Mechanical functioning of peripheral nerves: linkage with the “mushrooming” effect

Biomechanical properties of nerve have been studied extensively. All neural matrix tissues have been suggested to be the main load-bearing component. Based on the ultrastructure it has been proposed that the architecture of the epineurium allows some degree of extensibility of the nerve. A role of the perineurium could be to withstand the positive endoneurial pressure. The hypothesis is that the mechanical behaviour of nerves is dependent on an interaction between the core swelling pressure and restraint by the outer sheath. Loss of this balance will alter that behaviour. To test this, rat sciatic nerves were subjected to mechanical loading at in vivo and ex vivo tension. Retraction of nerve segments was measured after excision and after incubation at 37°C or freezing. Swelling properties of the nerve were measured by immersion in water or PBS (phosphate buffer solution) with intact or opened epineurium. Results showed a significant decrease in strength and stiffness with an increase in strain of the nerve after excision, compared to in vivo. Retraction was on average 11%. Freezing or incubation at 37°C did not alter retraction. The swelling properties of the nerve demonstrated a significant difference between intact and opened epineurium and similar results for water and PBS, indicating that epineurium is a constraint and that the nerves are underhydrated. The proposed model for the intact nerve is a continuous connective tissue tube surrounding and constraining an inner swelling pressure of the neural core. Loss of integrity of the nerve has detrimental effects on its biomechanical properties.Preliminary forms of this project were presented at the 1st UK Tissue & Cell Engineering Society meeting, Hammersmith Hospital, RPMS, London, 5 July 1999, and at the 7th FESSH, Barcelona, Spain, 22 June 2000. Support was partly given by EU grant QLK3-CT-1999-00625: NEURO-TEC     

Distribution of myelinated nerves in ascending nerves and myenteric plexus of cat colon

The parts of the colon differ in motor function and in responses to extrinsic and intrinsic nerve stimulation. The distribution of myelinated nerve fibers in the colonic myenteric plexus is not known. Because these fibers might be largely extrinsic in origin, their distribution might indicate the domain of influence of extrinsic nerves and help to explain the different behaviors of the different parts of the colon. Myelinated fibers were examined by electron microscopy in cross sections of the ascending nerves and in myelin-stained whole-mount preparations in the colon. The ascending nerves are much like one another. They have the structure of peripheral nerves, not that of myenteric plexus. The proportion of myelinated fibers in the ascending nerves declines rostrad with no uniform change in total nerve fiber number. Cross-sectional areas of ascending nerves, 3,304 to 7,448 microns 2; total number of nerve fibers per profile, 703-2,651; and mean myelin coat thickness, 0.45 +/- 0.01 micron, do not change uniformly along the ascending nerves. Myelinated fibers are about 2% of total fibers in the extramural colonic nerves, 7-9% in the ascending nerves in the sigmoid colon, and 2-3% at the rostrad ends of the ascending nerves in the transverse colon. Blood vessels lie at the core of each ascending nerve and on the nerve sheath. Myelinated fibers in the ascending nerves degenerate after section of colonic branches of the pelvic plexus and after section of the pudendal nerves, indicating that myelinated nerves reach the colon through both pathways.(ABSTRACT TRUNCATED AT 250 WORDS)     

Electron microscopy of severed motor fibers in the crayfish

Summary Cut and crushed crayfish claw nerves were examined with the electron microscope at intervals up to 6 months after lesion. In sections 1 centimeter distal to the lesion there were no signs of degeneration among the giant motor axons even after many months. Swelling of glial wrappings was observed within 48 hours of nerve severance and was particularly notable in the innermost glial layer, the adaxonal layer. Golgi elements, rough endoplasmic reticulum, and mitochondria accumulated in the glia. These changes were perhaps indicative of a greater supportive role required by the severed axons. Regeneration from the proximal stumps of the giant axons began within one week and had proceeded across the lesion gap by 4 weeks. Axon sprouts appeared to travel toward the terminals within the glial sheaths of the distal giant axon segments. Before regeneration was complete, as determined by a simple behaviour test, the regenerating axons occupied increasing proportions of the sheath space. After regeneration was complete occasional degenerations were seen among the sprouts. These degenerations may have occurred in regenerating axons which had grown to the incorrect muscles. The original distal giant axons probably degenerated, as well, after regeneration was complete. There was no evidence of rehealing of proximal and distal segments of the axons.This work was supported by NIH postdoctoral fellowship number 1F2 NB 32, 723 N RB awarded to RHN and grants in aid from the Multiple Sclerosis Society, The American Cancer Society and The National Institutes of Health.     

