The fine structure of human Golgi tendon organs as studied by three-dimensional reconstruction

Three-Dimensional Ultrastructure of Flower-Spray Nerve Endings in the Rat Carotid Sinus

The flower-spray nerve endings are afferent nerve terminals in the carotid sinus that arise from carotid sinus nerve of glossopharyngeal nerve. However, the three-dimensional ultrastructural characteristics of flower-spray nerve endings and spatial relationships between the terminal parts and other cellular elements have not been fully understood. To elucidate their detailed relationship, backscattered electron imaging of serial sections was performed with a scanning electron microscope to produce a three-dimensional reconstruction of the flower-spray endings. The terminal parts of flower-spray endings were distributed horizontally approximately 5 µm outside the external elastic membrane in the tunica adventitia of the internal carotid artery. The three-dimensional reconstruction showed that the terminal parts of flower-spray endings were flat with irregular contours and were partially covered by the thin cytoplasmic processes of Schwann cells. The complex consisting of the nerve terminals and associated Schwann cells was surrounded by a multilayered basement membrane. The terminal parts of the endings were also surrounded by fibroblasts with elastic fibers and collagen fibrils. Secretory vesicles without an electron-dense core were observed in the terminal parts of the endings. The accumulation of vesicles just below the axonal membrane was observed in terminal parts not covered by Schwann cell cytoplasmic processes on both the luminal and basal sides. Swollen mitochondria, concentric membranous structures, and glycogen granule-like electron-dense materials were often noted in some of the terminal parts of the endings and the parent axon. Collectively, the present results suggest that flower-spray endings are baroreceptors because their morphology was similar to other mechanoreceptors. Furthermore, flower-spray endings may be affected by glutamate secreted in an autocrine manner.

Three-dimensional architecture of the subepithelial corpuscular nerve ending in the rat epiglottis reconstructed by array tomography with scanning electron microscopy

In the rat laryngeal mucosa, subepithelial corpuscular nerve endings, called laminar nerve endings, are distributed in the epiglottis and arytenoid region and are activated by the pressure changes of the laryngeal cavity. They are also suggested to play a role in efferent regulation because of secretory vesicles in the axoplasm. In the present study, the laminar nerve endings in the rat laryngeal mucosa were analyzed by 3D reconstruction from serial ultrathin sections in addition to immunohistochemistry for synapsin 1. In the light microscopy, synapsin 1-immunoreactive flattened or bulbous terminal parts of the laminar endings were also immunoreactive with VGLUT1, and were surrounded by S100- or S100B-immunoreactive Schwann cells and vimentin-immunoreactive fibroblasts. In the electron microscopy, 3D reconstruction views showed that laminar endings were composed of flattened terminal parts sized 2-5 μm in longitudinal length, overlapping in three to five multiple layers. The terminal parts of the endings were incompletely wrapped by flat cytoplasmic processes of the Schwann cells. In addition, the fibroblast network surrounded the complex of nerve endings and the Schwann cells. Several terminal parts entered through the basement membrane into the epithelial layer and attached to the basal epithelial cells, suggesting that interaction between epithelial cells and laminar nerve endings plays an important role in sensing the pressure changes in the laryngeal cavity. Secretory vesicles were unevenly distributed throughout the terminal part of the laminar nerve endings. The secretory vesicles were frequently observed in the peripheral limb of the terminal parts. It suggests that the laminar nerve endings in the larynx may release glutamate to maintain continuous discharge during the stretching of the laryngeal mucosa.

A novel path to chronic proprioceptive disability with oxaliplatin: Distortion of sensory encoding

