Development of Walking, Swimming and Neuronal Connections after Complete Spinal Cord Transection in the Neonatal Opossum, Monodelphis domestica

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The Journal of Neuroscience, January 1, 1998, 18(1):339-355

Development of Walking, Swimming and Neuronal Connections after Complete Spinal Cord Transection in the Neonatal Opossum, Monodelphis domestica
N. R. Saunders¹, P. Kitchener¹, G. W. Knott¹, J. G. Nicholls², A. Potter¹, and T. J. Smith¹
¹ Division of Anatomy and Physiology, University of Tasmania, Hobart, Tasmania 7001, Australia, and ² Biozentrum der Universität Basel, CH-4056 Basel, Switzerland

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Development of coordinated movements was quantitatively assessed in adult opossums (Monodelphis domestica) with thoracic spinalcords transected by (1) crushing 7-8 d after birth [postnataldays 7-8 (P7-P8)]; at 2-3 years of age, systematic behavioraltests (e.g., climbing, footprint analysis, and swimming) showedonly minor differences between control (n = 5) and operated (n= 10) animals; and (2) cutting on P4-P6; at 1 month these opossumsexhibited coordinated walking movements but were unable to rightthemselves from a supine position, unlike controls (n = 6). Whentested at 2 or 6 months, they could right themselves and showedremarkable coordination, albeit with more differences from controlsthan after a crush. No animals with spinal cords that were crushedat P14-18 survived because of cannibalism by the mother. Morphologicalstudies (n = 10) 3 months-3 years after crush at 1 week showedrestoration of structural continuity and normal appearance atthe lesion site. Animals with cut rather than crushed cords showedcontinuity but greater morphological deficits. That lesions werecomplete was demonstrated by examining morphology and nerve impulseconduction immediately after crushing or cutting the spinal cordin controls. After lumbar spinal cord injection of 10 kDa dextranamine, retrogradely labeled cells were found rostral to the lesionin hindbrain and midbrain nuclei. Conduction was restored acrossthe site of the lesion. Thus complete spinal cord transectionin neonatal Monodelphis was followed by development of coordinatedmovements and repair of the spinal cord, a process that includeddevelopment of functional connections by axons that crossed thelesion.

Key words: Monodelphis domestica; behavior after spinal injury; regeneration; response to injury; spinal cord injury; neurite outgrowth

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Outgrowth of neurites in injured adult mammalian spinal cord only occurs under special experimental circumstances, such asapplication of trophic molecules or antibodies and implantationof fetal CNS grafts (see Schwab and Bartholdi, 1996). By contrast,regeneration is pronounced in immature mammalian CNS (Nichollsand Saunders, 1996). In most studies on injured immature spinalcord, axonal growth only occurred when part of the cord was leftintact, and fibers grew around the lesion via the normal tissuerather than across the lesion (e.g., Bernstein and Stelzner, 1983;Bregman and Goldberger, 1983a; Martin and Xu, 1988; Xu and Martin,1991; Bates and Stelzner, 1993). In young animals such as rats,fiber growth directly across a lesion in immature CNS that isaccompanied by evidence of functional development and recoveryhas only been demonstrable when the injury has been implantedwith fetal tissue (e.g., Iwashita et al., 1994) or peripheralnerve (e.g., Aguayo et al., 1991; Cheng et al., 1996). In theearly chick embryo, after spinal cord transection, the cord willrecover and grow, with more or less normal locomotor functionwhen adult (Shimizu et al., 1990; Hasan et al., 1993).

In mammals we have shown in vitro that spinal cord from neonatal opossums (Monodelphis domestica) (Treherne et al., 1992;Nicholls and Saunders, 1996) or embryonic rats [embryonic days15-16 (E15-E16)] (Saunders et al., 1992) recovers nerve impulseconduction across a complete spinal lesion 4-5 d after the lesion;this recovery involves growth of neurites across the lesion, atleast some of which are regenerating from damaged axons (Vargaet al., 1995b).

