Remodelling of the intracardiac ganglia in diabetic Goto-Kakizaki rats: an anatomical study.

BACKGROUND: Although cardiac autonomic neuropathy is one of major complications of diabetes mellitus (DM), anatomical data on cardiac innervation of diabetic animal models is scant and controversial. We performed this study to check whether long-term diabetic state impacts the anatomy of intracardiac ganglia in Goto-Kakizaki (GK) rats, a genetic model of type 2 DM. METHODS: Twelve GK rats (276 ± 17 days of age; mean ± standard error) and 13 metabolically healthy Wistar rats (262 ± 5 days of age) as controls were used for this study. Blood glucose was determined using test strips, plasma insulin by radioimmunoassay. Intrinsic ganglia and nerves were visualized by acetylcholinesterase histochemistry on whole hearts. Ganglion area was measured, and the neuronal number was assessed according to ganglion area. RESULTS: The GK rats had significantly elevated blood glucose level compared to controls (11.0 ± 0.6 vs. 5.9 ± 0.1 mmol/l, p < 0.001), but concentration of plasma insulin did not differ significantly between the two groups (84.0 ± 9.8 vs. 67.4 ± 10.9 pmol/l, p = 0.17). The GK rats contained significantly fewer intracardiac ganglia, decreased total area of intracardiac ganglia (1.4 ± 0.1 vs. 2.2 ± 0.1 mm2, p < 0.001) and smaller somata of ganglionic neurons. Mean total number of intracardiac neurons in GK rats was 1461 ± 62, while this number in control rats was higher by 39% and reached 2395 ± 110 (p < 0.001). CONCLUSIONS: Results of our study demonstrate the decreased number of intracardiac neurons in GK rats compared to metabolically healthy Wistar rats of similar age. It is likely that the observed structural remodelling of intracardiac ganglia in GK rats is caused by a long-term diabetic state.

Distribution, structure and projections of the frog intracardiac neurons.

Histochemistry for acetylcholinesterase was used to determine the distribution of intracardiac neurons in the frog Rana temporaria. Seventy-nine intracardiac neurons from 13 frogs were labelled iontophoretically by the intracellular markers Alexa Fluor 568 and Lucifer Yellow CH to determine their structure and projections. Total neuronal number per frog heart was (Mean ± SE) 1374 ± 56. Largest collections of neurons were found in the interatrial septum (46%), atrioventricular junction (25%) and venal sinus (12%). Among the intracellularly labelled neurons, we found the cells of unipolar (71%), multipolar (20%) and bipolar (9%) types. Multiple processes originated from the neuron soma, hillock and proximal axon. These processes projected onto adjacent neuron somata and cardiac muscle fibers within the interatrial septum. Average total length of the processes from proximal axon was 348 ± 50 µm. Average total length of processes from soma and hillock was less, 118 ± 27 µm and 109 ± 24 µm, respectively. The somata of 59% of neurons had bubble- or flake-shaped extensions. Most neurons from the major nerves in the interatrial septum sent their axons towards the ventricle. In contrast, most neurons from the ventral part of the interatrial septum sent their axons towards the atria. Our findings contradict to a view that the frog intracardiac ganglia contain only non-dendritic neurons of the unipolar type. We conclude that the frog intracardiac neurons are structurally complex and diverse. This diversity may account for the complicated integrative functions of the frog intrinsic cardiac ganglia.

Topography of the porcine epicardiac nerve plexus as revealed by histochemistry for acetylcholinesterase.

The aim of the present study was to map the topography of the porcine epicardiac nerve plexus (ENP) and to re-examine the total number and distribution of the porcine intracardiac ganglia and neurons. Eleven juvenile pigs (Sus scrofa domestica, 3-4 weeks of age) were examined employing histochemistry for acetylcholinesterase to reveal the ENP on total hearts. The nerves entered porcine epicardium at five sites: (1) ventro-medially to the origin of the superior vena cava, (2) dorsally to the origin of the superior vena cava, (3) among the pulmonary veins, (4) dorso-medially to the origin of the left azygos vein, and (5) ventrally to the left pulmonary vein. Within the porcine epicardium, the nerves connected to the groups of the intrinsic ganglia and proceeded into the discrete atrial and ventricular regions via five topographical pathways (subplexuses). In general, the porcine left atrium received nerves by four subplexuses, left ventricle by three subplexuses, right atrium and right ventricle each by two subplexuses. The estimated total number of the intrinsic ganglia per porcine heart was 362+/-52. About 55% of ganglia per porcine heart were accumulated on the left atrium while 36% on the right atrium. The percentage of ganglia within porcine ventricular and para-aortic regions was 7.6% and 1.6%, respectively. On average, porcine heart contained about 12,000 intrinsic neurons. In summary, the results of the present study imply that (1) the porcine epicardiac nerves are grouped into distinct topographical pathways, and (2) the porcine atria contain significantly more intrinsic ganglia and neurons compared to the ventricles.

