Erol Saygili

Augmentation of Left Ventricular Contractility by Cardiac Sympathetic Neural Stimulation

Background— Electric stimulation of mediastinal sympathetic cardiac nerves increases cardiac contractility but is not selective for the left ventricle because it elicits sinus tachycardia and enhanced atrioventricular conduction. The aim of this study was to identify sympathetic neural structures inside the heart that selectively control left ventricular inotropy and can be accessed by transvenous catheter stimulation. Methods and Results— In 20 sheep, high-frequency stimulation (200 Hz) during the myocardial refractory period with electrode catheters inside the coronary sinus evoked a systolic left ventricular pressure increase from 97±20 to 138±32 mm Hg (P<0.001) without changes in sinus rate or PR time. Likewise, the rate of systolic pressure development (1143±334 versus 1725±632 mm Hg/s; P=0.004) and rate of diastolic relaxation (531±128 versus 888±331 mm Hg/s; P=0.001) increased. The slope of the end-systolic pressure-volume relationship increased (2.3±0.8 versus 3.1±0.6 mm Hg/mL; P=0.04), as did cardiac output (3.5±0.8 versus 4.4±0.8 L/min; P<0.001). Systemic vascular resistance and right ventricular pressure remained unchanged. There was a sigmoid dose-response curve. Ultrasound analysis revealed an increase in circumferential and radial strain in all left ventricular segments that was significant for the posterior, lateral, and anterior segments. Pressure effects were maintained for at least 4 hours of continued high-frequency stimulation and abolished by &bgr;1-receptor blockade. Histology showed distinct adrenergic nerve bundles at the high-frequency stimulation site. Conclusions— Cardiac nerve fibers that innervate the left ventricle are amenable to transvenous electric catheter stimulation. This may permit direct interference with and modulation of the sympathetic tone of the left ventricle.

Acetylcholine as an age-dependent non-neuronal source in the heart

In the heart, acetylcholine (ACh) slows pacemaker activity, depresses contractility and slows conduction in the atrioventricular node. Beside these cardiovascular effects, ACh has also been associated with an anti-inflammatory and anti-apoptotic pathway. There is no evidence for ACh synthesis and excretion in other cell types than neuronal cells in the heart. Therefore, this study investigates whether cardiomyocytes are able to synthesize, transport and excrete ACh in the heart. We chose a rat model of different aged rats (neonatal, 6-8 week = young, 20-24 month = old). By real-time PCR, Western blot and immunofluorescence experiments we could demonstrate that adult, but not neonatal cardiomyocytes, express the choline acetyltransferase (ChAT). The expression level of ChAT is down-regulated in old cardiomyocytes. Furthermore, we found that young and old cardiomyocytes express the ACh transport proteins choline transporter-1 (CHT-1) and the vesicular acetylcholine transporter (VAChT). The amount of ACh excretion detected by high performance liquid chromatography (HPLC) is significantly down-regulated in old cardiomyocytes. Bromo-acetylcholine (BrACh), a specific ChAT inhibitor, significantly decreased ACh concentrations in cardiomyocyte supernatants demonstrating that ChAT is the main ACh synthesizing enzyme in cardiomyocytes. In conclusion, we could demonstrate that adult, but not neonatal, cardiomyocytes are able to synthesize, transport and excrete ACh in the rat heart. The expression level of ChAT and the ACh excretion amount are significantly down-regulated in old cardiomyocytes. This finding may provide new physiological/pathological aspects in the communication between cardiomyocytes and other cell types in the myocardium, e.g. fibrocytes, neurocytes or endothelial cells.

Regulation of nerve growth factor in the heart: the role of the calcineurin-NFAT pathway.

A heightened sympathetic tone accelerates the development of lethal arrhythmias after myocardial infarction (MI) and the progression of heart failure (HF). Cardiomyocytes control their local neural milieu by expression of nerve growth factor (NGF), which triggers sympathetic neural growth (sympathetic nerve sprouting: SNS). The molecular mechanisms that regulate NGF expression are largely unknown. During HF or MI the myocytes are exposed to increased mechanical load and adrenergic stimulation. Both stimuli induce myocyte hypertrophy. The angiotensin-II-calcineurin-NFAT (nuclear factor of activated t-cells) pathway is a well characterized signaling cascade in the pathogenesis of myocyte hypertrophy. The present study aims to investigate the molecular mechanisms by which mechanical stretch and/or alpha-1-adrenergic stimulation affect NGF expression in neonatal rat ventricular myocytes. Both stimuli resulted in a down-regulation of NGF gene and protein expression. Angiotensin-II type 1 receptor blockade with losartan blunted the stretch-induced NGF down-regulation. Specific calcineurin inhibition with cyclosporine A and FK506 or NFAT inhibition with 11R-VIVIT reversed the stretch or alpha-1-adrenergic induced decrease of NGF. Calcineurin over-expression increased NFAT-DNA binding activity and decreased NGF expression. The magnitude of NGF decrease was sufficient to reduce neurite outgrowth of cultured sympathetic neurons. In conclusion, mechanical stretch and alpha-1-adrenergic stimulation contribute to a decrease of cardiomyocyte NGF expression via the calcineurin-NFAT pathway. To evaluate if the calcineurin-NFAT is critically involved in the pathogenesis of SNS further in-vivo studies in models of HF and MI are required. Nevertheless, the calcineurin-NFAT pathway may provide promising starting points for new pharmacological strategies to prevent SNS in the heart.