Studies of functional recovery are limited in the in vitro CNS preparation (Varga et al., 1996), because it only survivesfor ~14 d. For longer periods, in any of the known eutherian speciesused for spinal repair experiments, it would be necessary to operatein utero. This problem can be overcome by using a marsupial species.When born, most of their CNS is extremely immature (Saunders etal., 1989; Krause and Saunders, 1994; Saunders, 1997). Termanet al. (1996) and Wang et al. (1996) have shown in the opossum,Didelphis virginiana, that after transection of the thoracic spinalcord in neonates both dorsal spinocerebellar and fasciculus gracilisaxons grow directly through the lesion but not when the animalsare >12 d old. In preliminary studies we have shown that neonatalMonodelphis with spinal cord transections will survive until adulthoodand will show a remarkable degree of normal locomotor function(Saunders et al., 1994, 1995).

Here we have analyzed in detail locomotor behavior of adult Monodelphis that were operated on in the first week of life toproduce a complete spinal cord lesion, compared with control unoperatedanimals. Electrophysiological and morphological studies of thespinal cord in these animals were also made. Complete transectionof the spinal cord in the first week of life in Monodelphis wasfollowed by fiber growth across the lesion, with substantiallynormal development of spinal cord structure, impulse conduction,and locomotor behavior.

  MATERIALS AND METHODS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Breeding and management of Monodelphis
General descriptions of colony management for Monodelphis have been published previously (Fadem et al., 1982; Saunders etal., 1989). The Hobart colony was established from breeding pairstransferred from the colony established in Southampton, UK (Saunderset al., 1989). In the Hobart colony, animals for breeding areheld in pairs in rat boxes made of colored polycarbonate, at anambient temperature of 27°C and a light/dark cycle of 14/10 hr.Females are paired with fertile males for 13 d, after which theyare separated, and the females are provided with plastic nestingboxes placed within the rat boxes and filled with strips of paper.The animals are fed cat food, meat meal, high-protein cereal,Veanavite, and Avi-Drops daily, Whiskettes 4 d per week, bananas3 d per week, and meal worms once a week. Water is provided fromstandard animal bottles ad libitum. Breeding in the animal houseoccurs all year round, although seasonal breeding has been reportedrecently for wild Monodelphis in their normal habitat (Bergalloand Cerqueira, 1994). Litter size is between 3 and 12. The younganimals remain tightly and almost continuously attached to theteats from the day of birth until ~15 d later, after which theybecome detached for increasing periods as they grow older andmore independent. They are weaned at 55-60 d after birth and achievetheir adult body weight of 90-110 gm by ~100 d of age (Fig. 1).

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Figure 1. Left, Adult Monodelphis together with a litter of neonates at P7, which was the age at which most animals were operated on.Adult females weigh ~110 gm. Right, P7 animal at higher magnification;crown-rump length, 15 mm.

Spinal cord operations
These were performed at two ages: neonatal opossums aged postnatal days 4-8 (P4-P8) (Table 1, Fig. 1) and P14-P18 (n = 18).The litter size was generally 6-10. The mothers were anesthetizedwith intraperitoneal sodium pentobarbitone (1 ml/100 gm body weightof 6 mg/ml sodium pentobarbitone); the young animals were givenadditional inhaled Metofane as required. The anesthetized motherwas placed ventral surface upward and covered with sterile drapes,apart from the pouchless area of the anterior abdominal wall towhich the young animals are attached to the mother by her teats.Operations were performed as rapidly as possible, because it wasfound in the early stages of these experiments that many of theyoung animals were eaten by the mother as she recovered from theanesthetic. Shortening the period of anesthesia and feeding themother with meal worms immediately on recovery from anesthesiaallowed an adequate number of the operated young animals to survive.The operation in the neonates consisted of a transverse incisionthrough the skin at the level of T1-T2 followed by either a crushby forceps or a transection made with ophthalmic scissors throughthe skin incision, which aimed to disrupt the whole cross-sectionof the spinal cord via the dorsal surface of the developing vertebralcolumn. Crushes were maintained for 10 sec. The effectivenessof the lesion (crush or cut) was checked in one or more of thefollowing ways.


