A two-compartment modification of the silicone chamber model for nerve regeneration

In the nerve regeneration silicone chamber model, the regenerate which forms across a 10-mm gap between proximal and distal nerve stumps is a monofascicular structure with an outer perineurial-like cell sheath. Recent work has provided indications that the geometry of the regenerate within a silicone chamber can be altered by experimental modifications of the chamber matrix. In the present study we modified the standard silicone chamber into a two-compartment chamber by inserting a 6- or 10-mm-long siliconized nitrocellulose strip in order to obtain two separate regenerates. Light microscopy 16 days after implantation revealed that two separate nerve structures had formed, one on each side of the nitrocellulose partition and adjacent to it, and each with its own perineurial-like cell sheath. In chambers with 6-mm-long strips a monofascicular regenerate started from the proximal stump and divided into two separate structures as it approached the proximal end of the strip: the two fascicles joined again into a monofascicular structure in the distal portion of the chambers. The new two-compartment silicone chamber model appears suitable for future examinations of experimental fasciculation. In addition, the nitrocellulose partition should allow one to study specific effects of growth factors on axonal regeneration in vivo, as growth factors bind strongly to untreated nitrocellulose while retaining their biological activity.     

Regeneration of the rat sciatic nerve in the silicone chamber model

The silicone nerve regeneration chamber is a useful model to investigate the cellular and molecular events underlying successful regeneration in the peripheral nervous system. In this model a transected rat sciatic nerve with a 10-mm interstump gap, is repaired with a silicone chamber. The spatial-temporal sequence of regeneration in the silicone chamber has been examined in detail. The chamber rapidly becomes filled with fluid which contains neurotrophic activity for neurons in vitro. The second event to occur is the formation of a fibrin matrix connecting the two nerve stumps. This matrix is then invaded by cellular elements in the following order: perineurial-like cells, vasculature, Schwann cells, and axons. The silicone chamber model also allows manipulation of the regeneration process. Prefilling the chamber at the time of implantation with phosphate-buffered saline or dialyzed plasma stimulates nerve regeneration. Multiple injections into the chamber of a mixture containing laminin, testosterone, and ganglioside GM1 increase the size and the vascularization of the regenerate. Specially designed chambers divided into two compartments by a longitudinally inserted nitrocellulose strip have been used to examine the effects of substrate-bound trophic factors on nerve regeneration. Fibroblast growth factor containing chambers have an improved regeneration and vascularization as compared to controls.     

Early profiles of axonal growth and astroglial response after spinal cord hemisection and implantation of Schwann cell-seeded guidance channels in adult rats

We previously demonstrated that transplantation of Schwann cell-seeded channels promoted the regrowth of injured axons in the adult spinal cord. It is not clear, however, whether injured axons recapitulate the developmental scenarios to accomplish regeneration. In the present study, we investigated the early events associated with axonal regrowth after spinal cord hemisection at the eighth thoracic level and implantation of a Schwann cell-seeded minichannel in adult rats. Animals were sacrificed at postoperative days (PO) 2, 4, 7, and 14. Anterograde tracing with fluoro-ruby showed that regenerating axons grew into the graft prior to PO2 and reached the distal end of the channel at PO7. These axons expressed both embryonic neural cell adhesion molecule (E-NCAM) and growth associated protein-43 (GAP-43). Although the expression of E-NCAM decreased by PO7, that of GAP-43 remained high throughout the first 2 weeks after implantation. A close relation of vimentin-positive astroglia to the growing axons in the host tissue suggested a contact-mediated role of these cells in axon guidance. Aggregation of glial fibrillary acidic protein (GFAP)-positive astrocytes together with the increased expression of chondroitin sulfate proteoglycans (CSPGs) starting at PO7 appeared to inhibit axonal growth at the host-graft interface. Thus, adult regenerating axons and astroglia do express developmentally related molecules that may facilitate axonal growth into a permissive graft at the early phase of injury and regeneration. These results suggest that molecules and astroglia essential to development are both important in influencing axonal regrowth in the adult spinal cord.     