Persistent neurotoxic side effects of oxaliplatin (OX) chemotherapy, including sensory ataxia, limit the efficacy of treatment and significantly diminish patient quality of life. The common explanation for neurotoxicity is neuropathy, however the degree of neuropathy varies greatly among patients and appears insufficient in some cases to fully account for disability. We recently identified an additional mechanism that might contribute to sensory ataxia following OX treatment. In the present study, we tested whether that mechanism, selective modification of sensory signaling by muscle proprioceptors might result in behavioral deficits in rats. OX was administered once per week for seven weeks (cumulative dose i.p. 70mg/kg) to adult female Wistar rats. Throughout and for three weeks following treatment, behavioral analysis was performed daily on OX and sham control rats. Compared to controls, OX rats demonstrated errors in placing their hind feet securely and/or correctly during a horizontal ladder rung task. These behavioral deficits occurred together with modification of proprioceptor signaling that eliminated sensory encoding of static muscle position while having little effect on encoding of dynamic changes in muscle length. Selective inability to sustain repetitive firing in response to static muscle stretch led us to hypothesize that OX treatment impairs specific ionic currents, possibly the persistent inward Na currents (NaPIC) that are known to support repetitive firing during static stimulation in several neuron types, including the class of large diameter dorsal root ganglion cells that includes muscle proprioceptors. We tested this hypothesis by determining whether the chronic effects of OX on the firing behavior of muscle proprioceptors in vivo were mimicked by acute injection of NaPIC antagonists. Both riluzole and phenytoin, each having multiple drug actions but having only antagonist action on NaPIC in common, reproduced selective modification of proprioceptor signaling observed in OX rats. Taken together, these findings lead us to propose that OX chemotherapy contributes to movement disability by modifying sensory encoding, possibly via a chronic neurotoxic effect on NaPIC in the sensory terminals of muscle proprioceptors.

Palisade endings and proprioception in extraocular muscles: a comparison with skeletal muscles

This article describes current views on motor and sensory control of extraocular muscles (EOMs) based on anatomical data. The special morphology of EOMs, including their motor innervation, is described in comparison to classical skeletal limb and trunk muscles. The presence of proprioceptive organs is reviewed with emphasis on the palisade endings (PEs), which are unique to EOMs, but the function of which is still debated. In consideration of the current new anatomical data about the location of cell bodies of PEs, a hypothesis on the function of PEs in EOMs and the multiply innervated muscle fibres they are attached to is put forward.

Mathematical models of proprioceptors. II. Structure and function of the Golgi tendon organ

We developed a physiologically realistic mathematical model of the Golgi tendon organ (GTO) whose elements correspond to anatomical features of the biological receptor. The mechanical interactions of these elements enable it to capture all salient aspects of GTO afferent behavior reported in the literature. The model accurately describes the GTO's static and dynamic responses to activation of single motor units whose muscle fibers insert into the GTO, including the different static and dynamic sensitivities that exist for different types of muscle fibers (S, FR, and FF). Furthermore, it captures the phenomena of self- and cross-adaptation wherein the GTO dynamic response during motor unit activation is reduced by prior activation of the same or a different motor unit, respectively. The model demonstrates various degrees of nonlinear summation of GTO responses resulting from simultaneous activation of multiple motor units. Similarly to the biological GTO, the model suggests that the activation of every additional motor unit to already active motor units that influence the receptor will have a progressively weaker incremental effect on the GTO afferent activity. Finally, the proportional relationship between the cross-adaptation and summation recorded for various pairs of motor units was captured by the model, but only by incorporating a particular type of occlusion between multiple transduction regions that were previously suggested. This occlusion mechanism is consistent with the anatomy of the afferent innervation and its arrangement with respect to the collagen strands inserting into the GTO.

Extraocular muscle proprioceptors and proprioception

Uncertainty of the roles of proprioception and efference copy in visual spatial perception persists. Proprioception has won back some support recently mainly on the evidence gained from physiological experiments in man, and rather than being mutually exclusive, the two mechanisms have been presented as collaborating. Another view supported by human and animal experiments states that current visual spatial perception may be served by efference copy whereas proprioception is responsible for temporal adaptations of the system. Certain characteristics of visuomotor cells of the monkey cortex can be explained assuming an efference copy input. Anatomical data from different sources are not easily reconciled. Disagreement about the nerve pathway of muscle afferents weakens arguments based on the results of open loop experiments involving nerve lesions in monkeys. The assumed presence of Golgi tendon organs in human extraocular muscles is no longer tenable and instead, palisade endings similar to those of cats and monkeys and other, irregular nerve endings are described. But man differs in having a limited and patchy distribution of neurotendonous endings and moreover, they may develop only after infancy. The allocation of a sensory function to palisade endings in myotendinous cylinders appears secure, at least in cats. Detailed examination of muscle spindles in man reveals anomalies of structure sufficient to question their capacity to provide useful proprioceptive information. One of the anomalies is the atrophy of intrafusal muscle fibres, present in both infant and adult muscles, and it is proposed that the redundant sensory endings, which do not appear to degenerate, search for new targets and may account for the random presence of tendon nerve endings. These observations place the role of proprioception in human extraocular muscles in jeopardy; they are unsupportive of the recent physiological studies and favour efference copy.

