Axonal Regeneration into Acellular Nerve Grafts Is Enhanced by Degradation of Chondroitin Sulfate Proteoglycan

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The Journal of Neuroscience, August 15, 2001, 21(16):6206-6213

Axonal Regeneration into Acellular Nerve Grafts Is Enhanced by Degradation of Chondroitin Sulfate Proteoglycan
Craig A. Krekoski¹, Debbie Neubauer², Jian Zuo¹, and David Muir¹^,²
¹ Departments of Neuroscience and ² Pediatrics (Division of Neurology), University of Florida Brain Institute and College of Medicine, Gainesville, Florida 32610-0296

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Although the peripheral nerve has the potential to regenerate after injury, degenerative processes may be essential to promoteaxonal growth into the denervated nerve. One hypothesis is thatthe nerve contains growth inhibitors that must be neutralizedafter injury for optimal regeneration. In the present study, wetested whether degradation of chondroitin sulfate proteoglycan,a known inhibitor of axon growth, enhances the growth-promotingproperties of grafts prepared from normal donor nerves. Excisedsegments of rat sciatic nerve were made acellular by freeze-killingbefore treatment with chondroitinase ABC. Chondroitinase-dependentneoepitope immunolabeling showed that chondroitin sulfate proteoglycanwas thoroughly degraded throughout the treated nerve segments.In addition, neuronal cryoculture assays revealed that the neurite-promotingactivity of acellular nerves was significantly increased by chondroitinasetreatment. Control and chondroitinase-treated acellular nerveswere then used as interpositional grafts in a rat nerve injurymodel. Axonal regeneration into the grafts was assessed 4 and8 d after implantation by growth-associated protein-43 immunolabeling.At both time points, the number of axons regenerating into acellulargrafts treated with chondroitinase was severalfold greater thanin control grafts. Growth into the chondroitinase-treated graftswas pronounced after only 4 d, suggesting that the delay of axonalgrowth normally associated with acellular grafts was attenuatedas well. These findings indicate that chondroitinase treatmentsignificantly enhanced the growth-promoting properties of freeze-killeddonor nerve grafts. Combined with the low immunogenicity of acellulargrafts, the ability to improve axonal penetration into interpositionalgrafts by preoperative treatment with chondroitinase may be asignificant advancement for clinical nerveallografting.

Key words: nerve regeneration; acellular nerve graft; chondroitinase; basal lamina; neurite inhibitor; Schwann cell

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Peripheral nerve injuries are a major source of chronic disability. Although nerve tissue possesses the potential to regenerateafter injury, this response is strictly dependent on regeneratingaxonal sprouts making appropriate contact with endoneurial basallaminae in the distal nerve segment (Fawcett and Keynes, 1990).In crush injury, where there is axonal disruption but the continuityof the endoneurial sheath remains intact, axons regenerate withintheir original basal lamina, and complete recovery can be expected.In contrast, axonal regrowth may be severely compromised afternerve transection, and end-to-end primary repair is variable becauseof misalignment of nerve sheaths, basal laminae, and axons (Dagum,1998). These difficulties are of even greater concern in segmentalrepair by interpositional nervegrafting.

Nerve grafting is warranted with nerve ablation but presents several practical challenges. Over the years, various graft alternativeshave been explored. Presently viewed as a developing alternativeis the application of allogenic nerve grafts. Although fresh donorgrafts have the difficulties of other organ replacement strategies,the importance of viable cellular elements in nerve grafts maybe far less important. Although Schwann cells contribute significantlyto the regenerative process, the nerve sheath structure containsthe essential scaffolding and adhesive cues to promote axonalregeneration, and significant regeneration has been achieved inacellular (freeze-killed) nerve grafts (Ide et al., 1983; Hall,1986; Gulati, 1988; Nadim et al., 1990). Moreover, acellular nervesgreatly reduce the concerns of host-graft immunorejection (Evanset al., 1994, 1998). These features provide considerable promisefor the use of cryostored allografts. On the other hand, the absenceof viable cells precludes nerve degeneration and remodeling, whichseem to promote the regenerative process (Bedi et al., 1992; Danielsenet al., 1994). Laminin is a major neurite-promoting componentof the basal lamina that almost certainly represents the adhesivestimulus for successful axonal regeneration (Wang et al., 1992).Interestingly, normal nerve is rich in laminin, yet before degeneration,it is refractory to axonal growth (Langley and Anderson, 1904;Brown et al., 1994). This suggests that the growth-promoting activityof laminin is suppressed in a normal nerve environment and thatlaminin activity must somehow be revived in nerve degenerationand ensuingregeneration.