Peripheral nerve regeneration through silicone chambers in streptozocin-induced diabetic rats

The silicone chamber model was used to evaluate peripheral nerve regeneration (PNR) in streptozocin (STZ)-induced diabetic rats. Diabetic and control animals underwent sciatic nerve transection and silicone chamber implantation establishing gaps of various lengths between the transected nerve ends. In animals with 5 and 10 mm gaps, diabetes was induced in experimental rats 1 week before surgery, and the animals were sacrificed 3 weeks after surgery. In animals with 8 mm gaps, diabetes induction occurred 3 days after surgery, and they were sacrificed after 7 weeks. Diabetic rats with 10 mm gaps demonstrated an impaired ability to form bridging cables, the initial step of regeneration through chambers. Morphometric studies of bridging cables between transected nerve ends demonstrated a significant reduction in the mean endoneurial area in diabetic animals with 5 and 8 mm gaps compared to controls. The number of regenerated myelinated axons in the chamber was significantly decreased in diabetic rats with 8 and 10 mm gaps. The mean myelinated fiber area in the regenerated cables of the diabetic group was significantly decreased with 5 mm gaps and significantly increased with 8 mm gaps compared to controls. Size-frequency histograms of regenerated myelinated fiber areas suggest a delay in the maturation of small caliber axons. Schwann cell migration across 5 mm gaps was examined with S-100 immunohistochemistry. The total distance of Schwann cell migration into cables from both proximal and distal ends was significantly reduced in diabetic animals. Characterization of PNR across gaps through silicone chambers in diabetic rats showed impairment in multiple aspects of the regenerative process, including cable formation, Schwann cell migration, and axonal regeneration.     

Modification of fibrin matrix formation in situ enhances nerve regeneration in silicone chambers

The spatial-temporal progress of nerve regeneration was examined in silicone chambers of three different volume capacities: 11, 25, and 75 microliter. In all chambers, the stumps of a transected rat sciatic nerve were sutured into the ends of the chamber leaving a 10 mm gap between the stumps. Chambers were implanted empty (E chambers) or prefilled with saline (PF chambers). A coaxial and continuous fibrin matrix had formed in all chambers by 1 week. In E chambers, the matrices had a proximal-distal taper that was more pronounced in E25 and E75 chambers due to significantly larger matrix diameters in the proximal region. At 3 weeks, vascular and Schwann cell migration and axonal regeneration were less advanced in the E25 and E75 than in the control E11 chambers. The retardation correlated with the presence of an avascular organization of circumferential cells. Saline prefilling affected the caliber and density of fibrin fibers in the 1 week matrices of PF25 and PF75 chambers. The matrices did not have a prominent taper and diameters were progressively larger with increasing chamber volume. Saline prefilling did not affect regeneration progress in 3 week PF11 chambers but did enhance regeneration in the PF25 chambers; a 1.5-fold larger diameter nerve formed at 3 weeks that contained 2.6-fold more axons. Progress in the PF75 chamber was retarded. We conclude that the volume, timing, and nature of the fluid filling a silicone chamber have significant influence on the formation of fibrin matrices. Alterations in matrix formation correlate with substantial changes in the subsequent progress of intrachamber regeneration events.     

Resorbable filament structures as a scaffold for matrix formation and axonal growth in bioartificial nerve grafts: long term observations

Gaps, 10 mm wide, in rat sciatic nerves were bridged by bioartificial nerve grafts consisting of a silicone tube containing seven longitudinally placed synthetic filaments, which were expected to serve as a scaffold for axonal growth. The filaments were made of non-resorbable material (polyamide [Ethilon?]) or resorbable material (polydioxanon [PDS?], polyglactin [Vicryl?] or catgut). The purpose was to study the influence of resorbable materials on axonal regeneration and to choose, in the long term, the best filament material among the four. After 3 and 6 months, histological techniques were used to study the regenerated nerve structure. The total axon number in the nerve segment distal to the silicone chamber was counted in all specimens at 6 months. The histological findings were different depending on the filament materials; all the three resorbable materials showing significantly larger numbers of axons than polyamide (non-resorbable). All materials were covered with several layers of more or less flattened cells. These results indicate that resorbable filaments are superior to non-resorbable filaments when used as a scaffold inside a silicone tube, and polyglactin seems ideal for this purpose.     

Roles of neural stem cells in the repair of peripheral nerve injury

Currently, researchers are using neural stem cell transplantation to promote regeneration after peripheral nerve injury, as neural stem cells play an important role in peripheral nerve injury repair. This article reviews recent research progress of the role of neural stem cells in the repair of peripheral nerve injury. Neural stem cells can not only differentiate into neurons, astrocytes and oligodendrocytes, but can also differentiate into Schwann-like cells, which promote neurite outgrowth around the injury. Transplanted neural stem cells can differentiate into motor neurons that innervate muscles and promote the recovery of neurological function. To promote the repair of peripheral nerve injury, neural stem cells secrete various neurotrophic factors, including brain-derived neurotrophic factor, fibroblast growth factor, nerve growth factor, insulin-like growth factor and hepatocyte growth factor. In addition, neural stem cells also promote regeneration of the axonal myelin sheath, angiogenesis, and immune regulation. It can be concluded that neural stem cells promote the repair of peripheral nerve injury through a variety of ways.     