Neurocalcin-immunopositive nerve terminals in the muscle spindle, Golgi tendon organ and motor endplate

The present study revealed the immunohistochemical distribution of neurocalcin, a three EF-hand calcium-binding protein, in the rat muscles and tendons. In the muscle spindles, annulospiral endings, which made spirals around the intrafusal muscles, showed intense neurocalcin-immunoreactivity. In the Golgi tendon organs, immunopositive thick nerve fibers entered the collagenous fibers resulting in the projection of many swelling terminals. In all examined muscles, nerve terminals in the motor endplates showed neurocalcin-immunoreactivity associated with the membranes of synaptic vesicles and mitochondria. These findings suggest that neurocalcin is distributed and regulates calcium signaling in both afferent and efferent nerve terminals in the muscles and tendons.

Encapsulated Ruffini-like endings in human lumbar facet joints

The innervation of the human lumbar facet joint capsule was studied by light and electron microscopy. Small numbers of encapsulated corpuscular endings were identified in the dense fibrous layer. Clusters of 2 types of endings were found: small cylindrical corpuscles (type 1) and large fusiform corpuscles (type 2). The corpuscles were classified structurally as Ruffini-type endings. The 1st type was predominant and characterised by a compartmentalised receptor complex, a thin perineurial capsule and a narrow subcapsular space. The 2nd type was characterised by a thicker perineurial capsule, a 'spindle-like' receptive complex, and an extensive subcapsular space with capillaries and concentrically oriented fibroblast-like cells. Both types of endings were innervated mainly by thinly myelinated group III (A delta) and unmyelinated group IV (C) nerve fibres that branched and terminated in the receptor complex. Their sensory endings were intimately related to the collagen fibre bundles as multiple enlarged axonal segments ('beads') with ultrastructural features which were characteristic of receptive sites: an accumulation of mitochondria and vesicles, and 'bare' areas of axolemma lacking a Schwann cell investment but covered by a thin basal lamina. Some beads in the 2nd type of ending contained granular vesicles, 30-60 mm in diameter, resembling sympathetic nerve endings. Small diameter collagen fibrils situated within multilayered basal laminae were found among the multiple receptive sites in the receptive complex in both types of ending. Their possible functional significance in mechanoreception is discussed. Particular attention has been given to their apparent variable orientation to the mechanoreceptive site.

A novel stretch receptor in the jaw of the rat

We report here an unusual type of stretch receptor found on each side of the rat jaw. This receptor has unique morphological features: it is quite long (24-28 mm), lies in connective tissue in between masticatory muscles, and extends between the medial pterygoid muscle-tendon on the maxilla and the masseter-tendon on the mandible through a zigzag course, forming a Greek capital letter sigma when viewed from the side. The receptor is neither in parallel nor in series with any masticatory muscles and receives multiple innervation. The receptor increases its length when the jaw closes and shortens when the jaw opens. Electron microscopy revealed axial structures composed of a central cellular core surrounded by tightly packed collagen bundles which are separated from the capsule by a wide capsular space. Most of the sensory endings are found among axial collagen bundles, some in between core cells. The core cells have many finger-like processes on their surface, being coupled by desmosomes. The origin and nature of these cells are unclear. The wide capsular space is filled with Alcian blue positive substrate, probably acid glycosaminoglycans. The structures of outer and inner capsules are similar to those of muscle spindles, the former being composed of three to ten layers of thin flattened cells. The response of the receptor was examined with in vivo as well as in vitro preparations. In in vivo experiments, impulse discharges from this receptor increased with the increase in jaw closing. When the jaw was fully opened the impulse discharge from this receptor disappeared.(ABSTRACT TRUNCATED AT 250 WORDS)

Central connections of trigeminal primary afferent neurons: topographical and functional considerations

This article reviews literature relating to the central projection of primary afferent neurons of the trigeminal nerve. After a brief description of the major nuclei associated with the trigeminal nerve, the presentation reviews several early issues related to theories of trigeminal organization including modality and somatotopic representation. Recent studies directed toward further definition of central projection patterns of single nerve branches or nerves supplying specific oral and facial tissues are considered together with data from intraaxonal and intracellular studies that define the projection patterns of single fibers. A presentation of recent immunocytochemical data related to primary afferent fibers is described. Finally, several insights that recent studies shed on early theories of trigeminal input are assessed.