Increasing evidence indicates that chondroitin sulfate proteoglycans (CSPGs) can inhibit axonal growth and negate the growth-promotingactivities of extracellular matrix components (Muir et al., 1989;Snow et al., 1990; Brittis et al., 1992; McKeon et al., 1995;Fidler et al., 1999). We recently found that the peripheral nervecontains CSPG, which inhibits the growth-promoting activity ofendoneurial laminin (Zuo et al., 1998a). Furthermore, our worksupports the conclusion that CSPG-degrading enzymes representa mechanism by which the growth-promoting properties of lamininmay be restored within a degenerating nerve (Zuo et al., 1998b;Ferguson and Muir, 2000). In the present study, we examined nerveregeneration into acellular nerve grafts treated with chondroitinase.Our results indicate that degradation of CSPG improves the abilityof axons to traverse the host-graft interface and significantlyincreases the number of axons growing into acellular nervegrafts.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Preparation of acellular nerve grafts. Adult (180-200 gm) female Sprague Dawley rats (Harlan, Indianapolis, IN) were usedas nerve donors and recipient hosts. This project was reviewedand approved by the Institutional Animal Care and Use Committee.Donor rats were anesthetized with halothane and decapitated. Sciaticnerves were exposed through a gluteal muscle-splitting incisionand isolated free of underlying fascia. A 15 mm nerve segmentwas excised rostral to the bifurcation into common peroneal andtibial nerves. The segments were rinsed with cold sterile Ringer'ssolution, stabilized by pinning the ends to a thin plastic support,and transferred to a cryogenic vial. The vials were submergedin liquid nitrogen for 2 min and then transferred to a 37°C waterbath for 2 min. This freeze-thaw cycle was repeated, yieldingacellular nerve grafts that were then stored in liquid nitrogen.On the day before grafting, the nerve grafts were warmed to roomtemperature and incubated in 100 µl of PBS, pH 7.4, containing2 U/ml chondroitinase ABC (Sigma, St. Louis, MO) or in PBS (vehicle)only for 16 hr at 37°C. The grafts were rinsed twice with Ringer'ssolution and kept on ice before use. The chondroitinase ABC preparationis highly purified and stated by the manufacturer to be essentiallyfree of proteaseactivity.

Interpositional nerve grafting. Twelve rats received bilateral acellular nerve grafts, one chondroitinase-treated and onevehicle-treated. Host rats were deeply anesthetized using xylazine(15 mg/kg, i.m.) and ketamine (110 mg/kg, i.p.). The sciatic nervewas exposed and supported by a plastic insert placed between thenerve and underlying tissue. The region of the nerve halfway betweenthe sciatic notch and bifurcation was first coated with fibringlue. Using serrated scissors, a 2.5 mm segment of the host nervewas excised and replaced with a freshly trimmed 10 mm acellularnerve graft. The graft was coapted to the host nerve stumps byepineurial neurorrhaphy using one 9-0 Ethilon suture at each end.Fibrin glue was then applied to stabilize the coaptations, which,in combination with the initial fibrin coating, also reduced protrusionof nerve elements (endoneurial mushrooming) (Menovsky and Bartels,1999). The muscle was closed with 4-0 sutures, and the skin wasclosed with wound clips. After recovery from the anesthetic, animalswere returned to standard housing. Nine rats were killed at 8d and four at 4 d aftergrafting.

Animals were deeply anesthetized and decapitated. The graft and 3 mm of proximal and distal host nerve were removed and immersedin 4% paraformaldehyde in 0.1 M phosphate buffer, pH 7.4, overnightat 4°C. The specimens were equilibrated with PBS and immersedin 30% sucrose in phosphate buffer for 2 d at 4°C. Using a dissectingmicroscope and the epineurial sutures as landmarks, each specimenwas subdivided into three segments representing (1) the proximalnerve-graft interface, (2) the main graft, and (3) the distalnerve-graft interface. The specimens were embedded and cryosectioned.Longitudinal sections were taken through the nerve-graft interfacesto examine the continuity of thecoaptations.

