Preganglionic fibers in the rat hypogastric nerve project bilaterally to pelvic ganglia

Stimulation of the hypogastric nerve (HGN) often evokes bilateral responses in some pelvic organs. Retrograde labeling studies indicate that axons of postganglionic neurons often cross to the opposite side. However, there is little information available as to whether preganglionic fibers in the HGN have a contralateral projection to pelvic ganglia. A retrograde tracer was injected into the left major pelvic ganglion (MPG) in rats receiving various lesions of preganglionic nerves (HGN and pelvic nerve, PN). The lumbar spinal cord was then examined for location and number of dye-filled neurons. In a second approach, the incidence of synaptophysin immunoreactivity (SN-IR) perineuronal profiles (baskets) was examined in the MPG and in the accessory pelvic ganglia (APG) after nerve lesions. Labeled neuronal profiles were found in spinal cord nuclei (Lumbar_1–2) after dye injection of the MPG in animals with an intact contralateral HGN. Cutting both HGNs virtually eliminated dye labeling in the lumbar cord, as did severing commissural branches (CB) between pelvic ganglia (leaving the contralateral HGN intact). Some SN-IR baskets were found in the left APG when only the contralateral HGN was intact, but baskets were rare when all four preganglionic nerves were cut. It could not be determined whether the HGN projects to the contralateral MPG, since SN-IR baskets were numerous in the MPG even when all four nerves were cut. This study has shown that some preganglionic fibers in the HGN synapse on neurons in contralateral pelvic ganglia. Both the APG and MPG receive contralateral innervation, but it is likely that neurons in the APG are the primary target of this input. Thus, in addition to crossing postganglionic fibers, a portion of the bilateral control of pelvic tissues is accomplished by preganglionic fibers which target autonomic neurons in contralateral ganglia. Anat. Rec. 252:229–234, 1998. © 1998 Wiley-Liss, Inc.     

Axons of sacral preganglionic neurons in the cat: II. Axon collaterals

Axon collaterals were identified in 21 of 24 preganglionic neurons in the lateral band of the sacral parasympathetic nucleus of the cat. Following the intracellular injection of HRP or neurobiotin the axons from 20 of these neurons were followed and 53 primary axon collaterals were found to originate from unmyelinated segments and from nodes of Ranvier. Detailed mapping done in the five best labeled cells showed bilateral axon collaterals distributions up to 25,000 microm in length with 950 varicosities and unilateral distributions up to 12,561 microm with 491 varicosities. The axon collaterals appeared to be unmyelinated, which was confirmed at EM, and were small in diameter (average 0.3 microm). Varicosities were located mostly in laminae I, V, VII, VIII and X and in the lateral funiculi. Most varicosities were not in contact with visible structures but some were seen in close apposition to Nissl stained somata and proximal dendrites. Varicosities had average minor diameters of 1.3 microm and major diameters of 2.3 microm. Most were boutons en passant while 10-20% were boutons termineaux. EM revealed axodendritic and axoaxonic synapses formed by varicosities and by the axons between varicosities. It is estimated that the most extensive of these axon collaterals systems may contact over 200 spinal neurons in multiple locations. These data lead to the conclusion that sacral preganglionic neurons have multiple functions within the spinal cord in addition to serving their target organ. As most preganglionic neurons in this location innervate the urinary bladder, it is possible that bladder preganglionic neurons have multiple functions.     

Distribution and origin of secretoneurin-immunoreactive nerves in the female rat uterus