Mechanisms of Ca2+-Dependent Calcineurin Activation in Mechanical Stretch-Induced Hypertrophy

Pressure overload is the major stimulus for cardiac hypertrophy. Accumulating evidence suggests an important role for calcium-induced activation of calcineurin in mediating hypertrophic signaling. Hypertrophy is an important risk factor for cardiovascular morbidity and mortality. We therefore employed an in vitro mechanical stretch model of cultured neonatal cardiomyocytes to evaluate proposed mechanisms of calcium-induced calcineurin activation in terms of inhibition of calcineurin activity and hypertrophy. The protein/DNA ratio and ANP gene expression were used as markers for stretch-induced hypertrophy. Stretch increased the calcineurin activity, MCIP1 gene expression and DNA binding of NFATc as well as the protein/DNA ratio and ANP mRNA in a significant manner. The specific inhibitor of calcineurin, cyclosporin A, inhibited the stretch-induced increase in calcineurin activity, MCIP1 gene expression and hypertrophy. The L-type Ca2+ channel blocker nifedipine and a blocker of the Na+/H+ exchanger (cariporide) both suppressed stretch-dependent enhanced calcineurin activity and hypertrophy. Also application of a blocker of the Na+/Ca2+ exchanger (KB-R7943) was effective in preventing calcineurin activation and increases in the protein/DNA ratio. Inhibition of capacitative Ca2+ entry with SKF 96365 was also sufficient to abrogate calcineurin activation and hypertrophy. The blocker of stretch-activated ion channels, streptomycin, was without effect on stretch-induced hypertrophy and calcineurin activity. The present work suggests that of the proposed mechanisms for the calcium-induced activation of calcineurin (L-type Ca2+ channels, capacitative Ca2+ entry, Na+/H+ exchanger, Na+/Ca2+ exchanger and stretch-activated channels) all but stretch-activated channels are possible targets for the inhibition of hypertrophy.

Electrical stimulation of sympathetic neurons induces autocrine/paracrine effects of NGF mediated by TrkA

Neuronal remodeling with increased sympathetic innervation density has been implicated in the pathogenesis of atrial fibrillation (AF). Recently, increased transcardiac nerve growth factor (NGF) levels were observed in a canine model of AF. Whether atrial myocytes or cardiac sympathetic neurons are the source of neurotrophins, and whether NGF is the main neurotrophic factor contributing to sympathetic nerve sprouting (SNS) in AF still remains unclear. Therefore, neonatal rat atrial myocytes were cultured under conditions of high frequency electrical field stimulation (HFES) to mimic rapid atrial depolarization. Likewise, sympathetic neurons from the superior cervical ganglia of neonatal rats were exposed to HFES to simulate the physiological effect of sympathetic stimulation. Real-time PCR, ELISA and Western blots were performed to analyze the expression pattern of NGF and neurotrophin-3 (NT-3). Baseline NGF and NT-3 content was 3-fold higher in sympathetic neurons than in atrial myocytes (relative NGF protein expression: 1+/-0.0 vs. 0.37+/-0.11, all n=5, p<0.05). HFES of sympathetic neurons induced a frequency dependent NGF and NT-3 gene and protein up-regulation (relative NGF protein expression: 0Hz=1+/-0.0 vs. 5Hz=1.13+/-0.19 vs. 50Hz=1.77+/-0.08, all n=5, 0Hz/5Hz vs. 50Hz p<0.05), with a subsequent increase of growth associated protein 43 (GAP-43) expression and morphological SNS. Moreover, HFES of sympathetic neurons increased the tyrosine kinase A (TrkA) receptor expression. HFES induced neurotrophic effects could be abolished by lidocaine, TrkA blockade or NGF neutralizing antibodies, while NT-3 neutralizing antibodies had no significant effect on SNS. In neonatal rat atrial myocytes, HFES resulted in myocyte hypertrophy accompanied by an increase in NT-3 and a decrease in NGF expression. In summary, this study provides evidence that high-rate electrical stimulation of sympathetic neurons mediates nerve sprouting by an increase in NGF expression that targets the TrkA receptor in an autocrine/paracrine manner.

