Anatomical and physiological characterization of avian sympathetic cardiac efferents

A comparative assessment of age-related nicotinamide adenine dinucleotide phosphate-diaphorase positivity in the spinal cord and medulla oblongata of pigeons, rats, and mice

Nicotinamide adenine dinucleotide phosphate (NADPH)-diaphorase (N-d) positive neurons have been extensively studied across various animals, and N-d neurodegenerative neurites have been detected in some aged animal models. However, detailed knowledge on N-d positivity and aging-related alterations in the spinal cord and medulla oblongata of pigeons is limited. In this study, we investigated N-d positivity and age-related changes in the pigeon's spinal cord and medulla oblongata and compared them to those in rats and mice. Pigeons, had more N-d neurons in the dorsal horn, around the central canal, and in the column of Terni in the thoracic and lumbar segments, with scattered neurons found in the ventral horn of the spinal segments. N-d neurons were also present in the white matter of the spinal cord. Morphometric analysis revealed that the size of N-d soma in the lumbosacral, cervical, and thoracic regions was substantially altered in aged pigeons compared to young birds. Furthermore, the lumbar to sacral segments underwent significant morphological alterations. The main findings of this study were the presence of age-related N-d positive bodies (ANB) in aged pigeons, predominantly in the external cuneate nucleus (CuE) and occasionally in the gracilis and CuEs. ANBs were also identified in the gracile nuclei and spinal cord in the aged rats and mice, whereas in aged rats, ANBs were detected in the CuE spinal nucleus. Immunohistochemistry showed that the age-related alterations occurred in the cell types and neuropeptides in old animals. The results suggest weak inflammatory response and neuronal dysfunction in the spinal cord in aged pigeons. Our results suggested that the ANB could be a potential aging marker for the central nervous system.

Cardiovascular responses to adrenergic agents in different acclimation states in the rock pigeon (Columba livia)

The effect of propranolol on heart rate (fH) was measured in season-acclimatized pigeons. Propranolol treatment decreased fH in winter-acclimatized pigeons, accelerated fH in summer-acclimatized pigeons, but had no effect on fH in spring-acclimatized pigeons. The effect of propranolol in summer-acclimatized pigeons is opposite to that observed in mammals. Interestingly, isoproterenol produced a propranolol-like cardioacceleration in heat-acclimated pigeons. We suggest that propranolol affects fH in summer-acclimatized pigeons via two opposing routes-a direct and a peripheral indirect route. We also suggest that the cardiovascular effects of propranolol are involved in the capacity of the pigeon to evaporate water from its skin.

Localization of sympathetic, parasympathetic and sensory neurons innervating the heart of the Beijing duck by means of the retrograde transport of horseradish peroxidase

Sympathetic, parasympathetic and sensory neurons were labeled by injections of horseradish peroxidase into various regions of the heart in 33 Beijing ducks. Sympathetic postganglionic neurons innervating the heart were located in the paravertebral ganglia C15 (C16 is the last cervical segment in the duck) to T3, especially in the ganglion T1. The coronary sulcus and ventricle were more abundantly innervated by sympathetic neurons than the atrium. The left side of the heart was preferentially innervated by sympathetic postganglionic neurons in the left side of paravertebral ganglia but the right side of the heart were equally supplied from the right and left ganglia. Within the medulla oblongata, the number of labeled vagal preganglionic neurons in the nucleus ambiguus was much greater than that in the dorsal motor nucleus of the vagus nerve. Labeled neurons of the nucleus ambiguus were found in many ducks injected into the coronary sulcus. Cardiac sensory neurons were observed in the dorsal root ganglia C15 to T2 (highest in the ganglion T1) and in the nodose and jugular ganglia of the vagus nerve. These labeled neurons probably form the afferent and efferent limbs of cardiac reflexes and control circulation in the Beijing duck.

Abnormal cardiac sensory innervation associated with experimentally induced, electrocardiographic long QT intervals in chick embryos

Prolongation of the QT interval in the ECG can be induced in d 17 chick embryos by ablating the nodose placode on the right side on d 1 of development. The nodose placode contains the precursor cells which form the neurons of the nodose (inferior vagal) ganglion. Neurons in this ganglion provide sensory innervation to the heart and other viscera. In this study, we measured ganglion volume and neuron size and number in the right and left nodose ganglia in d 17 experimental and control embryos from whom electrocardiograms had been obtained. A significant reduction in the number of neurons present in the right nodose ganglion, relative to the left ganglion, was evident in all embryos with abnormally prolonged QT intervals. Embryos with prolonged QT, as well as lesioned embryos who demonstrated normal.QT on d 17, also had abnormally small neurons in both right and left nodose ganglia, indicating an additional nonspecific, perhaps permissive, effect of the lesion. These results suggest that abnormal development of the sensory innervation of the heart may be an important link in the chain of events leading to the developmental long QT syndrome expressed by these embryos.