Secretoneurin is a 33-amino acid peptide derived from secretogranin II. Secretoneurin immunoreactivity has been localized in the peripheral nervous system where it exerts potent chemotactic activity for monocytes and may play a role in inflammation. Secretoneurin could play a role in this process, although the presence and distribution of secretoneurin-immunoreactive neurons in the female reproductive system has not been documented. Thus, this study was undertaken to examine secretoneurin immunoreactivity in nerves of the rat uterus and uterine cervix. A moderate plexus of secretoneurin-immunoreactive nerve fibers was present in the myometrium and endometrium of the uterus as well as in the smooth muscle and endocervix of the cervix. Many of these fibers were associated with the vasculature as well as the myometrium. Secretoneurin immunoreactivity was present in small- to medium-sized neurons of dorsal root and nodose ganglia. Retrograde tracing with FluoroGold indicated that some of these sensory neurons project axons to the cervix and uterine horns. Secretoneurin-immunoreactive terminal-like structures were associated with neurons in the sacral parasympathetic nucleus of the lumbosacral spinal cord. In addition, some secretoneurin terminals were apposed to pelvic parasympathetic neurons in the paracervical ganglia that projected axons to the uterus and cervix. Double-immunostaining indicated co-existence of calcitonin gene-related peptide or substance P with secretoneurin in some sensory neurons, in some terminals of the pelvic ganglia, as well as nerve fibers in the uterine horn and cervix. Finally, fibers in the uterus and cervix were depleted of secretoneurin by capsaicin treatment. This study indicates that secretoneurin is present in the uterus in C-afferent nerve fibers whose cell bodies are located in sensory ganglia. Some of these fibers contain both secretoneurin and calcitonin gene-related peptide or substance P. These substances have functions in inflammatory reactions. Further, secretoneurin could influence postganglionic parasympathetic "uterine-related" neurons in the pelvic ganglia and preganglionic parasympathetic neurons in the lumbosacral spinal cord.     

Properties of axons of sympathetic preganglionic neurons of the lower thoracic spinal cord

Sympathetic preganglionic fibers arising in spinal cord segments T7-T10. were investigated. Conduction velocity, excitability and refractory period were obtained by recording the antidromic wave in the ventral roots and the antidromic discharge in sympathetic preganglionic lateral horn neurons. Conduction along the spinal part of the axons is slower than along the peripheral. In four sympathetic preganglionic neurons inhibition of subsequent antidromic responses took place after antidromic stimulation. This suggests that axons of these neurons have recurrent collaterals.     

Distribution of neuropeptides in rat pterygopalatine ganglion: light and electron microscopic immunohistochemical studies.

The distribution and quantity of neuropeptides in the rat pterygopalatine ganglion were studied by using complete serial paraffin sections of the ganglion immunostained with antiserum against several neuropeptides. The pterygopalatine ganglion, composed of 4932 +/- 291 (mean +/- SD) neurons, was triangular in shape with a tapering caudal tail. The most commonly found peptide in neurons was vasoactive intestinal polypeptide (VIP) (99.0%), followed by neuropeptide Y (NPY) (54.1%) and enkephalin (10.5%). The rostro-ventromedial and caudal parts of the ganglion where intensely VIP-immunoreactive neurons predominate project to the nasal mucosa, while the rostro-dorsolateral part of the ganglion where NPY-immunoreactive neurons predominate projects to the Harderian gland. The coexistence of VIP/NPY (47.4%), VIP/NPY/enkephalin (6.6%) or VIP/enkephalin (3.9%) in the ganglionic neurons was recognized. Calcitonin gene-related peptide (CGRP)- and substance P-immunoreactive varicosities formed synaptic contacts with the somatic spine or soma, which confirmed that the reflex arch, composed of axon collaterals of trigeminal ganglionic neurons and parasympathetic ganglionic neurons, operates through direct synapses. Enkephalin-immunoreactive varicosities, which were probably derived from parasympathetic preganglionic neurons, also made synaptic contact with the somatic spine.     

Prenatal development of transient receptor potential vanilloid 1-expressing primary sensory projections to sacral autonomic preganglionic neurons

The visceral reflexes of the pelvic organs are mediated by connections between primary afferents innervating the pelvic organs and parasympathetic preganglionic neurons in the intermediolateral column of the sacral spinal cord. The present immunohistochemical study revealed many varicosities expressing transient receptor potential vanilloid 1 (TRPV1) that were closely apposed to the preganglionic neuronal perikarya at embryonic day 16 in mice. Many, but not all, varicosities expressing TRPV1 in the intermediolateral column were also immunopositive for calcitonin gene-related peptide. In contrast, no nerve fibers expressing TRPV1 projected to the sympathetic preganglionic cell column in the lumbar spinal cord in prenatal stages. The results of the present study raised the possibility that the primary afferents transmit signals elicited by the activation of TRPV1 receptors to the sacral parasympathetic preganglionic neurons. Thus, the functional circuit for pelvic spinal reflexes, such as micturition induced by urine influx, might develop in the prenatal stages in mice.     