Neuronal and non-neuronal responses to nerve crush in a pulmonate snail,Melampus bidentatus

Immunohistochemical and ultrastructural techniques were used to study sequelae of nerve injury in the pulmonate snail Melampus bidentatus. Either pedal or tentacle nerves were crushed, severing all axons, and recovery was monitored over 15 days. The axons regenerated from the segment attached to the soma, with no evidence of fusion of proximal and distal segments. The medium to large axons of central neurons, including those monitored with serotonin immunohistochemistry, grow distally across the path of smaller axons extending centrally from peripheral somata. The regions into which the growing axons projected were a focus of phagocytic activity. Cells previously labeled by PKH-26PCL, a fluorescent marker for phagocytic activity, were attracted to the crushed nerve within 6 h and were a consistent feature in the vicinity of the injury for at least 9 days, gradually extending their range as repair progressed in both directions from the crush. Repair proceeded within an intact sheath, and many sheath cells survived the crush, although the nuclear dye Hoechst 33258 revealed an initial distortion of their nuclei. The concentration of cells in the sheath in the crushed region increases after the crush, with the packing of nuclei peaking at 3 days and gradually returning to control conditions; this probably reflects migration of resident sheath cells. Cell division is rare in the sheath of intact nerves, but labeling with bromodeoxyuridine increases at the crush site between 4 and 9 days, indicating that cell replacement also occurs at the site. Electronic Publication     

Mechanical role of the leaf sheath in rattans

Leaf sheaths of rattans are long, tubular and persistent and unlike many self-supporting palms, extend far from the apex of the plant. The mechanical role of the leaf sheath was investigated in eight rattan species of the subfamily Calamoideae. The main objective was to analyse its influence on the mechanical architecture and contribution to the climbing habit. Bending mechanical properties were measured along climbing axes before and after removal of leaf sheaths. Results were related to stem and leaf sheath geometry and mechanical properties. Contribution of the leaf sheath to axial flexural rigidity was high (c. 90%) in the early stages of growth and towards the apex of older climbing axes for all climbing palms tested. Senescence and loss of the leaf sheath strongly influenced axial stiffness. A nonclimbing species, Calamus erectus, showed a different mechanical architecture. Although lacking secondary growth, palms have been able to develop successful climbers with a mechanical architecture broadly analogous to, although developmentally different from, dicotyledonous lianas. The role of the leaf sheath in modulating mechanical properties during ontogeny ought not to be neglected in studies on monocotyledons, as it possibly contributed significantly to the ways in which different growth forms have evolved in the group.     

Evidence of a discrete axial structure in unimodal collagen fibrils

The collagen fibrils of cornea, blood vessel walls, skin, gut, interstitial tissues, the sheath of tendons and nerves, and other connective tissues are known to be made of helically wound subfibrils winding at a constant angle to the fibril axis. A critical aspect of this model is that it requires the axial microfibrils to warp in an implausible way. This architecture lends itself quite naturally to an epitaxial layout where collagen microfibrils envelop a central core of a different nature. Here we demonstrate an axial domain in collagen fibrils from rabbit nerve sheath and tendon sheath by means of transmission electron microscopy after a histochemical reaction designed to evidence all polysaccharides and by tapping-mode atomic force microscopy. This axial domain was consistently found in fibrils with helical microfibrils but was not observed in tendon, whose microfibrils run longitudinal and parallel.     

A series of desmosomal attachments in the schwann sheath of myelinated mammalian nerves

Summary This paper reports the occurrence of a band of desmosome-like complexes between schwannian loops near the nodes of Ranvier in the myelin sheath of the sciatic nerves of rats. The complexes are characterized by focal widening of the space between adjacent loops and a conspicuous density of the subjacent cytoplasm. These complexes are arranged back-to-back in a row thereby forming a band-like structure. In serial and step-section reconstructions it appears that one such band is present on either side of each nodal gap. Although the function of these complexes is unknown, it is suggested that they may serve to bond together adjacent loops of the Schwann sheath near the point where the myelin sheath is interrupted at the node of Ranvier.This investigation was supported in part by United States Public Health Service Research Grant NB 04330-01, -02 and research career program award NB-K3-16,731 from the National Institute of Neurological Diseases and Blindness and by Grant No. 358 from the National Multiple Sclerosis Society.Presented in part at the 3rd Annual Meeting of the American Society for Cell Biology, New York City, 1963 (Harkin 1963a).     

