The role of neutrophil gelatinase associated lipocalin (NGAL) as biological constituent linking depression and cardiovascular disease.

Depression is more common in patients with cardiovascular disease than in the general population. Conversely, depression is a risk factor for developing cardiovascular disease. Comorbidity of these two pathologies worsens prognosis. Several mechanisms have been indicated in the link between cardiovascular disease and depression, including inflammation. Systemic inflammation can have long-lasting effects on the central nervous system, which could be associated with depression. NGAL is an inflammatory marker and elevated plasma levels are associated with both cardiovascular disease and depression. While patients with depression show elevated NGAL levels, in patients with comorbid heart failure, NGAL levels are significantly higher and associated with depression scores. Systemic inflammation evokes NGAL expression in the brain. This is considered a proinflammatory effect as it is involved in microglia activation and reactive astrocytosis. Animal studies support a direct link between NGAL and depression/anxiety associated behavior. In this review we focus on the role of NGAL in linking depression and cardiovascular disease.

Electrical neuromodulation for patients with cardiac diseases.

In this review we discuss the position of electrical neuromodulation as a safe and reversible adjuvant therapy for treatment of patients with chronic cardiac diseases who have become refractory to conventional strategies. In patients with chronic refractory angina, electrical neuromodulation, independent of the applied modality, has shown to reduce complaints of angina, to enhance exercise capacity, to improve quality of life and to employ anti-ischaemic effects. To date, electrical neuromodulation seems to be one of the best adjuvant therapies for these patients. In addition, neuromodulation in the treatment of heart failure and resistant arrhythmias is the subject of several ongoing studies.

Preemptive, but not reactive, spinal cord stimulation mitigates transient ischemia-induced myocardial infarction via cardiac adrenergic neurons.

Our objective was to determine whether electrical neuromodulation using spinal cord stimulation (SCS) mitigates transient ischemia-induced ventricular infarction and, if so, whether adrenergic neurons are involved in such cardioprotection. The hearts of anesthetized rabbits, subjected to 30 min of left anterior descending coronary arterial occlusion (CAO) followed by 3 h of reperfusion (control), were compared with those with preemptive SCS (starting 15 min before and continuing throughout the 30-min CAO) or reactive SCS (started at 1 or 28 min of CAO). For SCS, the dorsal C8-T2 segments of the spinal cord were stimulated electrically (50 Hz, 0.2 ms, 90% of motor threshold). For preemptive SCS, separate groups of animals were pretreated 15 min before SCS onset with 1) vehicle, 2) prazosin (alpha(1)-adrenoceptor blockade), or 3) timolol (beta-adrenoceptor blockade). Infarct size (IS), measured with tetrazolium, was expressed as a percentage of risk zone. In controls exposed to 30 min of CAO, IS was 36.4 +/- 9.5% (SD). Preemptive SCS reduced IS to 21.8 +/- 6.8% (P < 0.001). Preemptive SCS-mediated infarct reduction was eliminated by prazosin (36.6 +/- 8.8%) and blunted by timolol (29.4 +/- 7.5%). Reactive SCS did not reduce IS. SCS increased phosphorylation of cardiac PKC. SCS did not alter blood pressure or heart rate. We conclude that preemptive SCS reduces the size of infarcts induced by transient CAO; such cardioprotection involves cardiac adrenergic neurons.

The effect of electrical neurostimulation on collateral perfusion.

BACKGROUND/OBJECTIVES: Clinical data have shown that electrical neurostimulation may improve myocardial ischaemia. Our aim was to investigate the possible effect of electrical neurostimulation on collateral perfusion. METHODS: Thirty patients with stable angina and significant single-vessel coronary artery disease scheduled for elective percutaneous coronary intervention (PCI) were randomised into three groups. In all patients two balloon inflations were performed, one for predilatation of the lesion, the second for stent delivery. Group one received active neurostimulation during the first ischaemic episode (predilatation), group two during the second ischaemic episode (stent delivery), and group three received placebo neurostimulation continuously. During both ischaemic episodes the collateral flow index was determined. RESULTS: No significant differences were found between active, inactive or placebo neurostimulation. In a post-hoc analysis the patients were stratified for presence or absence of significant collaterals. In patients with pre-existing significant collaterals, the collateral flow index was significantly higher during active neurostimulation compared with inactive neurostimulation (p=0.012) and compared with the merged inactive and placebo groups (p=0.011). CONCLUSION: The present data show no effect of electrical neurostimulation on collateral perfusion in patients with single-vessel disease. In a post-hoc analysis in patients with evidence of collaterals, defined as a collateral flow index of >0.24, an increase in collateral perfusion was found during electrical neurostimulation.

Electrical neuromodulation improves myocardial perfusion and ameliorates refractory angina pectoris in patients with syndrome X: fad or future?