Reconsideration of the Autonomic Cranial Ganglia: An Immunohistochemical Study of Mid‐Term Human Fetuses

The cranial parasympathetic ganglia have been reported to paradoxically contain the sympathetic nerve marker, tyrosine hydroxylase (TH), in addition to neurons expressing parasympathetic markers such as vasoactive intestinal peptide (VIP) and neuronal nitric oxide synthase (nNOS). However, the distribution of these molecules in the cranial ganglia of human fetuses has not yet been examined. Using paraffin sections from 10 mid‐term human fetuses (12–15 weeks), we performed immunohistochemistry for TH, VIP, and nNOS in the parasympathetic ciliary, pterygopalatine, otic, and submandibular ganglia, and for comparison, the sensory inferior vagal ganglion. The ciliary and submandibular ganglia contained abundant TH‐positive neurons. In the former, TH‐positive neurons were much more numerous than nNOS‐positive neurons, whereas in the latter, nNOS immunoreactivity was extremely strong. No or a few cells in the pterygopalatine, otic, and inferior vagal ganglia expressed TH. Ciliary TH neurons appeared to compensate for classically described sympathetic fibers arising from the superior cervical ganglion, whereas in the submandibular ganglion, nNOS‐positive neurons as well as TH neurons might innervate the lingual artery in addition to the salivary glands. Significant individual variations in the density of all these markers suggested differences in sensitivity to medicine affecting autonomic nerve function. Consequently, in the human cranial autonomic ganglia, it appears that there is no simple dichotomy between sympathetic and parasympathetic function. Anat Rec, 2012. © 2011 Wiley Periodicals, Inc.     

Sympathetic neurons in lower cervical ganglia send axons through the superior cervical ganglion

In addition to the preganglionic axons which innervate the superior cervical ganglia, the cervical sympathetic trunks of the rat have been shown to contain axons of ganglionic neurons. Following the application of horseradish peroxidase to the cut cervical sympathetic trunk just caudal to the superior cervical ganglion, a population of approximately 300 labeled neurons was found in the inferior and middle cervical ganglia. The labeled neurons were localized primarily in the more rostral regions of these ganglia. The axons of most of these neurons entered the superior cervical ganglion, passed through it, and left via the external carotid nerve.The relevance of these observations to physiological studies on the cervical sympathetic nervous system is discussed     

Selective uptake of C-fragment of tetanus toxin by sympathetic preganglionic nerve terminals

Immunohistochemical techniques have shown that the C-fragment of tetanus toxin injected into medial gastrocnemius muscle in the guinea-pig and rat, in addition to its retrograde transport in the axons of the somatomotor, sympathetic and sensory neurons supplying this muscle, is taken up and concentrated by terminal varicosities within pre- and paravertebral sympathetic ganglia at all thoracolumbar levels. Staining was absent in chronically denervated ganglia, demonstrating the specific association of the antigen with preganglionic varicosities. Preganglionic varicosities at all levels were also labelled after C-fragment injection into the peritoneal cavity or into denervated medial gastrocnemius; both of these procedures failed to label somatomotor or sensory neurons. Although retrograde trans-synaptic transport could be demonstrated, sympathetic labelling was sparse and non-specific, so that the C-fragment of tetanus toxin is unsuitable for the identification of sympathetic pathways. The selective and widespread uptake of tetanus toxin by sympathetic preganglionic terminals could explain the diverse autonomic symptoms observed in tetanus intoxication.     

