrhythmic effects of adipose-derived stromal cells (ADSCs) across species are unknown. Using microelectrode arrays and microelectrode recordings, we obtained local unipolar electrograms and action potentials from monolayers of neonatal rat ventricular myocytes (NRVMs) that were cocultured with rat, human, or pig ADSCs (rADSCs, hADSCs, pADSCs, respectively). Monolayers of NRVMs were cultured in the respective conditioned medium to investigate paracrine effects. We observed significant conduction slowing in all cardiomyocyte cultures containing ADSCs, independent of species used (p < .01). All cocultures were depolarized compared with controls (p < .01). Only conditioned medium taken from cocultures with pADSCs and applied to NRVM monolayers demonstrated similar electrophysiological changes as the corresponding cocultures. We have shown that independent of species used, ADSCs cause conduction slowing in monolayers of NRVMs. In addition, pADSCs exert conduction slowing mainly by a paracrine effect, whereas the influence on conduction by hADSCs and rADSCs is preferentially by electrotonic interaction. Cell-based therapy is a promising option to treat patients after myocardial infarction. Although cell-based therapy may help replace infarcted heart tissue by functional tissue, it has some limitations. First, it may cause life-threatening arrhythmias. Slow conduction facilitates arrhythmias induction. Second, cells derived from and administered to the same patients may be affected by age and disease. Therefore, cells from other patients or other species may be used. This study shows that application of stromal cells caused conduction slowing in cardiomyocyte monolayers, irrespective of the specific origin of the cells, but that the conduction slowing is conferred through soluble factors or through coupling between fat-derived cells and cardiac myocytes in a species-dependent manne

Differential Mechanisms of Myocardial Conduction Slowing by Adipose Tissue-Derived Stromal Cells Derived From Different Species

Stem cell therapy is a promising therapeutic option to treat patients after myocardial infarction. However, the intramyocardial administration of large amounts of stem cells might generate a proarrhythmic substrate. Proarrhythmic effects can be explained by electrotonic and/or paracrine mechanisms. The narrow therapeutic time window for cell therapy and the presence of comorbidities limit the application of autologous cell therapy. The use of allogeneic or xenogeneic stem cells is a potential alternative to autologous cells, but differences in the proarrhythmic effects of adipose-derived stromal cells (ADSCs) across species are unknown. Using microelectrode arrays and microelectrode recordings, we obtained local unipolar electrograms and action potentials from monolayers of neonatal rat ventricular myocytes (NRVMs) that were cocultured with rat, human, or pig ADSCs (rADSCs, hADSCs, pADSCs, respectively). Monolayers of NRVMs were cultured in the respective conditioned medium to investigate paracrine effects. We observed significant conduction slowing in all cardiomyocyte cultures containing ADSCs, independent of species used (p < .01). All cocultures were depolarized compared with controls (p < .01). Only conditioned medium taken from cocultures with pADSCs and applied to NRVM monolayers demonstrated similar electrophysiological changes as the corresponding cocultures. We have shown that independent of species used, ADSCs cause conduction slowing in monolayers of NRVMs. In addition, pADSCs exert conduction slowing mainly by a paracrine effect, whereas the influence on conduction by hADSCs and rADSCs is preferentially by electrotonic interaction. SIGNIFICANCE: Cell-based therapy is a promising option to treat patients after myocardial infarction. Although cell-based therapy may help replace infarcted heart tissue by functional tissue, it has some limitations. First, it may cause life-threatening arrhythmias. Slow conduction facilitates arrhythmias induction. Second, cells derived from and administered to the same patients may be affected by age and disease. Therefore, cells from other patients or other species may be used. This study shows that application of stromal cells caused conduction slowing in cardiomyocyte monolayers, irrespective of the specific origin of the cells, but that the conduction slowing is conferred through soluble factors or through coupling between fat-derived cells and cardiac myocytes in a species-dependent manner

ST-Segment Elevation and Fractionated Electrograms in Brugada Syndrome Patients Arise From the Same Structurally Abnormal Subepicardial RVOT Area but Have a Different Mechanism

Brugada syndrome (BrS) is characterized by a typical ECG pattern. We aimed to determine the pathophysiologic basis of the ST-segment in the BrS-ECG with data from various epicardial and endocardial right ventricular activation mapping procedures in 6 BrS patients and in 5 non-BrS controls. In 7 patients (2 BrS and 5 controls) with atrial fibrillation, an epicardial 8×6 electrode grid (interelectrode distance 1 mm) was placed epicardially on the right ventricular outflow tract (RVOT) before video-assisted thoracoscopic surgical pulmonary vein isolation. In 2 other BrS patients, endocardial, epicardial RV (CARTO), and body surface mapping was performed. In 2 additional BrS patients, we performed decremental preexcitation of the RVOT before endocardial RV mapping. During video-assisted thoracoscopic surgical pulmonary vein isolation and CARTO mapping, BrS patients (n=4) showed greater activation delay and more fractionated electrograms in the RVOT region than controls. Ajmaline administration increased the region with fractionated electrograms, as well as ST-segment elevation. Preexcitation of the RVOT (n=2) resulted in ECGs that supported the current-to-load mismatch hypothesis for ST-segment elevation. Body surface mapping showed that the area with ST-segment elevation anatomically correlated with the area of fractionated electrograms and activation delay at the RVOT epicardium. ST-segment elevation and epicardial fractionation/conduction delay in BrS patients are most likely related to the same structural subepicardial abnormalities, but the mechanism is different. ST-segment elevation may be caused by current-to-load mismatch, whereas fractionated electrograms and conduction delay are expected to be caused by discontinuous conduction in the same area with abnormal myocardiu