The main grafts were sectioned serially on the transverse plane in a recorded measure to assess the extent of axonal growthby microscopy. Regenerating axons were labeled by growth-associatedprotein-43 (GAP-43) immunofluorescence (see below) in sectionsof the grafts at 0.56 mm intervals. Epifluorescent photomicrographswere acquired using a SPOT digital camera system (Diagnostic Instruments,Sterling Heights, MI) and Axiovert 10 microscope (Carl Zeiss,Thornwood, NY). GAP-43-positive axon profiles were scored usingImage-Pro Plus software (Media Cybernetics, Silver Spring,MD).

Immunocytochemistry. Axonal regeneration was assessed by GAP-43 immunofluorescence and digital image analysis. Tissue sectionsmounted on slides were washed with PBS and then treated with 0.5%Triton X-100 in PBS for 10 min. The sections were treated withblocking buffer (10% serum in PBS and 0.1% Triton X-100) and thenincubated overnight at 4°C with primary antibodies (diluted inblocking buffer). Bound primary antibodies were labeled with swineanti-rabbit immunoglobulins (Dako, Carpinteria, CA) or goat anti-mouseimmunoglobulins (Sigma) conjugated with fluorescein or rhodaminefor 1 hr at room temperature in darkness. The anti-mouse secondaryantibody was preadsorbed with rat serum before use. The sectionswere washed, post-fixed with 4% paraformaldehyde in PBS, rinsed,and coverslipped in fluorophore-stabilizing mounting media. Affinity-purifiedrabbit anti-GAP-43 peptide antibody was produced in our laboratoryas described previously (Ferguson and Muir, 2000) and was usedat 2 µg/ml. Polyclonal antibody 1918 (Chemicon International,Temecula, CA; 1:1000) binds only to the unsaturated disaccharideunit that remains attached to the linkage region of the CSPG coreprotein exposed by digestion with chondroitinase ABC (Bertolottoet al., 1986). Polyclonal anti-mouse laminin-1 antibody (Sigma;1:1000) was used to label basal laminae. Polyclonal anti-S-100antiserum (Dako; 1:500) was used to label Schwann cells. Dark-fieldimages were inverted and optimized for printing in Photoshop (AdobeSystems, San Jose,CA).

Cryoculture bioassay. Cryoculture is a neurite outgrowth assay in which neurons are cultured directly on fresh-frozen nervesections and was performed as described previously (Ferguson andMuir, 2000). Briefly, chondroitinase- and vehicle-treated nervesegments were sectioned at 20 µm, mounted on sterile coverslips,and stored at $-$ 20°C until used. Where indicated, sections weretreated with chondroitinase ABC (0.1 U/ml) or vehicle (50 mM Tris-HCl,pH 8.0, containing 50 mM NaCl) for 2 hr at 37°C. Purified dorsalroot ganglionic (DRG) neurons from day 8 chick embryos were seededdirectly on the nerve sections in a defined N2 medium (Bottensteinet al., 1980) containing 10 ng/ml nerve growth factor. Cryocultureassays were terminated after 24 hr of incubation by fixation with100% methanol. Neuritic growth by DRG neurons was accessed byGAP-43 immunofluorescent labeling. Epifluorescent photomicrographswere acquired as described for tissue sections. Neurite lengthswere measured directly using Image-Pro Plus software (Media Cybernetics).At least 250 neurons with neurites greater than one cell body(~15 µm) were scored for each condition in eachexperiment.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Degradation of CSPG by treatment of acellular nerve segments with chondroitinase

We previously found that treatment of peripheral nerve tissue sections with chondroitinase ABC degrades and inactivates neuritegrowth-inhibiting CSPG associated with the endoneurial basal laminae(Zuo et al., 1998a). The first aim of this study was to determinewhether chondroitinase treatment effectively degraded CSPG throughoutintact segments of acellular nerves. Segments of rat sciatic nerve(1.5 cm in length) were made acellular by repeated freeze-thawcycles and then bathed en bloc in a chondroitinase ABC solutionfor 16 hr. CSPG degradation within the chondroitinase-pretreatednerves was examined by immunolabeling with neoepitope antibodyAb1918. This antibody binds to an epitope created on the coreprotein after lysis of the chondroitin sulfate chains by chondroitinaseABC (Bertolotto et al., 1986). Ab1918 immunostaining was intensethroughout the entire pretreated nerve segment (Fig. 1A). Furthermore,the intensity of Ab1918 immunostaining was not increased by anadditional post-treatment of the sections with chondroitinase(Fig. 1B). Ab1918 immunoreactivity was absent in acellular nervesnot exposed to chondroitinase (results not shown). These findingsindicate that the en bloc chondroitinase treatment effectivelypermeated all nerve compartments and thoroughly degraded CSPGside chains.