Parasympathetic preganglionic neurons in the spinal cord involved in uterine innervation are cholinergic and nitric oxide-containing

Background: The purpose of this study was to elucidate parasympathetic preganglionic neurons in the spinal cord that project axons in pathways to the uterus and to reveal their neurotransmitter phenotype. Methods: “Uterine-related” neurons were identified by using a combination of retrograde axonal tracers: (1) Fluorogold injected into the ganglia of termination of preganglionic fibers, and (2) a transganglionic axonal tracer (pseudorabies virus) injected into the uterus. Immunohistochemistry was used to reveal virus-labeled neurons and their neurotransmitter marker. Results: Double-labeled (Fluorogold + pseudorabies virus) “uterine” preganglionic neurons were identified in the sacral parasympathetic nucleus of the rat lumbosacral spinal cord. Subpopulations of neurons in the sacral parasympathetic nucleus were shown to be immunoreactive for choline acetyltransferase or nitric oxide synthase. Double-staining immunohistochemistry (for pseudorabies virus + neurotransmitter enzyme) revealed that some of the uterine-related preganglionic neurons were cholinergic and some nitric oxide synthase-containing. Conclusions: These results demonstrate a subpopulation of pregauglionic parasympathetic neurons in the sacral parasympathetic nucleus that are involved in uterine innervation. In addition, both acetylcholine and nitric oxide could be used to modify activity in the postganglionic neurons, which directly innervate the uterus. © 1995 Wiley-Liss, Inc.     

猫空回肠交感节后神经元和副交感节前神经元的局部定位

本文应用ＨＲＰ逆行标记法研究猫空回肠的植物神经支配，发现猫空回肠交感节后神经纤维来自腹腔节和肠系膜前节以及双侧Ｔ９～Ｌ５交感于神经节，但大多数来自椎前节。交感节神经元大多数呈簇状集中分布在右侧腹腔节的前下部和肠系膜前节，而在左侧腹腔节和右侧腹腔节后上部仅有少数散在分布的标记细胞，具有明显的局部定位分布的特征。猫空回肠的交感节后神经元在双侧交感于神经节具有基本相同的分布范围，即Ｔ９～Ｌ５节段。其集中分布节段是Ｔ１１～Ｌ３，符合“既分散又集中的分布模式”。腹腔节和肠系膜前节内的标记细胞呈椭圆形、圆形或不规则形。交感干神经节内的标记细胞呈椭圆形和梭形。猫空回肠的副交感书前神经元主要分布在双侧迷走神经前核的闩以上４ｍｍ到闩以下２ｍｍ的范围内．但多数分布在此核的背外侧部靠近闩的水平上，细胞呈椭圆形。     

Autonomic innervation of reproductive organs: analysis of the neurons whose axons project in the main penile nerve in the pelvic plexus of the rat

An understanding of the composition of the various nerves of the pelvic plexus is essential in the design of studies to explore the autonomic control of pelvic visceral tissues. As a correlate of this interest, the present study was designed to determine the composition of the main penile nerve in the pelvic plexus of the laboratory rat, an animal commonly used for studies of reproductive physiology. Retrograde tracing studies indicate that the main penile nerve contains neurons which project to the penile crura, the corpus spongiosum, and the bulbourethral glands. The main penile nerve is the major source of neurons which innervate the corpus spongiosum and bulbourethral gland and contains about one-third of all parasympathetic neurons which project to the penile crura. Dye placed on the proximal cut end of the main penile nerve indicates that neurons in the parasympathetic region of the spinal cord (L6-S1) and to a lesser extent a sympathetic region of the cord, L1-L2, provide preganglionic innervation to ganglion cells in the main pelvic nerve. Processes of neurons in dorsal root ganglia L6-S1 and of neurons in the abdominopelvic sympathetic chain course in the main penile nerve to unknown destinations. In many respects this presumed postganglionic fiber tract is essentially a region of the pelvic plexus which subserves extrapelvic visceral tissues.     