Spinal distribution and brainstem projection of lamina I neurons in the pigeon

Lamina I neurons of the spinal dorsal horn serve nociception both in mammals and in birds. The projection of these neurons to the brain is largely unknown in birds. Injections of retrogradely transported fluorescent tracers into various brainstem nuclei showed that these neurons, which are distributed throughout the spinal cord, heavily project to the nucleus of the solitary tract and the parabrachial area but not to the hypothalamus. Injections into the nucleus of the solitary tract revealed a group of neurons located in Lissauer's tract of thoracic segments. These results point to a functional role of spinal lamina I neurons in avian visceronociception.

Sympathetic and sensory neurons projecting into the cervical sympathetic trunk in the chicken

The cell bodies of the sensory and sympathetic pre- and postganglionic neurons projecting into the cervical sympathetic trunk were retrogradely labeled with horseradish peroxidase in the chicken. Preganglionic neurons were located in the spinal segments T1-T6 (maximum T2), postganglionic neurons in the paravertebral ganglia T1-T3 (maximum T1) and sensory neurons in the dorsal root ganglia T1-T4 (maximum T1). Labeled preganglionic neurons were widely distributed across the intermediate gray matter and lateral funiculus, but the majority of them were located in the intermediomedial area dorsolateral to the central canal. The short and long axis diameters of labeled preganglionic neurons in this area decreased caudally. From the data of the present study, it is estimated that about 4190 preganglionic, about 450 postganglionic and about 390 sensory neurons project into the cervical sympathetic trunk cranial to the paravertebral ganglion T1 in the chicken.

Retrograde, trans-synaptic and transneuronal transport of fragment C of tetanus toxin by sympathetic preganglionic neurons

The atoxic binding fragment of tetanus toxin, Fragment C, was injected into paravertebral ganglion 14, the avian homologue of the mammalian stellate ganglion. Postinjection survival intervals were varied from 2.5 h to 33 days. Experiments performed at the shortest survival time of 2.5 h showed that Fragment C was retrogradely transported by sympathetic preganglionic axons at a rate greater than or equal to 10 mm/h. At survival times ranging from 5 to 15 h. Fragment C-positive, retrogradely labeled sympathetic preganglionic neurons were observed within the last cervical spinal segment and throughout the first three thoracic spinal cord segments. Sporadic retrograde labeling of sympathetic preganglionic neurons was evident within the fourth and fifth thoracic spinal cord segments. Fragment C-labeled perikarya and dendrites exhibited both diffuse cytoplasmic immunostaining as well as intracellular, perinuclear accumulations of small. Fragment C-positive granules. Retrogradely labeled preganglionic neurons were found within both autonomic subnuclei within avian thoracic spinal cord; the column of Terni and the nucleus intercalatus spinalis. The distribution and numerical density of retrogradely labeled sympathetic preganglionic neurons indicated further that: (a) both myelinated and unmyelinated preganglionic axons appear to be capable of intra-axonally transporting Fragment C; and (b) it is unlikely that there is differential Fragment C labeling of a morphologically distinct population of sympathetic preganglionic neurons within or across subnuclei. Fragment C is transferred out of sympathetic preganglionic somas and dendrites into the surrounding neuropil at an aggregate rate greater than or equal to 5 mm/h. Trans-synaptic transport was evident at postinjection survival times as short as 5 h and continued to increase in density within the sympathetic preganglionic neuropil for 24 h. Fragment C-positive terminal labeling persisted for at least 20 days. At survival times greater than or equal to 1 day. Fragment C-positive puncta and weak intracellular labeling of neurons were evident in areas of the spinal gray outside of the nuclear boundaries of the column of Terni and nucleus intercalatus. The regions showing evidence of trans-synaptic and transneuronal labeling included: (a) a group of small cells dorsal to the column of Terni, (b) lamina V and (c) lamina VII. This expansion of Fragment C-labeled neuronal elements was segmental in organization and co-extensive with the retrograde labeling pattern of sympathetic preganglionic neurons. Spinal interneurons in these regions may provide segmental, monosynaptic input to sympathetic preganglionic neurons. Fragment C leaked into the systemic circulation from the site of injection in paravertebral ganglion 14.(ABSTRACT TRUNCATED AT 400 WORDS)