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Table 1. Summary of spinal cord operations on Monodelphis domestica, indicating postnatal age at operation (day of birth = P0), natureof spinal lesion (crush or cut), and age at time of study

The tips of the forceps or ophthalmic scissors were passed through the site of the lesion viewed under an operating microscopeto check the completeness of the lesion. To confirm the effectivenessof the lesioning technique, some operated young animals, at thetime of operation or 24 hr later, were reanasthetized and exsanguinated,and their cords were either removed for electrical impulse conductionstudies or fixed for histology (see below). This was done in theearly part of the study for some whole litters to check on theconsistency of the lesions. Once the procedure was established,one operated young animal was removed at random, at or shortlyafter operation, for histological examination. All operationswere performed by one person (N.R.S.); the removal of one animalfor morphological evaluation of the lesion was made by someoneelse. In addition, most animals were checked either at the timeof operation or on the following day by a light nociceptive stimulusapplied to the hindlimbs. This usually evoked a local reflex,confined to the lower limbs; providing the lesion was complete,it did not result in any response from the upper limbs or upperpart of the animal above the level of the lesion, in contrastto the controls, which did show such responses. In most cases,all of the young animals in a single litter were operated on;in some cases alternate young animals were operated on. Afterinitial trials, we did not use sham operations involving skinlesions; because the mother tends to remove any kind of mark bylicking the young animal, it is extremely difficult to distinguishoperated from sham-operated animals if both have skin lesions.Attempts to suture the skin wound were counterproductive, becausethe mother almost always removed the suture material. In fact,the wounds healed within 48 hr, generally with limited scarring(as reported previously for this species in the neonatal periodby Armstrong and Ferguson, 1995), and we saw no signs of infectionin any of the operations performed. After operation, some younganimals were examined for electrophysiological conduction of impulsesacross the crush and evidence of histological growth of fibersthrough the crush at periods of 1-2 hr to 3-4 weeks after operation.The remaining animals with crush lesions were observed for behavioralperformance at 1, 2, and 3 weeks after crush and at 3 months aftercrush; some animals at each of these ages were terminally anesthetized,and their spinal cords were fixed for morphological studies (seeTable 1). Ten of the animals with spinal cords that had beencrushed at P7-P8 were maintained until 2-3 years of age and comparedwith five controls. Other animals with spinal cords that had beencut at P4-P6, rather than crushed, were maintained until 2 monthsof age (n = 3 compared with n = 3 controls) or 6 months (n = 3;controls, n = 3; Table 1). Systematic behavioral analysis wasperformed on the adult (crush) and 6 month (cut) animals usingprotocols that included those recommended by the American ParalysisAssociation (1994) as described below. These animals were thenterminally anesthetized, and morphological and/or electrophysiologicalstudies were performed (see below).

Behavioral testing
Some litters and controls were observed two to three times weekly, from shortly after operation until after weaning (~60 dpostnatal). Their general behavior and locomotor abilities werecompared with those of controls of the same age and noted. Videorecordings of their movements were made.
Comprehensive behavioral studies were performed on animals with complete crush or cut lesions of the spinal cord: (1) animalswith spinal cords transected by cutting at P4-P6 were studiedat weaning (2 months) and when they were young adults (6 monthsold); and (2) animals with cords that had been transected completelyby crushing at P7-P8 were studied when adult (2-3 years old).The behavioral studies were performed as follows.
Locomotor abilities were assessed using tests recommended by the American Paralysis Association (1994). These are based onthe detailed descriptions of such tests by Bregman and Goldberger(1983a,b), Goldberger et al. (1990), Kunkel-Bagden and Bregman(1990), and Kunkel-Bagden et al. (1992, 1993).
The range of movements that operated animals were capable of compared with controls was assessed using the tests describedbriefly below. Observers were unaware of the condition of theanimal whose performance they were scoring.
Training. Animals were trained to cross runways and grids and to climb a narrow beam for food reward. Animals were not fedon the day of training or testing and then were rewarded withmeal worms after each trial. After the trial they were fed theirusual meal.
Beam climbing. The animals climbed a narrow circular section beam, which was 1.2 m long, 20 mm in diameter, and placed atan angle of 45° (see Fig. 4). The time it took to climb to thetop and the number of errors made by the right and left hind feetwhile climbing were recorded. Each climb was videotaped, and thiswas used to assess the ability of the animal to perform this task.Each animal climbed the beam 10 times. The means and SEMs forthe time to climb and number of errors for each animal were calculated(see Fig. 5); the means and SEMs for the groups of operated andcontrol animals were also calculated (see Tables 3 and 4).
Grid. Two grid sizes were used. Both grids were 600 mm long but had differing gaps between the bars: 15 and 35 mm. The timetaken to cross the grid and the number of errors made during thecrossing were recorded using a videotape and were analyzed later(see Fig. 4). Each animal traversed each grid 10 times. The meansand SEMs for the time to cross the grid and number of errors foreach animal were calculated (see Fig. 5); the means and SEMs forthe groups of operated and control animals were also calculated(see Tables 3 and 4).
Runway. The runway was 1.2 m long and 60 mm wide with an inkwell at one end and a dark box containing meal worms at the other.The animals' hind feet were inked, and footprints were made ona paper insert on the bottom of the runway. Each animal repeatedeach "run" 10 times. The footprint analysis used was that describedby Kunkel-Bagden and Bregman (1990) and de Medinaceli et al. (1982)(modified) and is summarized below and illustrated in Figure 2.Key results are summarized in Tables 3 and 4.