Recombinant ciliary neurotrophic factor promotes nerve regeneration and induces gene expression in silicon tube-bridged transected sciatic nerves in adult rats

Sciatic nerves in adult male rats were transected and reunited via a silicone chamber. This was followed by a focal injection of recombinant ciliary neurotrophic factor (CNTF). To evaluate the effect of this therapeutic approach and to explore its possible mechanisms, nerve regeneration was traced by horseradish peroxidase retrograde labeling. Functional recovery was evaluated by functional assessment of the hind feet and the expression of a number of proteins was detected using immunohistochemistry. The results showed that a single administration of CNTF could promote regeneration of motor axons, with improved functional recovery in adult rats. Growth associated protein (GAP)-43, S100, CD68 and major histocompatibility complex class II immunoreactivity in the regenerative and distal nerves suggested that CNTF could promote axon regeneration, Schwann cell migration, monocyte infiltration and activation. CNTF might also indirectly promote axonal regeneration by further activating the JAK-STAT3 pathway and subsequently upregulating phosphotyrosine, GAP-43 and S100 expression to enhance proliferation, growth and migration of Schwann cells. CNTF has suggested important targets for pharmacological intervention in peripheral nerve disease and injury.     

Sciatic nerve regeneration across gaps within silicone chambers: long-term effects of NGF and consideration of axonal branching

We examined whether the short-term beneficial effects of nerve growth factor (NGF) upon regeneration are sustained over a prolonged period of time across 8-mm gaps within silicone chambers. Rat sciatic nerve regeneration both with and without NGF was examined after 10 weeks. Myelinated counts from the regenerated sciatic and distal tributary nerves were correlated to the numbers of motor and sensory neurons retrogradely labeled with horseradish peroxidase (HRP) applied distal to the regenerated segment. Regenerated sciatic and sural nerves were examined ultrastructurally for morphological analysis. Both regenerated groups by 10 weeks achieved essentially complete counts of myelinated axons in the distal tributary nerves and the regenerated segment of the sciatic nerve compared to the uninjured controls. There were similar numbers of retrogradely labeled sensory and motor neurons in the dorsal root ganglia (DRG) and lumbar spinal cord of both groups and, surprisingly, of the uninjured normal control group. Ultrastructural analysis demonstrated no difference in the distribution of axonal diameters or myelin thickness between the regenerated groups. In evaluating regeneration in experimental silicone chamber models, it is important to determine such parameters as the percentage of neurons that grow across the gap and the incidence of axonal sprouting. One can then make accurate assessments of experimental perturbations and predict whether they improve the naturally occurring regeneration through chambers. These results must ultimately be compared with equivalent determinations in the uninjured nerve. At 10 weeks there was essentially complete regeneration of both the NGF and control regenerative groups.(ABSTRACT TRUNCATED AT 250 WORDS)     

Don't fence me in: harnessing the beneficial roles of astrocytes for spinal cord repair

Astrocytes comprise a heterogeneous cell population that plays a complex role in repair after spinal cord injury. Reactive astrocytes are major contributors to the glial scar that is a physical and chemical barrier to axonal regeneration. Yet, consistent with a supportive role in development, astrocytes secrete neurotrophic factors and protect neurons and glia spared by the injury. In development and after injury, local cues are modulators of astrocyte phenotype and function. When multipotent cells are transplanted into the injured spinal cord, they differentiate into astrocytes and other glial cells as opposed to neurons, which is commonly viewed as a challenge to be overcome in developing stem cell technology. However, several examples show that astrocytes provide support and guidance for axonal growth and aid in improving functional recovery after spinal cord injury. Notably, transplantation of astrocytes of a developmentally immature phenotype promotes tissue sparing and axonal regeneration. Furthermore, interventions that enhance endogenous astrocyte migration or reinvasion of the injury site result in greater axonal growth. These studies demonstrate that astrocytes are dynamic, diverse cells that have the capacity to promote axon growth after injury. The ability of astrocytes to be supportive of recovery should be exploited in devising regenerative strategies.     