Comparative evaluation of the usability of 2 different methods to perform mild hypothermia in patients with out-of-hospital cardiac arrest.

BACKGROUND Several studies have shown that mild hypothermia (32-34°C) markedly mitigates brain damage after cardiac arrest (CA). This study aimed to compare the efficacy of the non-invasive cooling device Hilotherm Clinic (Hilotherm GmbH, Germany) with conventional cooling to induce and maintain mild hypothermia in patients after out-of-hospital CA. METHODS 50 adult patients with an indication for controlled mild hypothermia were prospectively assigned to conventional cooling (n=20) or cooling with the Hilotherm system (n=30). Patients receiving a cooling therapy by Hilotherm were treated either with 0.35 m(2) (n=20) or with 0.7 m(2) (n=10) surface area of cooling sleeves. RESULTS The speed of cooling was significantly higher in both Hilotherm groups compared to conventional cooling (Hilotherm 0.7 m(2): 0.91 ± 0.08°C/h, Hilotherm 0.35 m(2): 0.47 ± 0.04°C/h, and conventional: 0.3 ± 0.04°C/h, p ≤ 0.003). Temperature deviation from the target temperature of 33°C was significantly higher in the conventional group compared to both Hilotherm groups. During induction of mild hypothermia a significant reduction of the mean arterial blood pressure and the heart rate was observed without significant differences between the groups. However, the speed of cooling (range 0.3-0.91°C/h) did not correlate to the decrease of blood pressure and heart rate. Norepinephrine dosing during induction of mild hypothermia and re-warming (1st-2nd day) was significantly increased compared to the 3rd day after admission in all groups. Dobutamine dosing and 30 days in-hospital mortality did not differ significantly between the groups. CONCLUSIONS Rapid and reliable mild hypothermia can be better achieved by the non-invasive cooling system Hilotherm compared to conventional cooling with ice packs and cold infusion.

Mechanical stretch induces nerve sprouting in rat sympathetic neurocytes

Sympathetic nerve sprouting (SNS) has been shown to occur after myocardial infarction (MI) and heart failure (HF) and is known to be responsible for the development of lethal arrhythmias. During MI or HF intracardiac cells are exposed to increased mechanical stretch. Molecular mechanisms which trigger sympathetic neural growth are largely unknown. Therefore, this study aimed to investigate the impact of mechanical stretch on rat neonatal sympathetic neurocytes of the superior cervical ganglion (SCG). Mechanical stretch resulted in an increased growth of sympathetic neurocytes. Furthermore, we could demonstrate that SCG neurocytes express nerve growth factor (NGF), ciliary neurotrophic factor (CNTF), neurotrophin-3 (NT-3) and glial derived neurotrophic factor (GDNF) on mRNA and protein level. An increased NGF and CNTF expression, a down-regulated GDNF expression and an unchanged NT-3 expression were identified in the neurocyte cell culture supernatant of neurocytes exposed to mechanical stretch. However, neither brain derived neurotrophic factor (BDNF) mRNA and protein was expressed in SCG neurocytes, nor BDNF could be detected in the cell culture supernatant of SCG neurons. By anti-neurotrophin neutralizing experiments NGF and CNTF were identified as important stretch-induced growth-inducing factors. Losartan, an angiotensin-II type 1 receptor inhibitor, abolished the stretch-induced increase of NGF and CNTF expression and thereby prevented the stretch-induced neural growth. This study provides new molecular mechanisms by which the inhibitory effect of angiotensin-II type 1 receptor blockers on the neural/arrhythmogenic remodeling can be explained. However, further in-vivo studies are required to address this important issue.

Neurofilament light chain as an early and sensitive predictor of long-term neurological outcome in patients after cardiac arrest