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Figure 2. Left, Control and operated (crush) animals walking in the runway used for "footprint" analysis. The feet are partly obscuredby the edge of the runway. Walking patterns were quantitativelyassessed by the use of footprint analysis (right), as describedby de Medinacelli et al. (1982) and Kunkel-Bagden and Bregman(1990) and modified as outlined in Materials and Methods. A typicalpattern of hindlimb footprints and the measurements made are illustrated.PL, Print length; TS, toe spread; IT, distance between intermediarytoes; TOF, distance to opposite foot; DBF, base of support; LSL,left stride length (i.e., distance between consecutive left hindfootprints); RSL, right stride length; r, rotation. Results from animalswith crush lesions are summarized in Table 3 and Figure 5, andresults from cut lesions are summarized in Table 4 and Figure5.

Distance to opposite foot (TOF) was measured from the tip of one foot to the tip of the other. Control animals were definedas "normal TOF" (NTOF) and operated as "experimental TOF" (ETOF),The mean TOF for each animal was obtained from the 10 trials.Print length (PL) was measured from the length of the print (NPL,normal PL; EPL, experimental PL), and the mean for each was calculated.Toe spreading (TS) was the distance measurement taken from thefirst to the fifth toe and averaged for normal (NTS) and experimental(ETS) animals. Distance between intermediary toes (IT) was themean distance measured from the second and fourth toes for normal(NIT) and experimental (EIT) animals.
All of these measurements were then used in an equation to give an indication of the overall degree of normal function. Thisis called the sciatic functional index (SFI):

This is an empirically derived formula (de Medinaceli et al., 1982) that assumes that all four tests are equally important;the weighting factor is used to give an average of 100% deficitas a result of total nerve destruction.
Zero percent (±11%) represents normal function; any value below $-$ 11% indicates a loss of function; and $-$ 100% represents atotal loss of function (de Medinaceli et al., 1982).
Kunkel-Bagden and Bregman (1990) devised an additional three measurements as part of the footprint analysis. These were alsoused.
Base of support is the mean measured distance between the central pads of the hind feet. Limb rotation is the mean angle formedby the intersection lines from the left and right prints. Stridelength is the mean distance measured between consecutive printson the same side (left or right).
In addition to the above well established tests for function in animals with spinal cord lesions, we also used swimming teststo obtain information about locomotor performance in the absenceof the normal cutaneous and proprioceptive input from the limbsto the spinal cord, because this has been shown to be importantfor local limb movement rhythm generators in spinal preparations(Grillner and Wallen, 1985; Rossignol, 1996).
Swimming. A tank measuring 1.2 m long and 600 mm wide was used for this test. Individuals swam the tank length seven times,and the mean and SEM for each animal and the group means and SEMswere calculated. One control animal could not be tested, becauseit proved to be a nonswimmer.
Swim plus climb. The same tank was used, without the partition, but an island was placed at one end. Each animal was requiredto swim the length of the tank to the island and climb out ofthe water. The time recorded included the time it took to swimto the island and climb out. Once again individuals swam the tanklength seven times, and the mean and SEM for each animal and thegroup means and SEMs were calculated.
Other tests. Placing, both proprioceptive and contact, and hopping tests were not possible to perform, because no means couldbe found to discourage Monodelphis from holding onto either thehandler's hand or to their own opposite foot instead of to thebench top as required by the test.