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Figure 1. CSPG neoepitope immunofluorescence of chondroitinase-treated acellular nerve grafts. Acellular (freeze-thawed) rat sciatic nerve segments were treated en bloc with chondroitinase ABC for 16 hr in vitro. A, Neoepitope (chondroitinase-dependent) labeling with Ab1918 showed that en bloc treatment with chondroitinase effectively permeated all nerve compartments and degraded CSPG side chains. B, The intensity of Ab1918 immunolabeling was not increased by additionally treating sections of the nerve shown in A with chondroitinase, indicating that the initial en bloc treatment was thorough. C, The structural integrity of Schwann cell basal laminae in chondroitinase-treated acellular nerve segments was shown by laminin immunofluorescence. D, Ab1918 immunolabeling of chondroitinase-treated acellular interpositional nerve graft after 8 d in vivo.

In a normal nerve, CSPG and laminin are mainly colocalized in the nerve sheaths and basement membranes, including Schwanncell basal laminae (Zuo et al., 1998a). Their distributions wereunchanged after repeated freeze-thaw, and there was no indicationat the light microscopic level that en bloc chondroitinase treatmentaltered extracellular matrix structures (Fig. 1A,C). The integrityof chondroitinase-treated acellular nerve segments was an importantconsideration for their subsequent use as nerve regeneration grafts.Accordingly, we also examined the structural integrity of thepretreated nerve segments after nerve grafting. The intensityand distribution of Ab1918 immunoreactivity (in regions of thegrafts not infiltrated by host cells) was unchanged after 8 din vivo, indicating the primary structure of Schwann cell basallaminae remained intact (Fig. 1D). Taken together, these resultsdemonstrate that en bloc chondroitinase treatment of acellularnerve grafts effectively degraded CSPG without compromising thebasal lamina scaffold or dislocating its laminincontent.

Inactivation of inhibitory CSPG by treatment of acellular nerve segments with chondroitinase

Inactivation of inhibitory CSPG in a chondroitinase-treated acellular nerve was determined by cryoculture bioassay. Embryonicchick DRG neurons were seeded onto sections of prepared nervesegments, and the neurite-promoting activity was assessed by scoringneurite growth. Results are shown in Figure 2. On sections ofan acellular nerve pretreated en bloc with vehicle only, the averageneurite length was 49 µm. Neurite growth on an acellular nervepretreated en bloc with chondroitinase averaged 96 µm, representinga 95% increase compared with the control condition. To determinewhether the en bloc chondroitinase treatment was thorough, cryocultureassays were performed on nerve tissues treated with chondroitinaseafter sectioning (post-treatment). As expected, the neurite-promotingactivity of acellular nerve treated en bloc with vehicle onlywas increased significantly (86%) by post-treatment with chondroitinase.In contrast, chondroitinase post-treatment had only a slight additiveeffect on sections from en bloc chondroitinase-treated nerve grafts.These results indicate that inhibitory CSPG was effectively degradedand inactivated by bathing lengthy segments of acellular nervegrafts in small amounts of chondroitinase ABC. In addition, enbloc chondroitinase treatment effectively deinhibited the nervegrafts without disrupting the laminin-associated, neurite-promotingpotential of the basal lamina scaffold. The latter point was strengthenedby the observation that, as in cryoculture assays of normal anddegenerated nerve (Ferguson and Muir, 2000), neurite growth onsections of chondroitinase-treated acellular nerve grafts occurredin strict association with Schwann cell basal laminae.

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Figure 2. Inactivation of inhibitory CSPG by cryoculture bioassays of acellular nerve segments treated with chondroitinase. Acellular nerve segments were treated en bloc with chondroitinase or vehicle alone. The nerves were sectioned and then additionally post-treated with chondroitinase or vehicle only. Dissociated chick embryonic DRG neurons were grown on the nerve sections for 24 hr, and neurite lengths were scored as described in Materials and Methods. Determinations were made by scoring at least 250 neurons in each condition. Results are expressed as mean ± SEM, and statistical significance comparing the en bloc vehicle and chondroitinase conditions was determined using Student's t test. *p < 0.001.