Detailed characterization of familial idiopathic ventricular fibrillation linked to the DPP6 locus

Familial idiopathic ventricular fibrillation (IVF) is a severe disease entity and is notoriously difficult to manage because there are no clinical risk indicators for premature cardiac arrest. Previously, we identified a link between familial IVF and a risk haplotype on chromosome 7q36 (involving the arrhythmia gene DPP6). The purpose of this study was to expand our knowledge of familial IVF and to discuss its (extended) clinical characteristics. We studied 601 family members and probands: 286 DPP6 risk-haplotype positive (haplotype-positive) and 315 DPP6 risk-haplotype negative (haplotype-negative) individuals. Clinical parameters, a combination of all-cause mortality and (aborted) cardiac arrest and differences between haplotype-positives and haplotype-negatives, were evaluated. There were no differences in electrocardiographic indices between haplotype-positives and haplotype-negatives, or between haplotype-positives with or without events. Cardiac magnetic resonance documented slightly larger ventricular volumes in haplotype-positives compared to controls (P <.05), but these were not clinically useful. Mortality and/or cardiac arrest occurred in 85 haplotype-positives (30%) and 18 haplotype-negatives (6%). Twenty-four haplotype-positives (8% male) were resuscitated from ventricular fibrillation (VF). Documented VF was always elicited by monomorphic short-coupled extrasystoles from the right ventricular apex/lower free wall. Median survival in risk-haplotype haplotype-positives was 70 vs. 93 years for haplotype-negatives (P < .01), with a worse phenotype in males (median survival 63 vs. 83 years in females, P < .01). Implantable cardioverter-defibrillators were implanted in 99 patients (76 [77%] for primary prevention). Two arrhythmic events occurred in the primary prevention group during follow-up (5 ± 3 years). Despite our extensive analysis, the complexity in identifying asymptomatic IVF family members at risk for future arrhythmias based on clinical parameters is once more demonstrate

Myocardial fibrosis as an early feature in phospholamban p.Arg14del mutation carriers:phenotypic insights from cardiovascular magnetic resonance imaging

Aims: The p.Arg14del founder mutation in the gene encoding phospholamban (PLN) is associated with an increased risk of malignant ventricular arrhythmia (VA) and heart failure. It has been shown to lead to calcium overload, cardiomyocyte damage, and eventually to myocardial fibrosis. This study sought to investigate ventricular function, the extent and localization of myocardial fibrosis and the associations with ECG features and VA in PLN p.Arg14del mutation carriers. Methods and results: Cardiovascular magnetic resonance (CMR) data of 150 mutation carriers were analysed retrospectively. Left ventricular (LV) and right ventricular (RV) volumes, mass, and ejection fraction were measured. The extent of late gadolinium enhancement (LGE) was expressed as a percentage of myocardial mass. All standard ECG parameters were measured. Occurrence of VA was analysed on ambulatory 24-h and/or exercise electrocardiography, if available. Mean age was 40 ± 15 years, 42% males, and 7% were index patients while 93% were pre-symptomatic carriers identified after family cascade screening. Mean LV ejection fraction (LVEF) and RV ejection fraction were 58 ± 9% and 55 ± 9%, respectively. LV-LGE was present in 91% of mutation carriers with reduced LVEF (<45%) and in 30% of carriers with preserved LVEF. In carriers with positive LV-LGE, its median extent was 5.9% (interquartile range 3.2-12.7). LGE was mainly observed in the inferolateral wall. Carriers with inverted T-waves in the lateral ECG leads more often had LV-LGE (P < 0.01) than carriers without. Finally, the presence of LV-LGE, but not attenuated R-waves and inverted lateral T-waves, was independently associated with VA. Conclusion: LV myocardial fibrosis is present in many PLN p.Arg14del mutation carriers, and who still have a preserved LVEF. It is seen predominantly in the LV inferolateral wall and corresponds with electrocardiographic repolarization abnormalities. Although preliminary, myocardial fibrosis was found to be independently associated with VA. Our findings support the use of CMR with LGE early in the diagnostic work-up

Light microscope image of the two main cell types used and the different cultures.

<p><b>A:</b> Monolayers of NRVM cultured on multi-electrode arrays, <b>B:</b> Porcine ASC in culture, <b>C:</b> Monolayers of NRVM cultured together with microspheres, <b>D:</b> Co-cultures of NRVM and porcine ASC on a multi-electrode array and <b>E:</b> Co-cultures of NRVM and porcine ASC loaded on microspheres. Original magnification 10x. Black dots represent electrode terminals in the multi-electrode arrays. Abbreviations; ASC: adipose tissue-derived stromal cells, MS: microspheres and NRVM: neonatal rat ventricular myocytes.</p

Influence of recombinant human collagen-based microspheres on conduction slowing mediated by a paracrine mechanism.

<p><b>A:</b> Activation map of a monolayer of NRVM co-cultured with pASC (left), and an activation map of a monolayer of NRVM cultured with pASC loaded microspheres (right). Conduction velocity is determined along the white arrows perpendicular to isochronal (black) lines. Lower panels: the effects on <b>B:</b> conduction velocity and <b>C:</b> conduction heterogeneity. * indicates p< 0.001 compared to the NRVM + pASC. Number of replicates per experimental condition is indicated in the bar-graphs. Abbreviations; MS: microspheres, NRVM: neonatal rat ventricular myocytes, and pASC: porcine adipose tissue-derived stromal cells.</p

Scanning electron microscope micrographs of the recombinant human collagen-based microspheres loaded with porcine ASC.

<p>Original magnification is indicated underneath the image. Abbreviation: ASC: adipose tissue-derived stromal cells.</p