Morphological studies
Spinal cords from immature animals were fixed for light microscopy by immersion in Bouin's solution (overnight at room temperature)or in 4% paraformaldehyde in 0.1 M phosphate buffer (PB, pH 7.2)overnight at 4°C before vibratome sectioning (see below). Adultanimals were terminally anesthetized with an intraperitoneal injectionof sodium pentobarbitone (0.1 ml/100 gm body weight of 60 mg/ml)and then perfused immediately via the left ventricle over a 15min period with 200 ml of PB (0.1 M, pH 7.2 at 20°C containing,2000 IU of sodium heparin) followed by 500 ml of 4% paraformaldehydein 0.1 M PB, pH 7.2 at 4°C. After perfusion, the head and spinalcord (enclosed in the skull and vertebra) were separated fromthe animal and post-fixed for 24 hr in the same fixation solution.This was stored at 4°C in PBS (0.1 M, pH 7.2) until further analysis.In some adult preparations the spinal cord was dissected freeof the vertebral column after initial fixation; in others thespinal cord was left in situ, and bone was decalcified using Fastcaldecalcifier (Histo Labs). Bouin's-fixed material was washed brieflyin tap water, dehydrated in graded alcohols, cleared in chloroform,and embedded in paraffin wax. Serial sections of 2-20 µm werecut in either transverse or longitudinal planes. Sections werestained with hematoxylin and eosin or by a silver-staining method(Sievers and Munger, 1965).

Spinal pathways in operated animals
Injection of dextran amines. Previously spinal-operated adult animals were anesthetized with an intramuscular injection ofsodium pentobarbitone (60 mg/ml, 0.175 ml/100 gm body weight).Using a high-speed drill with a small (1-mm-diameter) sterilizeddrill bit, a tiny portion (2 × 1 mm) of the vertebra overlyingthe midline of the spinal cord was exposed at T12, taking carenot to puncture the covering dura. Using a 5 µl syringe (Hamilton)with a glass micropipette attached (tip diameter, 40-50 µm), 1.0-1.4µl of 25% tetramethylrhodamine-labeled dextran amine (Fluororuby,catalog #D-1817; Molecular Probes, Eugene, OR; molecular weight,10,000) in 2.5% (v/v) Triton X-100 diluted in 0.1 M Tris buffer,pH 9.0, was injected directly into the spinal cord. This dye mixturewas injected slowly over ~60 sec. Throughout this procedure noCSF leaked through the dura, and there did not appear to be anysignificant spread of dye out into the subdural space. After injectiona small piece of absorbable gelatin foam (Gelfoam) was placedover the dura before the skin was sutured. Animals were allowedto recover and returned to the colony for 7 d before further study.The animals were then reanasthetized with sodium pentobarbitone(60 mg/ml, 0.1 ml/100 gm body weight) and perfused with 0.1 MPB and 4% paraformaldehyde fixative as described above. Brainsand spinal cords were removed and post-fixed in the same fixativefor at least 24 hr, after which they were embedded in 5% agaroseand cut in either coronal or sagittal planes at 70 µm on a vibratome.Sections were placed in 0.1 M PBS, pH 7.2, mounted onto glassslides in an aqueous mounting medium (Faramount; Dako, High Wycombe,UK), and viewed under a microscope (BX50; Olympus Optical, Tokyo,Japan) with appropriate fluorescence optics.

Electrical recording
To check for the functional completeness of the lesion and to document the recovery of conduction in the first 2-3 weeks afteroperation in vitro, CNS preparations were set up as describedpreviously (Nicholls et al., 1990). The entire CNS was dissectedout from an exsanguinated young animal under ice-cold Eagle'sbasal medium (Life Technologies, Grand Island, NY) bubbled with5% CO₂ in O₂. For electrical stimulation and recording, preparationswere maintained at room temperature, and the brain was removedfrom the preparation at the level of the upper brainstem, andsuction electrodes were applied to each end of the spinal cord.The rostral electrode was used for stimulation, and the caudalend was used for recording. Chlorided silver wires were placedin the bath as indifferent electrodes. Signals were amplifiedwith a differential amplifier (AC3; Almost Perfect Electronics,Basel, Switzerland) displayed on a storage oscilloscope and recordedon paper. When recordings were made from injured preparations,the electrodes were positioned with one above and one below thecrush site at distances of several millimeters relative to thecrush. For testing the survival and viability of crushed preparations,recordings were made at different positions along the cord withboth electrodes either above or below the site of the crush.
In the adult control animals and those that had been operated on in the neonatal period (see above), to test for conductionthrough the crush site and in controls at the same spinal cordlevel, stimuli were applied to the sciatic nerve by hook electrodes(6 V, 0.1 msec, 1/sec). Recordings were made from spinal cordat the level of C2-C3 after a laminectomy and from the surfaceof the parietal cortex after the skull and dura mater had beenremoved. The recording electrode consisted of a silver wire (500µm in diameter) sealed into the tip of a microelectrode with epoxy.The electrode tip was ground on a fine stone until the wire, theepoxy, and the glass formed a smooth surface that made excellentelectrical contact with CNS tissue. The indifferent electrodewas placed in contact with tissue close to the recording electrode.Signals were amplified on a preamplifier (Almost Perfect Electronics)with filters set at 30 Hz and 10 kHz. Signals, which were largeenough to observe on single sweeps, were averaged on a MacLabcomputer (Macintosh Classic II computer with MacLab Mark III attached).Routinely 32, 64, or 128 evoked potentials were averaged. In someexperiments the polarity was reversed halfway through the run.Stimuli were also applied to the cerebral cortex or spinal cordwhile recording from the sciatic nerve. Recordings remained stablefor many hours and were remarkably reproducible from preparationto preparation.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Effectiveness of the lesion