Facial nerve parasympathetic preganglionic afferents to the accessory otic ganglia by way of the chorda tympani nerve in the cat

 The distribution of accessory otic ganglia and connections between the ganglia and the chorda tympani nerve were investigated in the cat in order to determine the parasympathetic preganglionic facial nerve afferents to the otic ganglia using whole mount acetylthiocholinesterase (WATChE) histochemistry. The otic ganglia consist of a sigle main prominent ganglion and many small accessory ganglia lying on a plexus around the origins of the branches of the mandibular nerve and near the junction of the chorda tympani nerve and lingual nerve. In cell analysis of Nissl-stained preparations, the neurons composing the accessory otic ganglia were morphologically similar to the main otic ganglion neurons. Connecting branches from the chorda tympani nerve to the peripherally located acccessory otic ganglia were found and they were not stained by WATChE histochemistry. WATChE-positive connecting branches from the ganglia to the inferior alveolar, lingual, and mylohyoid nerves were also found in the same preparations. The WATChE histochemistry on various autonomic nervous tissues revealed that autonomic postganglionic nerve fibers are selectively stained darkly and that preganglionic fibers remain unstained. Therefore, it is considered that the WATChE-negative connections from the chordra tympani nerve consist chiefly of autonomic preganglionic fibers, whereas the WATChE-positive connections to the branches of the mandibular nerve are mainly postganglionic fibers. This suggests that some of the facial nerve parasympathetic preganglionic fibers in the chorda tympani nerve are mediated in the accessory otic ganglia and then join the branches of the mandibular nerve to supply the target mandibular tissues. Accepted: 25 November 1997     

Neural circuit of the cervical sympathetic nervous system with special reference to input and output of the cervical sympathetic ganglia: relationship between spinal cord and cervical sympathetic ganglia and that between cervical sympathetic ganglia and their target organs

Using anterograde labeling technique with Phaseolus vulgaris leucoagglutinin (PHA-L), we demonstrated the arborization pattern of a single preganglionic axon in the superior cervical ganglion (SCG) and stellate ganglion (STG). These axons expanded in the longitudinal direction, but not for transverse direction. Segmental relationship was identified between the spinal cord and STG, as seen between spinal cord and sympathetic ganglia in the thoraco-lumbar region, but we did not find any segmental relationship between the spinal cord and SCG. Some sympathetic preganglionic neurons in the lateral horn of the thoracic cord, especially in the intermediolateral nucleus (IML) have nitric oxide synthase (NOS) activity. We demonstrated that SCG neurons, which were heavily innervated by these NOS-positive neurons, tended to innervate organs that have some secretory functional tissues. Finally, we showed that the size of neuronal somata does not correlate with the size of target organs, as has been reported in previous studies. We should consider that there are other factors determining the size of neuronal somata, such as the size of dendritic field or volumes of NGF secretory from target tissues.     

The relationship between serotonin, dopamine beta hydroxylase and GABA immunoreactive inputs and spinal preganglionic neurones projecting to the major pelvic ganglion of Wistar rats

Preganglionic neurones in the lumbosacral spinal cord give rise to nerves providing the parasympathetic and sympathetic innervation of pelvic organs. These neurones are modulated by neurotransmitters released both from descending supra-spinal pathways and spinal interneurones. Though serotonin has been identified as exerting a significant influence on these neurones, few studies have investigated the circuitry through which it achieves this particularly in relation to sympathetic preganglionic neurones. Using a combination of neuronal tracing and multiple immunolabeling procedures, the current study has shown that pelvic preganglionic neurones receive a sparse, and probably non-synaptic, axosomatic/proximal dendritic input from serotonin-immunoreactive terminals. This was in marked contrast to dopamine beta hydroxylase-immunoreactive terminals, which made multiple contacts. However, the demonstration of both serotonin, and dopamine beta hydroxylase immunoreactive terminals on both parasympathetic and sympathetic preganglionic neurones provides evidence for direct modulation of these cells by both serotonin and norepinephrine. Serotonin-containing terminals displaying conventional synaptic morphology were often seen to contact unlabeled somata and dendritic processes in regions surrounding the labeled preganglionic cells. It is possible that these unlabeled structures represent interneurones that might allow the serotonin containing axons to exert an indirect influence on pelvic preganglionic neurones. Since many spinal interneurones employ GABA as a primary fast acting neurotransmitter we examined the relationship between terminals that were immunoreactive for serotonin or GABA and labeled pelvic preganglionic neurones. These studies were unable to demonstrate any direct connections between serotonin and GABA terminals within the intermediolateral or sacral parasympathetic nuclei. Colocalization of serotonin and GABA was very rare but terminals immunoreactive for each were occasionally seen to contact the same unlabeled processes in close proximity. These results suggest that in the rat, the serotonin modulation of pelvic preganglionic neurones may primarily involve indirect connections via local interneurones.     