Indentation and adhesive probing of a cell membrane with AFM: theoretical model and experiments

In probing adhesion and cell mechanics by atomic force microscopy (AFM), the mechanical properties of the membrane have an important if neglected role. Here we theoretically model the contact of an AFM tip with a cell membrane, where direct motivation and data are derived from a prototypical ligand-receptor adhesion experiment. An AFM tip is functionalized with a prototypical ligand, SIRPalpha, and then used to probe its native receptor on red cells, CD47. The interactions prove specific and typical in force, and also show in detachment, a sawtooth-shaped disruption process that can extend over hundreds of nm. The theoretical model here that accounts for both membrane indentation as well as membrane extension in tip retraction incorporates membrane tension and elasticity as well as AFM tip geometry and stochastic disruption. Importantly, indentation depth proves initially proportional to membrane tension and does not follow the standard Hertz model. Computations of detachment confirm nonperiodic disruption with membrane extensions of hundreds of nm set by membrane tension. Membrane mechanical properties thus clearly influence AFM probing of cells, including single molecule adhesion experiments.     

Uptake of Vinca Alkaloids into Mammalian Nerve and its Subcellular Components

Three Vinca alkaloids, vinblastine (VLB), vincristine (VCR), and vindesine (VDS), were recently found to affect axoplasmic transport to different degrees, with VCR the most potent. The uptake of these three species by desheathed cat sciatic nerves in vitro was determined by using tritium-labeled derivatives. In a sucrose medium, the uptake of VCR was found to be three to four times greater than that of VLB and VDS, which is in accord with the neurotoxicity of VCR. Uptake of VCR was dependent on Ca2+ concentration in the medium. Removal of Ca2+ from the incubation medium reduced the uptake of VCR, without having much effect on VLB or VDS uptake. The uptake of all three Vinca agents into nerve in a saline medium was about 50% of that in a sucrose medium, and elimination of Ca2+ from the saline incubation medium did not result in any significant change in uptake. High Ca2+ concentrations (100 mM) in the incubation medium, which cause a block of axoplasmic transport, did not change the total uptake of the Vinca alkaloids to any significant degree. The amount of labeled alkaloid found in the soluble fraction was, however, decreased by 50%. There was an increase in the amount present in the particulate fraction, caused, most likely, by an aggregation of vinca-binding components. The amount of VCR associated with tubulin-containing components isolated by gel filtration of the soluble fraction increased twofold when the nerves were exposed to a high-Ca2+ medium, as might be expected of a microtubule disassembly. Exposure of the nerve to low temperatures (0 degrees-4 degrees C) for 90 min did not show any effect on the total uptake of Vinca alkaloids.     

Composition of the medial and posterior articular nerves of the mouse knee joint

The number and the distribution of fiber size in the medial (MAN) and posterior (PAN) articular nerves of the mouse knee joint were studied by electron microscopy. The MAN contained 75 &#45 28 nerve fibers consisting of 63 &#45 24 unmyelinated and 12 &#45 6 myelinated fibers. The PAN was composed of 195 &#45 50 nerve fibers, namely 129 &#45 28 unmyelinated and 66 &#45 24 myelinated fibers. A skewed unimodal distribution of the unmyelinated nerve fiber diameters was seen in both nerves ranging from 0.1 to 1.2 &#119 m with a maximum between 0.3 and 0.6 &#119 m. The myelinated nerve fibers in the MAN ranged from 1 to 8 &#119 m with a peak between 2 and 5 &#119 m. In the PAN, their diameters ranged from 1 to 12 &#119 m with a clearly visible peak at 4-5 &#119 m and a plateau at 8-9 &#119 m that may represent a second maximum. These data show that the knee joint innervation of the mouse is comparable to those of the cat and rat concerning the types of nerve fibers and the composition of the two nerves. However, in relation to the much smaller area of tissue to be innervated the total number of primary afferents is considerable smaller in the mouse.     