A preliminary series of operations was performed to establish an effective crush technique that severed the spinal cord ofneonates completely. Electrophysiological evidence for the effectivenessof the lesion was obtained by using stimulating and recordingsuction electrodes attached to the ends of the isolated cord,as described in Materials and Methods. In 11 operated (crush)cords tested for nerve impulse conduction across the lesion at0-24 hr postoperatively (Table 2), nine showed no evidence ofconduction; in the other two cords, which were tested at the beginningof the series, there were only tiny action potentials (i.e., clearlydistinct from background noise), compared with the much largeramplitude of those recorded with both stimulating and recordingelectrodes rostral to the lesion. Morphological examination (seebelow) was performed in six of these preparations. All six spinalcords showed apparently complete disruption at the site of thelesion (Fig. 3); i.e., as far as could be detected in microscopicalexamination of serial sections through the lesions, no continuityof cord structure could be detected. As a control of the effectivenessof the crush (or cut) procedure in later experiments, one animalwas selected randomly from the operated litter by someone otherthan the operator; this neonate was terminally anesthetized, exsanguinated,and examined morphologically for evidence of the effectivenessof the crush or cut. As a further check on the crush procedureall six neonates in one litter were prepared for morphologicalexamination shortly after operation. All these animals were foundto have complete spinal cord lesions (Fig. 3). All cut spinalcords showed complete separation of the two ends of the spinalcord (Fig. 3).


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Table 2. Conduction of action potentials across crush lesion of spinal cord at different times after making the lesion in postnatalanimals aged P5-P8

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Figure 3. Typical examples of spinal cord lesions made in neonatal Monodelphis. These sections were prepared from animals that wereterminally anesthetized within 1 hr (a-c, e) or 24 hr (d) of operation,and their spinal cords were removed for morphological examinationas described in Materials and Methods. a, Low-power magnificationof sagittal section of a P6 Monodelphis with a crush lesion ofthe spinal cord. The lesion is shown at higher magnification inc. Note that not only was the spinal cord lesion complete, butthe crush was sufficiently deep to also disrupt the vertebralbody at the level of the lesion [arrow in a; and note disruptedvertebral body (v) in c]. This was apparent in many of the crushesexamined histologically. e, Low-power sagittal section of a P7Monodelphis with the cord transected by a cut. The lesion is illustratedat higher magnification in b. d, Crush lesion 24 hr after operation.Scale bars: a, e, 1 mm; b, 100 µm; b-d are at same magnification.

Behavioral studies

The American Paralysis Association (1994) recommends using multiple sensitive quantitative methods when the recovery of sensoryfunction and motor behavior of specific body parts can be assessed.The results of the tests are summarized in Tables 3 and 4; someof the individual tests are illustrated in Figures 2 and 4. Figure2 shows consecutive frames from a video recording of an operatedanimal and a control animal while walking in the runway used forfootprint analysis. In general, operated animals walked normallyand without apparent difficulty, although minor abnormalitiesin gait were noticeable in some animals. When present these tookthe form of a tendency to higher stepping than seen in controlsand a rolling movement of the pelvis. None of the animals operatedat P14-P18 (n = 18) survived for more than a few days; all wereeaten by the mother.