Nerve regeneration is enhanced by chondroitinase treatment of acellular nerve grafts

In the next set of experiments, we tested the hypothesis that chondroitinase treatment improves nerve regeneration throughacellular nerve allografts. As described above, acellular sciaticnerve segments were treated en bloc with vehicle or chondroitinaseABC. Ten millimeter interpositional nerve grafts were joined tothe host nerve by epineurial neurorrhaphy reinforced with fibringlue. Each of nine host rats received bilateral grafts, one vehicle-treatedand one chondroitinase-treated. Regeneration was initially examinedafter 8 d. First, the proximal and distal nerve-graft coaptationswere examined in longitudinal sections to assess the alignmentof the surgical coaptation (Fig. 3). All of the grafts were incontinuity and thus were included in the subsequent analysis.Scoring of regeneration was based on GAP-43 immunolabling, whichintensely stained growing axons. Axon and Schwann cell remnantswithin the freeze-killed grafts were immunonegative for GAP-43,and host Schwann cells were only very faintly stained (at an intensitybelow the threshold used for digital scoring). Axonal growth wasassessed at specified spatial intervals within the graft by scoringGAP-43-immunopositive profiles in transverse sections. Some axonalingrowth was observed in all grafts, as depicted in Figure 4.However, the growth into chondroitinase-treated grafts was markedlygreater and more widely distributed than in control grafts. Quantitativeresults are shown in Figure 5. The average number of axons (GAP-43-immunopositiveprofiles) entering chondroitinase-treated grafts was on averagemore than threefold greater than in control grafts. Although theaxons entering the control grafts were always restricted and mostoften clustered centrally, the initial growth into chondroitinase-treatedgrafts was more widely dispersed and especially abundant at theproximal end. These findings indicate that the success of axonalpenetration into acellular nerve grafts was markedly improvedby pretreatment of the grafts with chondroitinase. However, asimilar number of axons was consistently observed at the distalends of grafts in both conditions. This suggested that axonalpenetration into the control grafts occurred early and then wastemporally restricted, whereas axons continued to penetrate chondroitinase-treatedgrafts during the 8 d period.

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Figure 3. Assessment of the continuity and GAP-43 immunostaining of interpositional acellular nerve grafts. The continuity of each nerve graft was confirmed by examining the proximal and distal nerve-graft coaptations in a longitudinal section. At the proximal coaptation, GAP-43 labeling revealed numerous regenerating axons entering the proximal aspect of the graft. GAP-43 did not label any remnant elements within the acellular graft.

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Figure 4. Axonal regeneration into acellular interpositional nerve grafts after 8 d. Shown is a representative series of sections from two animals, each receiving vehicle-treated and chondroitinase-treated grafts. Serial sections taken from the proximal graft (top) and subsequent 0.56 mm intervals were immunolabeled with GAP-43. In each animal receiving bilateral grafts (n = 9), axon growth was greater in the acellular graft treated with chondroitinase than in the vehicle-treated control. Images were cropped at the epineurium to approximate the fields scored by digital image analysis in Figure 5.

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Figure 5. Greater accession of regenerating axons into chondroitinase-treated acellular nerve grafts. Serial sections of 8 d interpositional nerve grafts (as depicted in Fig. 4) were scored for GAP-43-labeled axonal profiles by digital image analysis. Data represent the mean ± SEM of nine vehicle-treated and nine chondroitinase-treated grafts assessed at the specified distances into the graft (proximal to distal).

To determine whether the latency of axonal growth into acellular grafts was reduced by chondroitinase treatment, the sameanalysis was performed on 4 d grafts except that the most proximalaspects of the grafts were examined and scored in a transversesection as well. Although only 3 animals receiving bilateral graphswere examined, the results were consistent with those observedfor 8 d grafts. Moreover, at the most proximal aspect of the graft(0.3 mm from the host-graft interface), axonal penetration wason average fivefold greater in chondroitinase-treated grafts (Fig.6). From these results we conclude that chondroitinase treatmentdecreases the latency and significantly improves the accessionof axonal regeneration into acellular nerve grafts.

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Figure 6. Axonal regeneration into the initial segment of acellular interpositional nerve grafts after 4 d. The nerve-graft interface and immediately proximal region of 4 d acellular grafts were examined as described in Figure 5. GAP-43-labeled axon profiles were compared at 0.3 mm into the grafts. Data represent the mean ± SEM of three vehicle-treated and three chondroitinase-treated grafts.