Evidence for aerobic ATP synthesis in isolated myelin vesicles

Even though brain represents only 2–3% of the body weight, it consumes 20% of total body oxygen, and 25% of total body glucose. This sounds surprising, in that mitochondrial density in brain is low, while mitochondria are thought to be the sole site of aerobic energy supply. These data would suggest that structures other than mitochondria are involved in aerobic ATP production. Considering that a sustained aerobic metabolism needs a great surface extension and that the oxygen solubility is higher in neutral lipids, we have focused our attention on myelin sheath, the multilayered membrane produced by oligodendrocytes, hypothesizing it to be an ATP production site. Myelin has long been supposed to augment the speed of conduction, however, there is growing evidence that it exerts an as yet unexplained neuro-trophic role. In this work, by biochemical assays, Western Blot analysis, confocal laser microscopy, we present evidence that isolated myelin vesicles (IMV) are able to consume O₂ and produce ATP through the operation of a proton gradient across their membranes. Living optic nerve sections were exposed to MitoTracker, a classical mitochondrial dye, by a technique that we have developed and it was found that structures closely resembling nerve axons were stained. By immunohystochemistry we show that ATP synthase and myelin basic protein colocalize on both IMV and optic nerves. The complex of data suggests that myelin sheath may be the site of oxygen absorption and aerobic metabolism for the axons.     

Contribution of actin filaments and microtubules to quasi-in situ tensile properties and internal force balance of cultured smooth muscle cells on a substrate

The effects of actin filaments (AFs) and microtubules (MTs) on quasi-in situ tensile properties and intracellular force balance were studied in cultured rat aortic smooth muscle cells (SMCs). A SMC cultured on substrates was held using a pair of micropipettes, gradually detached from the substrate while maintaining in situ cell shape and cytoskeletal integrity, and then stretched up to approximately 15% and unloaded three times at the rate of 1 mum every 5 s. Cell stiffness was approximately 20 nN per percent strain in the untreated case and decreased by approximately 65% and approximately 30% following AF and MT disruption, respectively. MT augmentation did not affect cell stiffness significantly. The roles of AFs and MTs in resisting cell stretching and shortening were assessed using the area retraction of the cell upon noninvasive detachment from thermoresponsive gelatin-coated dishes. The retraction was approximately 40% in untreated cells, while in AF-disrupted cells it was <20%. The retraction increased by approximately 50% and decreased by approximately 30% following MT disruption and augmentation, respectively, suggesting that MTs resist intercellular tension generated by AFs. Three-dimensional measurements of cell morphology using confocal microscopy revealed that the cell volume remained unchanged following drug treatment. A concomitant increase in cell height and decrease in cell area was observed following AF disruption and MT augmentation. In contrast, MT disruption significantly reduced the cell height. These results indicate that both AFs and MTs play crucial roles in maintaining whole cell mechanical properties of SMCs, and that while AFs act as an internal tension generator, MTs act as a tension reducer, and these contribute to intracellular force balance three dimensionally.     

Mechanics of anesthetic needle penetration into human sciatic nerve

Nerve blocks are frequently performed by anesthesiologists to control pain. For sciatic nerve blocks, the optimal placement of the needle tip between its paraneural sheath and epineurial covering is challenging, even under ultrasound guidance, and frequently results in nerve puncture. We performed needle penetration tests on cadaveric isolated paraneural sheath (IPS), isolated nerve (IN), and the nerve with overlying paraneural sheath (NPS), and quantified puncture force requirement and fracture toughness of these specimens to assess their role in determining the clinical risk of nerve puncture. We found that puncture force (123 ± 17 mN) and fracture toughness (45.48 ± 9.72 J m⁻²) of IPS was significantly lower than those for NPS (1440 ± 161 mN and 1317.46 ± 212.45 Jm⁻², respectively), suggesting that it is not possible to push the tip of the block needle through the paraneural sheath only, without pushing it into the nerve directly, when the sheath is lying directly over the nerve. Results of this study provide a physical basis for tangential placement of the needle as the ideal situation for local anesthetic deposition, as it allows for the penetration of the sheath along the edge of the nerve without entering the epineurium.     

Knockout of p75(NTR) impairs re-myelination of injured sciatic nerve in mice

Remyelination is an important aspect of nerve regeneration after nerve injury but the underlying mechanisms are not fully understood. The neurotrophin receptor, p75(NTR), in activated Schwann cells in the Wallerian degenerated nerve is up-regulated and may play a role in the remyelination of regenerating peripheral nerves. In the present study, the role of p75(NTR) in remyelination of the sciatic nerve was investigated in p75(NTR) mutant mice. Histological results showed that the number of myelinated axons and thickness of myelin sheath in the injured sciatic nerves were reduced in mutant mice compared with wild-type mice. The myelin sheath of axons in the intact sciatic nerve of adult mutant mice is also thinner than that of wild-type mice. Real-time RT-PCR showed that mRNA levels for myelin basic protein and P0 in the injured sciatic nerves were significantly reduced in p75(NTR) mutant animals. Western blots also showed a significant reduction of P0 protein in the injured sciatic nerves of mutant animals. These results suggest that p75(NTR) is important for the myelinogenesis during the regeneration of peripheral nerves after injury.     