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Table 3. Summary of quantitative data from behavioral testing of Monodelphis with spinal cords that had been completely transectedby crushing at P7-P8 (n = 10) compared with unoperated controls(n = 4-5)


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Table 4. Summary of quantitative data from behavioral testing of 6-month-old Monodelphis with spinal cords that had been transectedcompletely by cutting at P4 (n = 3) compared with unoperated controlsof the same age (n = 3)

Behavior of adult animals with spinal cord lesions (crush) made at P7-P8

Systematic behavioral tests were performed in 10 adult animals with spinal cords that had been crushed at P7-P8. These werecompared with five adult controls.

Beam climbing
Animals climbing the beam are illustrated in Figure 4. Results from individual animals are shown in Figure 5, and mean valuesfor operated and control animals are given in the legend to Figure5. Any apparent differences were not statistically significant(Fig. 5 legend). Even after training each animal seemed to havea different way of climbing the beam; e.g., some "hugged" thebeam, and others ran up it. Most of them seemed to make good useof their prehensile tail by wrapping it around the beam. Thismade it difficult to quantify the number of errors that the animalsmade. Kunkel-Bagden et al. (1993) found that rats also differin their methods of climbing a beam and concluded that the abilityto do so is dependent on the method of an individual and doesnot reflect the severity of the spinal injury. The range of individualperformance in this test is shown in Figure 5.

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Figure 4. a, Consecutive frames taken from video recordings of climbing in an adult Monodelphis with spinal cord that had been crushedcompletely at P7 (operated) compared with an unoperated (control)adult. As described in Materials and Methods the animals climbeda narrow beam inclined at ~45° to the horizontal. The time takento climb and the number of errors made were recorded. b, Consecutiveframes taken from video recordings of crossing a 1.5 cm grid inan adult Monodelphis with spinal cord that had been crushed completelyat P7 (operated) compared with an unoperated control adult. Asdescribed in Materials and Methods the animals crossed a gridwith bars 1.5 cm apart. The time taken to climb and the numberof errors made were recorded (Fig. 5, Tables 3, 4) for the quantitativeresults of both tests). c, Consecutive frames taken from videorecordings of swimming in an adult Monodelphis with spinal cordthat had been completely crushed at P7 (operated) compared withan unoperated (control) adult. As described in Materials and Methods,animals made seven timed swims in a 1.2 m tank (Fig. 5, Tables3, 4).

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Figure 5. Quantitative results from three of the behavioral tests made in adult animals with spinal cords that been crushed at P7 (leftpanels) or cut at P4 (right panels) and examined at 6 months ofage. Top graphs, Comparison of individual control (open bars)and operated (filled bars) animals in the beam-climbing test (timetaken and number of errors); middle panels, crossing the 1.5 cmgrid (time taken and number of errors); bottom panels, Resultsof the swimming test (time taken to complete distance). Meansfrom 10 trials (7 for swimming test) are shown; error bars indicate1 SEM; where no bar is shown it was too small to be visible. Themean time for all animals with crush lesions to climb the narrowbeam was 9.4 ± 2.4 sec, and it was 8.6 ± 0.6 sec in the controls(NS). The mean swimming time for animals with crush lesions was4,5 ± 0.3 sec, and it was 4.3 ± 0.4 sec in the controls (NS).For the animals with cut lesions in the swimming test, the meantime for the controls was 2.7 ± 0.2 sec, and for the operatedanimals it was 5.3 ± 1.2 sec (NS). *Section of spinal cord fromthis animal are shown in Figure 8f; also compare Figure 6, SFI.Sections of spinal cord from this animal are shown in Figure 8a.Note that for the tests on the animals with crush lesions, fourcontrols were used except in the swimming test, in which n = 3,because one of the controls was unable to swim.

Grid
Examples of video frames from this test are shown in Figure 4. There was no significant difference between the control andexperimental animals in how long it took to cross either sizeof grid (Table 3) or in the number of mistakes (footfalls throughthe grid) (Table 3) made in either of the grid sizes. However,in the case of the operated animals, there was a significant difference(p < 0.002) in the number of errors made by the hindlimbs comparedwith the forelimbs; such a difference was not present in the controls(Table 3); this suggests a minor degree of impairment in thelesioned animals. The range of individual performance by all operatedand control animals is illustrated in Figure 5.