BACKGROUND Neurofilament light chain (NF-L) is the major intermediate filament specifically expressed in neurons and their axons. No data are available concerning serum levels of NF-L after global cerebral ischemia due to cardiac arrest. To find a specific neuronal marker of long-term neurological outcome, we examined serum levels of NF-L in patients after cardiac arrest. METHODS A prospective observational cohort study was conducted. Blood samples for the measurement of NF-L were analyzed from 85 patients within 2h after admission, as well as on 2nd, 3rd, 5th, and 7th day. Neurological outcome was assessed 6 months after cardiac arrest by employing the Modified Glasgow Outcome Score (MGOS). RESULTS The serum course of NF-L in patients with poor neurological outcome (MGOS 1+2) was significantly augmented compared to patients with good neurological outcome (MGOS 3+4+5) (on admission (pg/ml): good: 125 ± 11.7 vs. poor: 884.4 ± 86.2 pg/ml; 3rd day: good: 153.1 ± 13.2 vs. poor: 854.4 ± 119.1; 7th day: good: 112.5 ± 10.4 vs. poor: 1011.8 ± 100.8; P<0.001). Intermediate NF-L serum values were found in patients with MGOS 0, which represents a mixture of patients who died with and without certified brain damage (on admission (pg/dl): 433.7 ± 49.8; 3rd day: 598.3 ± 86.6; 7th day: 474 ± 77.4). A prediction power of 0.93 (c-statistic, 95%-CI 0.87-0.99) on 1st, 0.85 (0.81-0.95) on 2nd, 0.92 (0.85-0.99) on 3rd, 0.97 (0.92-1) on 5th and 0.99 (0.98-1) on 7th day was achieved for NF-L predicting poor neurological outcome. CONCLUSIONS The present data suggest that within 7 days after cardiac arrest serum NF-L is a valuable marker of long-term neurological outcome.

Chronic Electrical Neuronal Stimulation Increases Cardiac Parasympathetic Tone by Eliciting Neurotrophic Effects

Rationale: Recently, we provided a technique of chronic high-frequency electric stimulation (HFES) of the right inferior ganglionated plexus for ventricular rate control during atrial fibrillation in dogs and humans. In these experiments, we observed a decrease of the intrinsic ventricular rate during the first 4 to 5 months when HFES was intermittently shut off. Objective: We thus hypothesized that HFES might elicit trophic effects on cardiac neurons, which in turn increase baseline parasympathetic tone of the atrioventricular node. Methods and Results: In mongrel dogs atrial fibrillation was induced by rapid atrial pacing. Endocardial HFES of the right inferior ganglionated plexus, which contains abundant fibers to the atrioventricular node, was performed for 2 years. Sham-operated nonstimulated dogs served as control. In chronic neurostimulated dogs, we found an increased neuronal cell size accompanied by an increase of choline acetyltransferase and unchanged tyrosine hydroxylase protein expression as compared with unstimulated dogs. Moreover, &bgr;-nerve growth factor (NGF) and neurotrophin (NT)-3 were upregulated in chronically neurostimulated dogs. In vitro, HFES of cultured neurons of interatrial ganglionated plexus from adult rats increased neuronal growth accompanied by upregulation of NGF, NT-3, glial-derived neurotrophic factor (GDNF), ciliary neurotrophic factor (CNTF) and brain-derived neurotrophic factor (BDNF) expression. NGF was identified as the main growth-inducing factor, whereas NT-3 did not affect HFES-induced growth. However, NT-3 could be identified as an important acetylcholine-upregulating factor. Conclusions: HFES of cardiac neurons in vivo and in vitro causes neuronal cellular hypertrophy, which is mediated by NGF and boosters cellular function by NT-3–mediated acetylcholine upregulation. This knowledge may contribute to develop HFES techniques to augment cardiac parasympathetic tone.

Mechanical stretch of sympathetic neurons induces VEGF expression via a NGF and CNTF signaling pathway.

Mechanical stretch has been shown to increase vascular endothelial growth factor (VEGF) expression in cultured myocytes. Sympathetic neurons (SN) also possess the ability to express and secrete VEGF, which is mediated by the NGF/TrkA signaling pathway. Recently, we demonstrated that SN respond to stretch with an upregulation of nerve growth factor (NGF) and ciliary neurotrophic factor (CNTF). Whether stretch increases neuronal VEGF expression still remains to be clarified. Therefore, SN from the superior cervical ganglia of neonatal Sprangue Dawley rats were exposed to a gradual increase of stretch from 3% up to 13% within 3days (3%, 7% and 13%). Under these conditions, the expression and secretion of VEGF was analyzed. Mechanical stretch significantly increased VEGF mRNA and protein expression (mRNA: control=1 vs. stretch=3.1; n=3/protein: control=1 vs. stretch=2.7; n=3). ELISA experiments to asses VEGF content in the cell culture supernatant showed a time and dose dependency in VEGF increment due to stretch. NGF and CNTF neutralization decreased stretch-induced VEGF augmentation in a significant manner. This response was mediated in part by TrkA receptor activation. The stretch-induced VEGF upregulation was accompanied by an increase in HIF-1α expression. KDR levels remained unchanged under conditions of stretch, but showed a significant increase due to NGF neutralization. In summary, SN respond to stretch with an upregulation of VEGF, which is mediated by the NGF/CNTF and TrkA signaling pathway paralleled by HIF-1α expression. NGF signaling seems to play an important role in regulating neuronal KDR expression.