| human | Q5 |
| P106 | occupation | author | Q482980 |
| Q85644710 | A combined acetylcholinesterase and immunohistochemical method for precise anatomical analysis of intrinsic cardiac neural structures |
| Q46818551 | A novel method of measuring nitric-oxide-dependent fluorescence using 4,5-diaminofluorescein (DAF-2) in the isolated Langendorff-perfused rabbit heart |
| Q57575304 | Autonomic modulation of electrical restitution, alternans and ventricular fibrillation initiation in the isolated heart |
| Q37867850 | Cardiac contractility modulation in the treatment of heart failure: initial results and unanswered questions |
| Q37690133 | Cardiac contractility modulation increases action potential duration dispersion and decreases ventricular fibrillation threshold via β1-adrenoceptor activation in the crystalloid perfused normal rabbit heart |
| Q38939301 | Characterization of the intrinsic cardiac nervous system |
| Q55177494 | Data highlighting the effects of spinal segmental stimulation of preganglionic sympathetic neurons on the electrophysiology of the rabbit heart. |
| Q42494662 | Differential cardiac responses to unilateral sympathetic nerve stimulation in the isolated innervated rabbit heart |
| Q46031589 | Direct evidence of nitric oxide release from neuronal nitric oxide synthase activation in the left ventricle as a result of cervical vagus nerve stimulation. |
| Q57575161 | Electrophysiological effects of nicotinic and electrical stimulation of intrinsic cardiac ganglia in the absence of extrinsic autonomic nerves in the rabbit heart |
| Q57575172 | Functional selectivity of cardiac preganglionic sympathetic neurones in the rabbit heart |
| Q44493535 | Innervation of sinoatrial nodal cardiomyocytes in mouse. A combined approach using immunofluorescent and electron microscopy |
| Q57575314 | Interaction between direct sympathetic and vagus nerve stimulation on heart rate in the isolated rabbit heart |
| Q38017144 | Mechanisms underlying the autonomic modulation of ventricular fibrillation initiation--tentative prophylactic properties of vagus nerve stimulation on malignant arrhythmias in heart failure |
| Q46931833 | Morphological pattern of intrinsic nerve plexus distributed on the rabbit heart and interatrial septum |
| Q57575299 | Nitric oxide mediates the vagal protective effect on ventricular fibrillation via effects on action potential duration restitution in the rabbit heart |
| Q47123968 | Study protocol for statin web-based investigation of side effects (StatinWISE): a series of randomised controlled N-of-1 trials comparing atorvastatin and placebo in UK primary care |
| Q35223644 | The acute inotropic effects of cardiac contractility modulation (CCM) are associated with action potential duration shortening and mediated by β1-adrenoceptor signalling |
| Q53638125 | The effect of direct autonomic nerve stimulation on left ventricular force in the isolated innervated Langendorff perfused rabbit heart. |
| Q28081003 | The heart's 'little brain' controlling cardiac function in the rabbit |
| Q37073023 | The mechanical uncoupler blebbistatin is associated with significant electrophysiological effects in the isolated rabbit heart |
| Q57575275 | To the Editor: Quantitative analysis of the parasympathetic innervation of the porcine heart |
| Q57575251 | To the Editor— Does the cervical vagus contain sympathetic fibers that act on the heart? |
| Q57575269 | To the Editor—Sympathetic innervation of the anterior left ventricular wall by the right and left stellate ganglia |
| Q43287621 | Vagus nerve stimulation inhibits the increase in Ca2+ transient and left ventricular force caused by sympathetic nerve stimulation but has no direct effects alone--epicardial Ca2+ fluorescence studies using fura-2 AM in the isolated innervated beati |
| Q43627201 | Vagus nerve stimulation protects against ventricular fibrillation independent of muscarinic receptor activation |
| Q35932644 | hERG potassium channel inhibition by ivabradine may contribute to QT prolongation and risk of torsades de pointes. |
| Q57575227 | hERG potassium channel inhibition by ivabradine requires channel gating |
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