Architecture and age-related analysis of the neuronal number of the guinea pig intrinsic cardiac nerve plexus.

The aims of the present study have been to determine the architecture of the guinea pig intrinsic cardiac nerve plexus (ICNP) and to test whether or not the heart of this species undergoes decrease in neuronal number with aging. Nine young (3-4 weeks of age) and nine adult (18-24 months of age) animals were examined employing histochemistry for acetylcholinesterase to reveal the ICNP in total hearts. The number of intracardiac neurons in seven animals was assessed via counting of the nerve cells both on total hearts and in serial sections of the atrial walls. The intracardiac neurons from adult guinea pigs were amassed within 329 +/- 15 ganglia. The hearts of young animals contained significantly fewer ganglia, only 211 +/- 27. In adult guinea pigs approximately 60% of the intracardiac neurons were distributed within ganglia of not more than 20 neurons, but the ganglia of such size accumulated only 45% of the neurons in young animals. The total number of the intracardiac neurons estimated per guinea pig heart was 2321 +/- 215, and this number did not differ significantly between young and adult animals. The nerves entering the guinea pig heart were found both in the arterial and venous part of the heart hilum. The nerves from the arterial part of the heart hilum proceeded into the ventricles, but the nerves from the venous part of the hilum formed a nerve plexus of the cardiac hilum located on the heart base. Within the guinea pig epicardium, intrinsic nerves divided into six routes and proceeded to separate atrial, ventricular and septal regions. In conclusion, findings of this study contradict the age-related decrease of the neuronal number in the guinea pig heart and illustrate the remarkable similarity in the architecture of the intracardiac nerve plexuses between guinea pig and rat.

Key anatomic data for the use of rat heart in electrophysiological studies of the intracardiac nervous system.

The aim of the present study was to elucidate both the topography and architecture of the rat intrinsic cardiac nerve plexus, as this species becomes a frequent mammalian model for electrophysiological investigations of the intracardiac nervous system. Fifteen adult rats were examined employing histochemistry for acetylcholinesterase to visualize the intracardiac nerve plexus in hearts. Extracardiac nerves entering the rat heart were found amid aorta and pulmonary trunk as well as along both right and left cranial veins. The nerves from the arterial part of the heart hilum extended directly to the ventricles but the nerves from the venous part of the hilum interconnected among themselves forming a nerve plexus of the cardiac hilum on the heart base. Within the rat epicardium, intrinsic nerves clustered into six routes by which they selectively projected to different rat heart regions. Ventral wall of the ventricles was supplied by three neural subplexuses, dorsal ventricular wall--by one subplexus; each atrium received nerves from two distinct subplexuses. In conclusion, this morphological study demonstrates that rat intracardiac nerve plexus compounds to anatomical scheme of the same plexus in human, therefore rat is a usable model for electrophysiological experiments of the intracardiac nervous system.

Topographic morphology and age-related analysis of the neuronal number of the rat intracardiac nerve plexus.

The study was designed to determine the three-dimensional organization of the rat intrinsic cardiac neural plexus (ICNP) and to ascertain whether the rat heart undergoes a decrease in neuronal number with aging as has been reported for other mammalian species, including human. Juvenile (3-4 weeks of age, n = 14) and adult (more than 2 months of age, n = 23) animals were examined using enzyme histochemistry for acetylcholinesterase in order to visualize the ICNP in total hearts. The number of intrinsic cardiac neurons was estimated by counting nerve cells in serial sections of the atrial pieces stained with cresyl fast violet. The total number of intrinsic cardiac neurons in old rats was 6576 +/- 317. The juvenile animals contained significantly fewer such neurons, only 5009 +/- 332. Approximately 70% of all intracardiac neurons were amassed within the heart hilum, while 30% of the neurons were distributed epicardially. Within the interatrial septum, only 11 +/- 11 neurons were identified in the juvenile and 6 +/- 4 neurons in old rats. Extrinsic nerves entered the rat heart in both the arterial and venous parts of the cardiac hilum. The nerves from the arterial part of the cardiac hilum extended directly to the ventricles but the nerves from the venous part of the hilum formed a particular nerve plexus of the cardiac hilum on the heart base. Within the rat epicardium, intrinsic nerves clustered into six routes by which they selectively projected to different atrial and/or ventricular regions. In conclusion, this study provides a detailed description of the three-dimensional organization of the rat ICNP and contradicts the decrease in neuronal number with aging in the rat heart.