Morphometric comparison between human and rat abducens and oculomotor nerves

A morphologic and morphometric comparison between normal human and rat extraocular muscle nerves was performed using a computer-assisted method to obtain scatter diagrams of relative sheath thickness (g ratio = quotient axon diameter/fiber diameter). Human and rat extraocular muscle nerves (nervus abducens and ramus medialis n. oculomotorii) were excised immediately before the nerve branching at the entering point into the muscle. There was no difference in the absolute number of myelinated fibers between the oculomotor and abducens nerves in both species. The distribution of myelinated fibers was classified according to their g ratios into a two-stage density cluster analysis. Two main populations of nerve fibers for human oculomotor and rat oculomotor and abducens nerves and three main populations for human abducens nerve were differentiated morphometrically and mathematically, differing in their relative sheath thicknesses. There are distinct differences between scatter diagrams of human and rat extraocular muscle nerves, in correlation with the basically different oculomotor functions of these two species. The morphometric differences between human and rat extraocular muscle nerves suggest a difference in the myelination process and the presence of functionally different nerve fibers, strongly indicated by the populations and subpopulations of myelinating nerve fibers peculiar to extraocular muscle. The existence of more than two different types of myelinated fibers in the human nerves implies that the traditional classification based on fiber caliber must be reviewed and a comparison of different classes of nerve and muscle fibers should be performed.     

Receptive properties of primary afferent fibres from rabbit pleura,in vitro

Abstract We investigated the physiological properties of mediastinal pleural primary afferent units by recording single nerve fibre activity from the phrenic nerve in an in vitro preparation of rabbit tissue. A total of 41 units with conduction velocities in the group III and IV range were examined for their responsiveness to mechanical, thermal and chemical stimuli. Most receptive fields were adjacent to the phrenic nerve-pericardiacophrenic artery complex. The thresholds to punctate mechanical stimulation (von Frey hairs) were widely scattered around a median of 5.4 mN; all fibres showed slowly adapting responses to mechanical stimulation. Heat sensitivity was observed in 7/41 units (17%), while 17/41 (41%) of the fibres exhibited a spurious transient excitation to strong and rapid cooling. Chemosensitivity was scarce with respect to capsaicin (7/33 (21%) of the units responding) but more common to CO2-saturated synthetic interstitial fluid (pH 6.1, 5/16 (31%) responding). The most effective stimulus was a mixture of bradykinin, serotonin, histamine and prostaglandin E2 ('inflammmatory soup') which evoked stimulus responses in 27/33 (82%) of the afferent fibres challenged. Sensitization to mechanical stimuli occurred in 5/41 (12%) of the units, following the application of heat or inflammatory mediators. The rabbit pleura appears as a tissue mainly innervated by multimodal mechano- and chemosensitive afferent units.     

Persistence of Immunoreactive Neurofilament Protein Breakdown Products in Transected Rat Sciatic Nerve

Abstract: Alterations occurring in nerve proteins of transected nerves were studied in rat sciatic nerves using polyclonal and monoclonal antibodies to identify and monitor neurofilament (NF) epitopes among nerve proteins following their electrophoresis and transfer to nitrocellulose paper. Immunoblot methods identified NF epitopes in NF triplet proteins (M_r 200,000, 150,000, and 68,000) and in NF nontriplet proteins (all other immunobands below M_r 200,000 and above M_r 40,000). NF triplet and nontriplet proteins were Triton-insoluble in both untransected and transected nerves. Extensive loss of NF triplet and most nontriplet proteins occurred during the 24-48-h period following nerve transection and was attributed to proteolytic degradation. Loss of protease-labile NF proteins led to a markedly reduced level of NF immunoreactivity in 2-day transected nerve. NF proteins which survived the 2-day posttransectional period were considered to represent protease-stable NF fragments. These fragments persisted in transected nerve for periods of at least 35 days. Most protease-stable NF fragments which retained immunoreactivity had M_r of 57,000-65,000. Low concentrations of the same immunobands were present in untransected nerves.     