Axon regeneration occurred within basal lamina tubes of chondroitinase-treated grafts

The success of nerve regeneration depends on the growth of axons within the laminin-rich basal lamina tubes. We examined whetherthe association of axonal growth with basal laminae was alteredby chondroitinase treatment of acellular grafts. Transverse sectionsof 8 d grafts were double-labeled for GAP-43 and laminin. Figure7 represents the pattern of growth observed in the middle of achondroitinase-treated graft. Laminin labeling was intense, andbasal laminae appeared similarly intact throughout control andchondroitinase-treated grafts. Despite repeated freeze-thaw, enzymetreatment, surgical manipulation, and 8 d in vivo, the extracellularmatrix scaffold appeared structurally intact. Multiple GAP-43-labeledaxons (or neurites) were evident within individual basal laminae,and most of these were observed in close association with thelumenal surface of the tubes (Fig. 7, inset). A similar and minornumber of neurites with ambiguous apposition were observed incontrol and treated grafts. By and large, the propensity of axonsto grow within basal laminae was unaltered by chondroitinase treatmentof acellular nerve grafts.

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Figure 7. Axonal regeneration occurred within the basal lamina of chondroitinase-treated grafts. A transverse section from the midsection of an 8 d chondroitinase-treated acellular graft is shown double-labeled for GAP-43 (regenerating axons; red) and laminin (basal laminae; green). Multiple axons (neurites) often grew within a single endoneurial tube. Most axon profiles were found in close association with the lumenal surfaces of Schwann cell basal laminae (inset).

Axonal growth was not preceded by Schwann cell migration into the grafts

Serial sections of the 8 d grafts were immunolabeled for S-100 and GAP-43 to examine the migration of Schwann cells with respectto axon growth. The grafts contained two distinct patterns ofS-100 staining: intense staining was associated with live, host-derivedSchwann cells and faint staining with freeze-killed Schwann cellremnants. The descriptions that follow refer to the intenselystained (live) Schwann cell profiles, unless otherwise indicated.In proximal regions of the grafts, the distributions of Schwanncells and axons mainly coincided (Fig. 8). Occasional clustersof axons were found without any apparent Schwann cell association.Scattered Schwann cells were also seen in regions without growingaxons. Schwann cell migration was apparent well into the 8 d grafts.However, at more distal points in the grafts, axons were mostoften found without accompanying Schwann cells (Fig. 8). Thiswas confirmed in longitudinal sections including the distal coaptation(Fig. 9). S-100-labeled Schwann cells were abundant in the distalhost stumps, yet few if any had invaded the distal aspect of thegrafts (which contained only freeze-killed Schwann cell remnants)(Fig. 9B). The examples presented in Figures 8 and 9 were obtainedfrom chondroitinase-treated grafts, and identical results wereobserved in the control grafts. These findings suggested thatthe enhancement of axonal growth in chondroitinase-treated graftswas primarily attributable to the potentiation of the neurite-promotingactivity of the basal lamina.

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Figure 8. Association of axon regeneration and Schwann cell migration within the grafts. Serial sections of 8 d grafts were immunolabeled for GAP-43 (axons) and S-100 (Schwann cells). In proximal regions of the chondroitinase-treated grafts, Schwann cells were most often found in close association with regenerating axons. Occasional clusters of axons were observed without comigrating Schwann cells (arrow). At more distal points in the grafts, axons were often found without accompanying Schwann cells. Few isolated Schwann cells were intensely immunolabeled for S-100 in the more distal regions of the grafts, which contained mostly faint S-100 staining associated with freeze-killed Schwann cell remnants.

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Figure 9. Axon and Schwann cell growth at the distal graft coaptation. Serial longitudinal sections of 8 d chondroitinase-treated grafts and distal nerve stumps were immunolabeled for GAP-43 (axons; A) and S-100 (Schwann cells; B). A, Axons (small arrows) approach, traverse the distal coaptation, and grow diffusely within the host distal stump. B, S-100-labeled Schwann cells are abundant in the distal host stumps, yet few if any invade the distal aspect of the grafts (which contains faint S-100 immunostaining associated with freeze-killed Schwann cell remnants).

In this study, the path of axonal growth was examined only in longitudinal sections of tissues immediately surrounding theproximal and distal coaptations. On entering the grafts, axongrowth was directed distally, and there was no indication of deviantgrowth or neuroma formation within the grafts. This suggestedthat guidance mechanisms (or chemoattractant properties associatedwith the distal stump) were not compromised in chondroitinase-treatedgrafts. In addition, on the basis of the few instances in whichaxons had reached the distal extent of the graft, axons exitedthe grafts and continued growth into the host nerve stump (Fig.9A).