Middle cardiac nerve section alters ventilatory response to PaCO2 in the cockerel

To determine whether afferents in the middle cardiac nerves (MCN) contribute to extrapulmonary PaCO2 sensitivity, we did the following: we anesthetized six cockerels with sodium pentobarbital (25-35 mg/kg), and cannulated the cutaneous ulnar vein, and the carotid and brachial arteries. The thorax was opened and each lung unidirectionally ventilated from separate gas delivery systems. A ligature, which temporarily occluded blood flow, was placed around the right pulmonary artery. Both cardiac sympathetic nerves were cut, as well as the left vagus just above the level of the recurrent branch. We exposed the non-perfused right lung to 105 Torr PCO, to silence intrapulmonary chemoreceptors (IPC). We measured blood pressure, heart rate and ventilatory movements while the denervated left lung was used to fix PaCO2 at seven levels ranging from 7-140 Torr. As arterial PCO2 increased, ventilatory amplitude increased from 0.3 mm to 3.6 mm, while frequency decreased from 140 to 24 per min. After cutting the MCN, ventilatory movements were less responsive to PaCO2 changes. Ventilatory amplitude was 3.0 mm at the lowest PaCO2 and increased to 4.0 at the highest PaCO2. We conclude that: 1) when IPC discharge is low, afferents in the MCN inhibit ventilatory movements during hypocapnia, and 2) these afferents may contribute to systemic CO2 sensitivity.

Raphe inhibition of sympathetic preganglionic neurons

Anatomical and electrophysiological studies suggest that the medullary raphe gives rise to a monosynaptic, inhibitory projection on sympathetic preganglionic neurons. Physiological and behavioral data indicate that this sympathoinhibitory pathway participates in the central control of cardiovascular function.

Localization of sensory neurons traversing the stellate ganglion of the cat

The distribution of sensory cells whose axons traverse the stellate ganglion and project via sympathetic cardiac nerves to the heart of the cat has been examined quantitatively. Horseradish peroxidase (HRP) injected at multiple sites in the right stellate ganglion, or applied to the middle cardiac nerve, labelled small numbers of cells in the thoracic dorsal root ganglia (DRG) from T1 to T8. These cells were most numerous between T2 and T5 and were consistently small (less than 40 micrometer) relative to other cells in the DRG. When HRP was applied to middle cardiac nerves, the numbers of labelled sensory cells always exceeded the numbers of myelinated axons counted in the same nerves from other cats. It is concluded that the distribution of the cells of cardiac sensory fibers is more extensive within thoracic DRG than has been previously reported, and it is suggested that such fibres travelling in the sympathetic cardiac nerves may be either myelinated or unmyelinated.

Avian sympathetic cardiac fibers and their cells of origin: anatomical and electrophysiological characteristics

The sympathetic cardiac innervation of the pigeon was investigated to describe certain anatomical and physiological properties of the cardiac nerve fibers and their postganglionic cells of origin. The compound action potential of the right cardiac nerve has two major components, one conducting at 2.0-5.6 m/sec with no chronotropic effect on the heart and the other conducting at 0.4-1.0 m/sec with a cardioacceleratory effect. Postganglionic neurons responding antidromically to cardiac nerve stimulation were then studied in ganglion 14 which contains most cells of origin of the cardiac fibers. These neurons have refractory periods of approximately 4 msec, following frequencies of less than 4 HZ, and axons conducting at 0.4-2.0 m/sec; this conduction velocity range corresponds to the slower compound action potential component. Electron microscopy of the cardiac nerve revealed unmyelinated fibers ranging in diameter from 0.2 to 1.2 micrometer and a population of myelinated fibers 1.0-3.6 micrometer in diameter. The unmyelinated fibers account for the slower compound action potential component and are largely postganglionic cardioaccelerator axons. The myelinated fibers account for the faster compound action potential component which has no chronotropic effect and is not reflected in postganglionic antidromic latencies; it is suggested that these myelinated fibers are cardiac sympathetic afferents. This study thus establishes electrophysiological criteria for identifying cardiac postganglionic neurons and describes the anatomical basis of these criteria.