J Wink1, R van Delft2, R G E Notenboom3, P F Wouters4, M C DeRuiter3, J W M Plevier5, M R M Jongbloed6. 1. Department of Anesthesiology, Leiden University Medical Center, Leiden, the Netherlands. Electronic address: j.wink@lumc.nl. 2. Department of Anesthesiology, Leiden University Medical Center, Leiden, the Netherlands. 3. Department of Anatomy & Embryology, Leiden University Medical Center, Leiden, the Netherlands. 4. Department of Anesthesia, University Hospitals Ghent, Belgium. 5. Walaeus Library, Leiden University Medical Center, Leiden, the Netherlands. 6. Department of Anatomy & Embryology, Leiden University Medical Center, Leiden, the Netherlands; Department of Cardiology, Leiden University Medical Center, Leiden, the Netherlands.
Abstract
BACKGROUND: Cardiac sympathetic blockade is a therapeutic approach for arrhythmias and heart failure and may be a beneficial effect of high thoracic epidural anesthesia. These treatments require detailed knowledge of the spatial location and distribution of cardiac autonomic nerves, however, there are controversies on this subject in humans. OBJECTIVE: To provide a systematic overview of current knowledge on human anatomy of the cardiac autonomic nervous system. RESULTS: In contrast to the often claimed assumption that human preganglionic sympathetic cardiac neurons originate mainly from thoracic spinal segments T1-T4 or T5, there is ample evidence indicating involvement of cervical spinal segment C8 and thoracic spinal segments below T5. Whether cervical ganglia besides the stellate ganglion play a role in transmission of cardiac sympathetic signals is unclear. Similarly, there is debate on the origin of cardiac nerves from different thoracic ganglia. Most human studies report thoracic cardiac nerves emerging from the first to fourth thoracic paravertebral ganglia; others report contributions from the fifth, sixth and even the seventh thoracic ganglia. There is no agreement on the precise composition of nerve plexuses at the cardiac level. After years of debate, it is generally accepted that the vagal nerve contributes to ventricular innervation. Vagal distribution appears higher in atria, whereas adrenergic fibers exceed the number of vagal fibers in the ventricles. CONCLUSION: Anatomy of the human cardiac autonomic nervous system is highly variable and likely extends beyond generally assumed boundaries. This information is relevant for thoracic epidural anesthesia and procedures targeting neuronal modulation of cardiac sympathetic innervation.
BACKGROUND: Cardiac sympathetic blockade is a therapeutic approach for arrhythmias and heart failure and may be a beneficial effect of high thoracic epidural anesthesia. These treatments require detailed knowledge of the spatial location and distribution of cardiac autonomic nerves, however, there are controversies on this subject in humans. OBJECTIVE: To provide a systematic overview of current knowledge on human anatomy of the cardiac autonomic nervous system. RESULTS: In contrast to the often claimed assumption that human preganglionic sympathetic cardiac neurons originate mainly from thoracic spinal segments T1-T4 or T5, there is ample evidence indicating involvement of cervical spinal segment C8 and thoracic spinal segments below T5. Whether cervical ganglia besides the stellate ganglion play a role in transmission of cardiac sympathetic signals is unclear. Similarly, there is debate on the origin of cardiac nerves from different thoracic ganglia. Most human studies report thoracic cardiac nerves emerging from the first to fourth thoracic paravertebral ganglia; others report contributions from the fifth, sixth and even the seventh thoracic ganglia. There is no agreement on the precise composition of nerve plexuses at the cardiac level. After years of debate, it is generally accepted that the vagal nerve contributes to ventricular innervation. Vagal distribution appears higher in atria, whereas adrenergic fibers exceed the number of vagal fibers in the ventricles. CONCLUSION: Anatomy of the human cardiac autonomic nervous system is highly variable and likely extends beyond generally assumed boundaries. This information is relevant for thoracic epidural anesthesia and procedures targeting neuronal modulation of cardiac sympathetic innervation.
Authors: Bettina Kronsteiner; Lydia M Zopf; Patrick Heimel; Gunpreet Oberoi; Anne M Kramer; Paul Slezak; Wolfgang J Weninger; Bruno K Podesser; Attila Kiss; Francesco Moscato Journal: Front Cell Dev Biol Date: 2022-09-12