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The results of the present study show that (1) chondroitinase ABC treatment effectively degraded and inactivated inhibitoryCSPG throughout acellular nerve segments, and (2) axonal ingressand the magnitude of axonal regeneration were markedly increasedin acellular grafts treated with chondroitinase. The main conclusionis that degradation of CSPG within acellular grafts improves theability of regenerating axons to traverse the nerve-graft interfaceand potentiates axonal growth within its basal lamina scaffold.These results confirm our previous in vitro findings that inactivationof inhibitory CSPG deinhibits the neurite-promoting activity ofendoneurial laminin in normal nerves. This work supports the hypothesisthat deinhibition by chondroitinase mimics an essential processthat occurs naturally in nerve degeneration to reveal the growth-promotingpotential of the Schwann cell basallamina.

Our past work indicates that the conversion of a normal nerve from a nonpermissive state to one that promotes axonal regenerationmay occur by degradation of the CSPG core protein by matrix metalloproteinasesexpressed in a degenerating nerve (Zuo et al., 1998b; Fergusonand Muir, 2000). A goal of the present study was to optimize thegrowth-promoting potential of acellular nerve grafts preparedfrom normal nerves. Although this may be achieved during nervedegeneration by metalloproteinases that degrade the CSPG coreprotein, inactivation of CSPG is also effectively achieved byapplication of chondroitinase. This bacterial enzyme is veracious,and, unlike matrix metalloproteinases, its activity appears tobe unchecked by natural inhibitors in nerve tissues. An additionaladvantage is that this glycosidase degrades only CSPG side chainsand does not disrupt nerve sheath organization or displace lamininfrom the Schwann cell basal lamina. Moreover, chondroitinase ABCis suggested for clinical application, and it is safe regardingadverse effects on nerve tissue and blood vessels (Olmarker etal., 1996).

Nerve grafting is warranted with nerve ablation or transection when the stumps have retracted and cannot be coapted withouttension (Millesi, 1984). Presently, autologous nerve grafts arethe first choice for interpositional grafting. Autografts offerdistinct advantages, because they are available fresh at surgery,contain viable glial and vascular elements, and are inherentlyimmunocompatible. However, alternatives to nerve autografts remaina goal of neurosurgeons to avoid the concurrent functional deficitsassociated with procuring autografts, which also preclude thisapproach for management of major or extensive nerve defects. Allogenicnerve grafting overcomes these concerns but remains experimentaland is limited by the need for long-term systemic immunosuppression.On the other hand, recent advances have been made to reduce theimmunoreactive responses to allografts by nullifying the cellularcomponents of the graft (for review, see Evans et al., 1994).This approach may be especially relevant in light of accumulatingevidence that regenerating axons can grow effectively within freeze-killednerve grafts (Gulati, 1988; Ide et al., 1990; Sondell et al.,1998). Important characteristics of these acellular nerve graftsis that they have lost much of their immunogenicity and can bestored frozen for extended periods without losing their growth-promotingactivity (Ide, 1996; Evans et al., 1998). Despite these advantages,freeze-killing also decreases the ability of grafts to promoteregeneration, and acellular grafts remain inferior to those containingviablecells.

Acellular nerve grafts have been used as a model for investigating the relative contributions of the extracellular matrixand non-neuronal cells for the support of regenerating axons.It is generally agreed that both axons and Schwann cells regeneratinginto acellular grafts are mostly associated with preexisting basallaminae (Hall, 1986; Nadim et al., 1990; Ide et al., 1990). Thisassociation was confirmed in the present study, and we observedthat axonal regeneration occurred within the Schwann cell basallaminae of chondroitinase-treated grafts as well. Axonal regrowthis accompanied by and enhanced or sustained by the ingress ofSchwann cells. In our studies, Schwann cell invasion into controland chondroitinase-treated grafts appeared to follow axonal growth.Although there was a high proportion of Schwann cells in the proximalgraft, Schwann cell numbers progressively diminished, and theirassociation with axons was less evident at the distal extent ofaxonal growth. We also observed isolated axons and growth conesin the distal regions of the grafts, and there was little evidenceof Schwann cell ingress from the distal host nerve. Otherwise,Schwann cell processes were closely associated with establishedaxons within the grafts. More directed studies are required todetermine whether chondroitinase treatment also enhanced the migrationof Schwann cells into acellular grafts. Aside from the magnitudeof the regenerative response, and considering the bilateral evidencethat either axons or Schwann cells might have a leading role inregeneration through nerve grafts, there was no evidence thatchondroitinase treatment altered the course of axonal growth orcellular interactions commonly associated with nerve regeneration.Combined with our cryoculture studies, these findings supportthe conclusion that chondroitinase treatment primarily enhancednerve regeneration in the grafts by deinhibiting the neurite-promotingproperties of the basal lamina. Examination of longer nerve graftsis required to determine whether chondroitinase treatment aloneis sufficient to overcome the limitations of axonal growth inacellular grafts over longerdistances.