Sensory neurite outgrowth on white matter astrocytes is influenced by intracellular and extracellular S100A4 protein

The central nervous system (CNS) is considered a nonpermissive environment for axonal regeneration because of the presence of myelin and associated repulsive molecules. However, neural cells transplanted to the CNS preferably migrate and extend their fibers in white matter areas. We previously showed that white matter astrocytes in vivo express the calcium-binding protein S100A4, which is strongly up-regulated in areas of white matter degeneration. To investigate the role of white matter astrocytes and their specific protein S100A4 in axonal regeneration, we developed white matter astrocyte cultures with strong S100A4 expression and grew dissociated adult dorsal root ganglion (DRG) cells on top of astrocytes for 24 hr. By using small interfering S100A4 RNA, we were able to eliminate S100A4 expression and compare growth of DRG cell neurites on S100A4-silenced and S100A4-expressing astrocytes. In addition, we studied whether extracellular S100A4 has an effect on neurite growth from adult DRG cells cultured on S100A4-expressing white matter astrocytes. Our data show that white matter astrocytes are permissive for neurite growth, although high levels of S100A4 in white matter astrocytes have a negative effect on this growth. Extracellular application of S100A4 induced extensive growth of DRG cell neurites on white matter astrocytes. These findings suggest that white matter astrocytes are able to support axonal regeneration and, furthermore, that administration of extracellular S100A4 provides strong additional support for axonal regeneration.     

Limits to the capacity of transplants of olfactory glia to promote axonal regrowth in the CNS

Olfactory bulb ensheathing cell (OBEC) transplants promoted axonal regeneration in the spinal cord dorsal root entry zone and in the corticospinal tract. However, OBECs failed to promote abducens internuclear neuron axon regeneration when transplanted at the site of nerve fibre transection. In experiments performed in both cats and rats, OBECs survived for up to 2 months, lining themselves up along the portion of the regrowing axons proximal to the interneuron cell body. However, OBECs migrated preferentially towards abducens somata, in the direction opposite to the oculomotor nucleus target. OBECs seem to promote nerve fibre regeneration only where preferred direction of glial migration coincides with the direction of axonal growth towards its target.     

Inhibition of p38 MAP kinase activity enhances axonal regeneration

Tumor necrosis factor alpha (TNF)-induced cellular signaling through the p38 mitogen-activated protein kinase (p38 MAPK) pathway plays a critical role in Wallerian degeneration and subsequent regeneration, processes that depend on Schwann cell (SC) activity. TNF dose-dependently induces Schwann cell and macrophage activation in vivo and apoptosis in primary SC cultures in vitro, while inhibition of p38 MAPK is thought to block these cellular processes. We show with Western blots that after sciatic nerve crush injury, phosphorylated p38 (p-p38) MAPK is significantly increased (P < 0.01) in distal nerve segments. In tissue sections, p38 co-localized immunohistochemically with activated Schwann cells (GFAP) and to a lesser degree with macrophages (ED-1). In other experiments, animals were gavaged with Scios SD-169 (10 or 30 mg/kg) or excipient (PEG300) 1 day before and daily after crush injury to the sciatic nerve. SD-169 is a proprietary oral inhibitor of p38 MAPK activity. The rate of axonal regeneration was determined by the functional pinch test and was significantly increased in treated animals 8 days after crush injury (P < 0.05; 30 mg/kg dose). In SD-169-treated animals with nerve transection, nerve fibers regenerating through a silicone chamber were morphologically more mature than untreated nerves when observed 28 days after transection. TNF immunofluorescence of distal nerve segments after crush injury suggested that SD-169 reduced SC TNF protein. In support of these findings, SD-169 significantly reduced (P < 0.05) TNF-mediated primary SC death in culture experiments. We conclude that inhibition of p38 activity promotes axonal regeneration through interactions with SC signaling and TNF activity.     