乳液法神经生长因子（NGF）电纺纤维的体外研究

目的：使用乳液法制备含有神经生长因子（NGF）的电纺纤维,研究其外观形貌和机械强度等物理性能,以及制备过程中NGF活性的变化,纤维中NGF的担载量和纤维体外释放动力学,评价其能否成为理想的神经修复材料,为进一步将NGF电纺纤维应用于周围神经修复奠定基础。方法：将NGF水溶液分散于PLLA溶液,通过W／O乳液法制备静电纺丝缓释纤维,对纤维的外观形貌等物理性能等进行表征,使用Elisa方法测定制备过程中NGF活性的保持以及体外释放动力学。结果：NGF电纺纤维具备类似细胞外基质（ECM）的良好外观形貌和一定的机械强度,其中NGF活性保持19．58％士6．05％,体外有效释放11天。结论：本文制备的乳液法NGF电纺纤维具备良好的物理性能,能够持续缓释有效剂量的NGF,适合作为神经修复材料进行进一步研究。     

Effect of oculomotor and trigeminal nerve section on the ultrastructure of different myoneural junctions in the rat extraocular muscles

Summary The intramuscular nerves and myoneural junctions in the rat rectus superior, medialis and inferior muscles from 10 hours to about 10 days after section of the trigeminal and oculomotor nerves were studied with the electron microscope. Two different kinds of myoneural junctions are to be observed; one type derives from myelinated nerves and is similar to the ordinary myoneural junctions (motor end plates) of other striated skeletal muscles, while the other type derives from unmyelinated nerves, is smaller in size and has many myoneural synapses distributed along a single extrafusal muscle fibre.Section of the trigeminal nerve caused no changes in the myoneural synapses. After section of the oculomotor nerve degenerative changes occur in both the myelinated and unmyelinated nerves and in both types of myoneural junctions. In the axon terminals of both the myelinated and unmyelinated nerves the earliest changes are to be observed 10 to 15 hours after section of the nerve. First, swelling of the axoplasm, fragmentation of microtubules and microfilaments and swelling of mitochondria takes place, somewhat later agglutination of the axonal vesicles and mitochondria. The axon terminals are separated from the postsynaptic muscle membrane by hypertrophied teloglial cells about 24 hours after section of the nerve. The debris of the axon terminals is usually digested by the teloglial cells within 42 to 48 hours in both types of myoneural junction.Changes in the postsynaptic membrane are observed in the myoneural junctions of the unmyelinated nerves as disappearance of the already earlier irregular infoldings, whereas no changes take place in the infoldings of the motor end plates. The postsynaptic sarcoplasm and its ribosomal content increase somewhat.The earliest changes occur along unmyelinated axons 10 to 15 hours and along myelinated axons 15 to 24 hours after nerve section. The unmyelinated axons are usually totally digested within 48 hours, whereas the myelinated axons took between 48 hours and 4 days to disappear. The degeneration, fragmentation and digestion of the myelin sheath begin between 24 and 42 hours and still continues 10 days after the operation.The results demonstrate that in the three muscles studied structures underlying the physiologically well known double innervation of the extraoccular muscles are all part of the oculomotor system.We are grateful to Professor Antti Telkkä, M. D. Head of the Electron Microscope Laboratory, University of Helsinki, for permission to use the facilities of the laboratory.     

The fine structure of the nerve cord of Myxicola infundibulum (annelida,polychaeta)

Summary Ultrastructural observations of the giant axon of Myxicola infundibulum reveal that the axoplasm contains neurofilaments, a few neurotubules and mitochondria. Finger-like projections issuing from the glial cells of the sheath encircle the giant axon at various angles. The space between the axolemma and sheath is 125 Å. Branches of the giant axon are also surrounded by a glial sheath as they course through the neuropil. Some branches of the giant axon seem to fuse with certain neurons, creating a syncytial arrangement between the giant axon and these neurons.Many small nerve fibers course longitudinally in the neuropil of the nerve cord. Most of these axons are separated from each other by a space of 200 Å without intervening glial processes. Synapses in the neuropil have both clear 600 Å vesicles and larger dense core vesicles suggesting chemical transmission. Some, but not all, of the synaptic areas show thickened membranes and dense material in the synaptic cleft.This study was supported in part by PHS NS-07740 to R.L.P., J.A.B. is a NDEA Predoctoral Fellow in the Department of Physiology.