雄性大鼠催产素纤维与脊髓泌尿生殖器调控神经元的关系

目的:观察丘脑催产素纤维与雄性大鼠脊髓泌尿生殖器调控神经元的关系。方法:微量莹光金注入雄性大鼠左侧盆腔神经节后3 d,截取脊髓胸11-骶2节段分别做横切和纵切片,观察免疫荧光组织化学显示脊髓催产素纤维和莹光金逆行示踪标记的脊髓神经元。结果:荧光金逆行示踪标记神经元位于脊髓胸12-腰2节段左侧的交感神经核﹑后灰质联合以及左侧腰6和骶1节段侧角的副交感神经核。含催产素纤维分布于荧光金标记的神经元周围。结论:丘脑催产素纤维密集分布于脊髓调控泌尿生殖器的交感和副交感节前神经元周围,这种特征性分布方式提示催产素纤维对泌尿生殖器可能有重要调节作用。     

Reduction of glial fibrillary acidic protein-immunoreactive astrocytes in some brain areas of old hairless rhino-j mice (hr-rh-j)

In the rat the majority of sympathetic and parasympathetic postganglionic neurons that innervate the pelvic viscera are located together in the major pelvic ganglia. We have ascertained that it is only the sympathetic population of this ganglion that exhibits age-associated attrition. Recent immunohistochemical investigations of the distribution of calcium binding proteins in this ganglion in young adult and aged rats have demonstrated that calbindin-D28k is only present in the sympathetic neurons and that the number of calbindin-immunoreactive sympathetic neurons of the aged ganglion was dramatically reduced. In the present study we have investigated the distribution of neurocalcin (NC) alpha isoform in the major pelvic ganglion. In young adults 98.7% of sympathetic neurons (identified by anti-tyrosine hydroxylase immunostaining) and 98% of parasympathetic neurons (identified by anti-nitric oxide synthase immunostaining) contained NC immunoreactivity and these figures are reduced to 68 and 45.5% in the aged group. Thus, unlike calbindin-D28k, NC is not confined to the sympathetic neuron population in the major pelvic ganglion and decreases significantly in old age in both neuronal populations. The likely effects are to impair intracellular calcium-dependent signalling in neurons of the major pelvic ganglion, possibly compounding the effects of the previously reported decrease in calbindin-D28k in the sympathetic population.     

Axons of sacral preganglionic neurons in the cat: I. Origin,initial segment,and myelination

Parasympathetic preganglionic neurons in the cat sacral spinal cord innervate intraspinal neurons and pelvic target organs. Retrograde tracing studies have revealed little of the morphology of their axons including their origin, initial segments, or their myelin, due to methodological limitations. Intracellular labeling of single neurons with neurobiotin or HRP has overcome these problems. Axons were studied in 24 preganglionic neurons. In 21 neurons the axon originated as a branch of a dendrite, without a detectable axon hillock, at distances from the soma ranging from 10 to 110 m (average 34.1 m ). In 3 neurons the axon was derived from the soma. Initial segments, present in all cells, ranged from 15 to 40 m (average 26.8 m). Nearly all axons followed the initial segment with unmyelinated segments that varied between 59 to 630 m, followed by myelin and nodes of Ranvier. Internodal distances were variable and relatively short (average 93 m). Axonal diameters measured over the intraspinal course in 18 axons averaged 1.3 m (range 0.6–2.4 m) and were relatively constant compared with other neurons. Spine-like protrusions were observed on the initial segments of 12 cells. Axon collaterals originated from unmyelinated sections and nodes of Ranvier. Antidromic action potentials showing initial segment, soma-dendritic inflections, did not differentiate between soma-derived and dendrite-derived axons. The data suggest that axons originating from a dendrite are the normal structure of preganglionic neurons in the lateral sacral parasympathetic nucleus. It is proposed that the particular structure of these axons may be part of a timing mechanism that coordinates preganglionic neurons with other spinal neurons involved in target organ reflexes.     