Evaluation of the long-term regenerative potential in an experimental nerve amputee model

In this study, we evaluated the long-term maintenance of regenerated axons in an experimental nerve amputee model. The sciatic nerve of adult rats was transected and repaired with a silicone tube leaving a short gap; the distal nerve segment was again transected 10 mm distally and the distal stump either introduced in a capped silicone chamber (amputee group) or connected to denervated targets (tibial branch into the gastrocnemius muscle and peroneal nerve apposed to skin) (reinnervation group). Morphological studies were performed at 2.5, 6, and 9 months after surgery. In all cases, axons regenerated across the silicone tube and grew in the distal nerve segment. In the amputee group, the morphological results show the expected features of a neuroma that is formed when regenerating axons are prevented from reaching the end organs, with a large number of axonal profiles indicative of regenerative sprouting. The number of myelinated axons counted at the distal nerve was sustained over 9 months follow-up, indicating that regenerated axons are maintained chronically. Immunohistochemical labeling showed maintained expression of choline acetyltransferase, calcitonin gene-related peptide, and growth-related peptides 43 in the distal neuroma at 6 and 9 months. Reconnection of the distal nerve to foreign targets mildly improved the pattern of nerve regeneration, decreasing the number of excessive sprouts. These results indicate that axons regenerated may be eventually interfaced with external input-output systems over long time, even if ending in the absence of distal targets as will occur in amputee limbs.     

Neurite-promoting factors and extracellular matrix components accumulating in vivo within nerve regeneration chambers

The outgrowth of neurites from cultured neurons can be induced by the extracellular matrix glycoproteins, fibronectin and laminin, and by polyornithine-binding neurite-promoting factors (NPFs) derived from culture media conditioned by Schwann, or other cultured cells. We have examined the occurrence of fibronectin, laminin and NPFs during peripheral nerve regeneration in vivo. A previously established model of peripheral nerve regeneration was used in which a transected rat sciatic nerve regenerates through a silicone chamber bridging a 10 mm interstump gap. The distribution of fibronectin and laminin during regeneration was assessed by indirect immunofluorescence. Seven days after nerve transection the regenerating structure within the chamber consisted primarily of a fibrous matrix which stained with anti-fibronectin but not anti-laminin. At 14 days, cellular outgrowths from the proximal and distal stumps (along which neurites grow) had entered the fibronectin-containing matrix, consistent with a role of fibronectin in promoting cell migration. Within these outgrowths non-vascular as well as vascular cell stained with anti-fibronectin and anti-laminin. Wihtin the degenerated distal nerve segment, cells characteristics of Bungner bands (rows of Schwann cells along which regenerating neurites extend) stained with anti-fibronectin and laminin. The fluid surrounding the regenerating nerve was found to contain NPF activity for cultured ciliary ganglia neurons which markedly increased during the period of neurite growth into the chamber. In previous studies using this particular neurite-promoting assay, laminin but to a much lesser extent fibronectin also promoted neurite outgrowth. Affinity-purified anti-laminin antibody failed to block chamber fluid NPF activity while completely blocking the neurite-promoting activity of laminin. These two results suggested that chamber fluid NPF activity did not consist of individual molecules of either fibronectin or laminin. The spatial and temporal distribution of insoluble fibronectin and laminin and the temporal correlation between chamber fluid NPF accumulation and neurite outgrowth support the possibility that these agents influence regenerative events including axonal elongation in vivo.     

Fgf-dependent glial cell bridges facilitate spinal cord regeneration in zebrafish

Adult zebrafish show a remarkable capacity to regenerate their spinal column after injury, an ability that stands in stark contrast to the limited repair that occurs within the mammalian CNS post-injury. The reasons for this interspecies difference in regenerative capacity remain unclear. Here we demonstrate a novel role for Fgf signaling during glial cell morphogenesis in promoting axonal regeneration after spinal cord injury. Zebrafish glia are induced by Fgf signaling, to form an elongated bipolar morphology that forms a bridge between the two sides of the resected spinal cord, over which regenerating axons actively migrate. Loss of Fgf function inhibits formation of this "glial bridge" and prevents axon regeneration. Despite the poor potential for mammalian axonal regeneration, primate astrocytes activated by Fgf signaling adopt a similar morphology to that induced in zebrafish glia. This suggests that differential Fgf regulation, rather than intrinsic cell differences, underlie the distinct responses of mammalian and zebrafish glia to injury.     