At present, there is no reliable antianginal drug therapy for patients with cardiac syndrome X. Therefore, the effect of electrical neuromodulation on refractory angina pectoris and myocardial perfusion in cardiac syndrome X was assessed. Eight patients (aged 55+/-7 years) with heterogeneous myocardial perfusion and no esophageal abnormalities were included. The subjects were nonresponders to antianginal drug therapy. Angina pectoris attacks and myocardial perfusion dynamics were evaluated by positron emission tomography at baseline and following 4 weeks of (transcutaneous electrical nerve stimulation) TENS. Following TENS there was a reduction of angina pectoris episodes (baseline 20+/-3, TENS 3+/-1; p=0.012), and short acting nitroglycerin intake per week (baseline 10+/-3, TENS 2+/-1; p=0.008). The rate pressure product (mmHg min(-1)) during the cold pressor test (CPT) was reduced during TENS (baseline 12800+/-1200, TENS 11500+/-900; p=0.02). Following TENS, the perfusion reserve ratio between rest and dipyridamole flow increased (baseline 1.59+/-0.15, TENS 1.90+/-0.11 ml min(-1)x 100g; p=0.05). The coronary vascular resistance had a trend towards a reduction (baseline 0.96+/-0.04, TENS 0.85+/-0.06 mmHg min(-1)x 100 g/ml; p=0.06) during CPT. This observation may suggest that neurostimulation improves angina pectoris with a concomitant improvement of myocardial perfusion in cardiac syndrome X.

Cardiac tissue engineering: characteristics of in unison contracting two- and three-dimensional neonatal rat ventricle cell (co)-cultures.

Patients with heart failure have, in spite of improved palliative therapies, bad prognosis. Cardiac tissue engineering by use of a temporary bioscaffold and cardiomyocytes may help to find answers for future treatments in heart failure. For that purpose two neonatal rat heart ventricular cell fractions were obtained after a gradient cell separation. Time related characteristics of Fractions I and II were established in two-dimensional (2-D) and three-dimensional (3-D) cell cultures. The 3-D cardiac constructs were obtained by use of a bovine type I collagen matrix after culturing either under static conditions or in the HARV bioreactor. With the 2-D cultures contracting cells were present after 1 day, and reached confluency from day 5 on and this was maintained up to 135 days. In Fraction-I some non-contracting cells were always noticed between the (in time in unison) contracting cells. Transmission electron microscopy (TEM) revealed that these mainly concerned fibroblasts. Differences in the expression of alpha-SM-1 actin and troponin-T were observed between the two fractions. In both fractions endothelial cells and macrophages were only sporadically observed. All through the 3-D matrix pendant-like single cell and clustered cell contractions were present after 1-2 days, resulting in time in unison contracting of cells with the collagen matrices. The whole event was faster with Fraction-I and was observed up to 3 weeks. At this time point clusters of troponin-T positive cells were found scattered through the collagen matrices. Additionally, TEM revealed healthy layers of connected cardiomyocytes with intercalated discs, in this case on and in between the collagen fibres. These findings provide evidence that in unison contracting structurally organized cell-matrix cardiac constructs can be engineered by use of co-cultures (neonatal cardiomyocytes and fibroblasts) and collagen matrices, which is very promising for the repair of larger scar areas of the myocardium.

Long-term modulation of the intrinsic cardiac nervous system by spinal cord neurons in normal and ischaemic hearts.

Electrical excitation of the dorsal aspect of the rostral thoracic spinal cord imparts long-term therapeutic benefits to patients with angina pectoris. Such spinal cord stimulation also induces short-term suppressor effects on the intrinsic cardiac nervous system. The purpose of this study was to determine whether spinal cord stimulation (SCS) induces long-term effects on the intrinsic nervous system, particularly in the presence of myocardial ischaemia. The activity generated by right atrial neurons was recorded in 10 anesthetized dogs during basal states, during prolonged (15 min) occlusion of the left anterior descending coronary artery, and during the subsequent reperfusion phase. Neuronal activity and cardiovascular indices were also monitored when the dorsal T1-T4 segments of the spinal cord were stimulated electrically (50 Hz; 0.2 ms) at an intensity 90% of motor threshold (mean 0.32 mA) for 17 min. SCS was performed before, during and after 15-min periods of regional ventricular ischaemia. Occlusion of a major coronary artery, one that did not perfuse investigated neurons, resulted in their excitation. Ischaemia-induced neuronal excitatory effects were suppressed (-76% from baseline) by SCS. SCS suppression of intrinsic cardiac neuronal activity persisted during the subsequent reperfusion period; after terminating 17 min of SCS, at least 20 min elapsed before intrinsic cardiac neuronal activity returned to baseline values. It is concluded that populations of intrinsic cardiac neurons are activated by inputs arising from the ischaemic myocardium. Ischaemia-induced activation of these neurons is nullified by SCS. The neuronal suppressor effects that SCS induces persist not only during reperfusion, but also for an extended period of time thereafter. These long-term effects may account, in part, for the fact that SCS imparts clinical benefit to patients with angina of cardiac origin not only during its application, but also for a time thereafter.