Acute implantation of an avulsed lumbosacral ventral root into the rat conus medullaris promotes neuroprotection and graft reinnervation by autonomic and motor neurons

Trauma to the conus medullaris and cauda equina may result in autonomic, sensory, and motor dysfunctions. We have previously developed a rat model of cauda equina injury, where a lumbosacral ventral root avulsion resulted in a progressive and parallel death of motoneurons and preganglionic parasympathetic neurons, which are important for i.e. bladder control. Here, we report that an acute implantation of an avulsed ventral root into the rat conus medullaris protects preganglionic parasympathetic neurons and motoneurons from cell death as well as promotes axonal regeneration into the implanted root at 6 weeks post-implantation. Implantation resulted in survival of 44+/-4% of preganglionic parasympathetic neurons and 44+/-4% of motoneurons compared with 22% of preganglionic parasympathetic neurons and 16% of motoneurons after avulsion alone. Retrograde labeling from the implanted root at 6 weeks showed that 53+/-13% of surviving preganglionic parasympathetic neurons and 64+/-14% of surviving motoneurons reinnervated the graft. Implantation prevented injury-induced atrophy of preganglionic parasympathetic neurons and reduced atrophy of motoneurons. Light and electron microscopic studies of the implanted ventral roots demonstrated a large number of both myelinated axons (79+/-13% of the number of myelinated axons in corresponding control ventral roots) and unmyelinated axons. Although the diameter of myelinated axons in the implanted roots was significantly smaller than that of control roots, the degree of myelination was appropriate for the axonal size, suggesting normal conduction properties. Our results show that preganglionic parasympathetic neurons have the same ability as motoneurons to survive and reinnervate implanted roots, a prerequisite for successful therapeutic strategies for autonomic control in selected patients with acute conus medullaris and cauda equina injuries.     

Uptake and retrograde axonal transport of horseradish peroxidase in regenerating facial motor neurons of the mouse

Summary Uptake and retrograde axonal transport of intravenously injected horseradish peroxidase (HRP) was studied during regeneration after a crush injury of the facial nerve of the mouse. The circulation time of HRP was 12 to 24 h. HRP injected immediately after the crush diffused into injured axons in the crushed region and accumulated subsequently in perikarya of facial neurons in the brain stem. After a time interval of 1 h or 5 days between the crush and the injection only a faint HRP accumulation occurred in a few facial neurons. After an interval of 7 days a moderate number of neurons had incorporated the tracer, while after more than 9 days the HRP activity in the regenerating neurons was more pronounced than in the contralateral neurons. Ultrastructurally, muscles of the vibrissae showed denervated subneural apparatuses 6 days after the crush. 8 days after the crush regenerating axon terminals containing small clusters of synaptic vesicles, dense cored vesicles and some HRP-labelled vesicles, were found over some gutters and after 10 to 13 days all examined gutters contained axon terminals with large numbers of synaptic vesicles and some HRP-containing vesicles. More than one axon terminal profile was seen in the same synaptic gutter. 32 and 64 days after the crush the neuromuscular junctions had regained a more mature appearance. The calibre spectra of the crushed facial nerves still showed a shift towards smaller diameters 134 days after the crush, at a time when a slight increase in HRP activity in the facial neurons persisted.