Neurite extension on dibutyryl cyclic AMP-stimulated astrocytes

Although both central and peripheral neurons successfully regenerate cut axons along peripheral nerve and other suitable substrates, axonal elongation through the mature central nervous system (CNS) is limited. It has been proposed that the presence of reactive astrocytes formed in response to CNS injury act as a barrier to axonal regeneration. In contrast, in vitro, astrocytes in a flat or unstimulated state have been shown to be a preferred substrate for neurite extension. We have investigated whether induced modifications of astrocytes alter the capacity of these cells to act as a substrate for axonal elongation. Treatment with dibutyryl cyclic AMP (dBcAMP) results in a marked morphological and biochemical change in astrocytes, considered by some to be a model of reactive astrocytosis. Retinal and dorsal root ganglia explants from embryonic mice were cultured on top of untreated glial monolayers and those treated with dBcAMP. The subsequent neuritic growth was measured at 48 h. No difference was found between the groups, indicating that astrocytes are an excellent substrate for axonal growth, even after they develop a stellate shape and high levels of glial fibrillary acidic protein.     

The effects of delayed nerve repair on nerve regeneration in a silicone chamber model

The silicone chamber model for nerve regeneration is suitable to test the effects of exogenous agents or surgical manipulations on nerve regeneration. The total 16-day regeneration period used in this model makes it possible to analyze the effects of certain manipulations on the sequential advancement of the individual cellular components (circumferential perineurial-like cells, vessels, Schwann cells, axons, and myelin) into the chamber fibrin matrix. In the present study we compared the effects on cellular migration of a 7 day delayed chamber repair vs. chamber repair immediately after transection (control chambers) of the rat sciatic nerve. Regeneration was evaluated with light and electron microscopic techniques. Chambers implanted after a delay of 7 days had a statistically significant more advanced migration of vessels, Schwann cells, and axons from the proximal nerve stump and also a significantly increased vascular density as compared to control chambers. We conclude that a 7 day delayed nerve repair stimulates nerve regeneration in this specific silicone chamber model.     

Nerve growth factor enhances regeneration through silicone chambers

The effect of exogenous NGF on axonal growth across a gap between sectioned ends of a sciatic nerve within silicone chambers was examined in Sprague-Dawley rats. After nerve section and surgical implantation, silicone chambers were filled with either a 1 mg/ml nerve growth factor (NGF)/saline solution (experimental) or a normal saline solution (control). Four weeks after surgery, the regenerated nerves from within the silicone chambers were dissected and fixed for histological studies at both light microscopic and ultrastructural levels. Morphological analysis of the nerves showed no difference between the NGF-treated and control groups in the size of the regenerated nerves within the chambers or in the diameters of myelinated axons. Total myelinated axonal counts were determined from within the distal chamber. NGF significantly increased the number of myelinated axons that grew into the distal end of the chamber (2126 +/- 437 NGF/saline; 1064 +/- 268 saline; P less than 0.05 Student's t test). Counts of the unmyelinated axons from the distal nerve segment from the two groups were not different. Myelin sheath thickness was 58% greater in the NGF-treated group compared with that in the saline group. There was no difference between the two groups in the size-frequency spectra of the diameters of the myelinated axons in the distal segment. The NGF/saline group showed a more mature-appearing regenerated nerve based on the percentage of myelinated axons, thickness of the myelin sheaths, and development of internal organization (e.g., amount of endoneurial collagen fibers, ensheathment of unmyelinated axons by Schwann cells, and interfascicular patterns).(ABSTRACT TRUNCATED AT 250 WORDS)     

Axonal growth and glial migration from co-cultured hippocampal and septal slices into fibrin-fibronectin-containing matrix of peripheral regeneration chambers: a light and electron microscope study

In order to investigate whether a fibrin-fibronectin-containing matrix of a peripheral regeneration chamber could promote the growth of central nervous system neurons, hippocampal and septal slices were co-cultured in the presence of this acellular substrate. In introducing the peripheral matrix into a 2-mm-long tube between hippocampal and septal slices, a spatio-temporal sequence of cell migration and axonal growth was described by light and electron microscopy. Axons were able to elongate directly into the flocculent material constituting the matrix and a possible neurite-promoting activity was implicated in this process as axonal growth was not detected in direct contact with rat plasma coagulated with calcium, or chicken plasma coagulated with thrombin, used as control matrices. However, in the 3 different substrates tested, astrocytes were able to migrate and dilated astroglial processes containing intermediate filaments were detected. Axonal processes were observed growing on the glial cell surface. GFAP-positive phagocytic cells, that could be of the same origin as astrocytes, were involved in matrix removing. Neuronal growth and glial migration arose from hippocampal and septum slices and acetylcholinesterase-containing fibers were seen in the bridging structure suggesting that cholinergic axons were able to progress to the hippocampal slice. This technique appeared to provide a model in which axonal growth and cell migration can be studied ‘in vitro’ in a 3-dimensional environment.