Acellular grafts prepared from fresh nerves are inherently incapable of degeneration. Schwann cells and inflammatory cellsfrom the host nerve will migrate into and remodel the acellulargraft, promoting regeneration. However, this process is slow anderratic and may be restricted in long grafts by limits in Schwanncell proliferation and migration (Hall, 1986; Anderson et al.,1991). One approach to improve the growth-promoting propertiesof acellular grafts is to repopulate the graft with autologousSchwann cells (Gulati et al., 1995). Autologous Schwann cell replacementstrategies retain the low immunogenicity of acellular allograftsand may reinstate nerve degeneration and remodeling. The importanceof the degenerative process has been demonstrated in several nerve-graftingmodels, and fresh predegenerated nerve grafts may be as effectiveor more effective than fresh normal nerve grafts in promotingregeneration of peripheral nerve axons (Gordon et al., 1979; Danielsenet al., 1994). Furthermore, predegeneration reduces the initialdelay of axon penetration and enhances regeneration into freeze-killednerves as well (Danielsen et al., 1995). This indicates that,in degeneration, cellular mechanisms act to enhance the growth-promotingproperties of the basal lamina, which then retains the abilityto stimulate nerve regeneration after the cellular elements havebeen killed. Our results suggest that chondroitinase treatmentmimics a key degenerative process by enhancing the growth-promotingproperties of the basal lamina scaffold in acellular nerve grafts.Additionally, modification of acellular nerve grafts by chondroitinasemarkedly accelerates the ingress of axons and thus overcomes amajor shortcoming associated with freeze-killed nerve grafts.Because the in vivo predegeneration of a human donor nerve isimpractical, degradation and inactivation of CSPG by chondroitinasemay greatly expand the clinical potential for acellulargrafts.

Loss of continuity is inevitable in end-to-end nerve repair or grafting and presents a major obstacle to regenerating axonalsprouts. At the nerve-graft interface, we observed tangles ofregenerating axons as they sought passage into the graft. Neuromaformation is often associated with regeneration failure afternerve injury and surgical repair (Dellon and Mackinnon, 1988).Our findings indicate that axonal penetration into acellular graftswas markedly improved by pretreating the grafts with chondroitinase.Not only did deinhibition of the Schwann cell basal laminae increasethe number of axons that penetrated the grafts, but the initialdelay of ingrowth appeared to be decreased as well. It is knownthat axon sprouts will degenerate if they fail to traverse thecoaptation and make appropriate contact with basal laminae inthe distal nerve or graft (for review, see Fu and Gordon, 1997).Thus, it is likely that the rapid accession into chondroitinase-treatedgrafts may also increase survival by axotomized neurons, whichis especially important for negating the increased risk of neuronalatrophy and death associated with more proximalinjuries.

Functional recovery after microsurgical nerve repair is variable. Serious sensory and motor deficits are the most likely outcomesand are the direct result of insufficient reinnervation of targetorgans. Any failure of initial growth into nerve grafts surelycontributes to sparse reinnervation. However, even marginal increasesin reinnervation can result in significant improvements in function.Combined with the low immunogenicity of acellular grafts, theability to improve axonal penetration into interpositional graftsby preoperative treatment with chondroitinase may provide considerableimprovement in clinical nerve allografting. Additionally, long-termand thorough neurological studies are required to assess the fullpotential of this graft preparation on recovery offunction.

  FOOTNOTES

Received March 6, 2001; revised May 23, 2001; accepted June 5, 2001.

Support for this work was provided by grants awarded to D.M. from the National Institutes of Health (Grant NS37901) and theFlorida State Brain and Spinal Cord Injury Rehabilitation TrustFund. We thank Dr. P. Mickle (Department of Neurosurgery, Universityof Florida) for support and advice in microsurgicaltechnique.
Correspondence should be addressed to Dr. David Muir, Pediatric Neurology, Box 100296, University of Florida College of Medicine,Gainesville, FL 32610-0296. E-mail: muir{at}ufbi.ufl.edu.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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