Runway
The analysis obtained from footprints (Fig. 2) allowed us to determine the pattern of locomotion for each individual operatedand control animal.
From the results of previous studies in rodents we expected to see a decrease in all of the measurements obtained with theexception of the base of support, which increases in animals withspinal cord lesions (Kunkel-Bagden et al., 1993; Bregman et al.,1993). In our experiments there were small decreases in all ofthe parameters measured, which unexpectedly included a decreasein the base of support rather than an increase (Table 3). However,in only two of the seven components analyzed in the footprintstudies were any of the small differences between control andoperated animals statistically significant (Table 3). These wereprint length (p < 0.005) and toe spread (p < 0.05). Both of thesemeasurements were shorter in the operated animals than in thecontrols, and this may indicate that the experimental animalstended to walk on their toes rather than on the whole length ofthe foot. The mean values for rotation, distance to opposite foot,and distance between intermediary toes (see Materials and Methods)were not significantly different between control and crushed animals,and they are not included in Table 3.
As indicated in Materials and Methods, the originally described components of footprint analysis can be used to compute anoverall indicator of performance called the SFI. The SFI calculatedfrom our results indicates that all animals except one were withinthe range of 0 ± 11% (±11% indicates the range of normality forthe SFI; it is not the SEM; see Materials and Methods) (Fig. 6)and were therefore normal with respect to this battery of tests.The one individual that was outside of the normal range was onlymarginally so, with an SFI of $-$ 13.1%. A section from the spinalcord of this animal is illustrated (see Fig. 8f).

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Figure 6. Results from calculation of SFI. The SFI is an estimate of locomotor ability calculated from measurements made in footprintanalysis (Fig. 2; see Materials and Methods). The index is consideredto be within normal limits if it is within 11% (note that thisis not an SEM) on either side of the control mean. Open circlesare mean values for individual animals from 10 trials in adultswith spinal cords that had been crushed at P7-P8; filled circlesare means of 10 trials for animals with spinal cords cut at P4.Error bars indicate 1 SEM. Mean values for each operated group(n = 10 for crush, n = 3 for cut) are shown by arrows at right;the filled arrow is for cut data, and the open arrow is for crushdata. Note that only one animal (with a crush lesion) falls outsideof the normal range. The histological appearance of its spinalcord is shown in Figure 8f.

Swimming, swim plus climb
Examples of control and operated animals performing this test are illustrated in Figure 4c. Results for individual animalsare shown in Figure 5. The mean swimming time for animals withcrush lesions was 4.5 ± 0.3 sec, and it was 4.3 ± 0.4 sec in thecontrols (not significantly different).
There was no measurable time difference between the control and the experimental animals for the swim plus climb test (Table3).

Behavior of animals 2-6 months after spinal transection (cut)

Some animals (n = 19 from 12 litters) were subjected to cut lesions of the spinal cord at P4-P7. Thirteen of these animalswere terminally anesthetized, and their spinal cords were removedfor morphological examination. All cords were severed completely(e.g., Fig. 3). The behavior of groups of the remaining animalswas observed, and they were then killed by an overdose of anesthetic,after which their spinal cords were removed for morphologicalexamination (2 months, n = 3; 6 months, n = 3). At 3-4 weeks afteroperation these animals could walk with apparent coordinationof forelimbs and hindlimbs, but in contrast to control littermatesthey could not right themselves from a supine to a prone position.However, by 2 months after cutting the animals could walk andrun in an apparently normal manner, and they could also rightthemselves from being placed on their backs. Animals at 6 monthsafter cutting were given the same battery of behavioral testsused for the adult animals with crush lesions (for details ofthe tests, see above and Materials and Methods). The results obtainedfrom the behavioral testing of these animals are summarized inTable 4. Results from individual animals for several of the testsare shown in Figure 5. As was the case for the older animals withcrush lesions (Table 3), many of the differences between controland cut animals were not significantly different; most have thereforenot been included in Table 4. There were no significant differencesbetween the control and cut groups in the runway, swimming, andswim plus climb tests (Table 4 and legend to Fig. 5); the SFI(Fig. 6) was within the normal range of 0 ± 11% for all threeoperated animals. However, there were significant differencesin the time taken to climb the narrow beam and to cross both the1.5 and 3.5 cm grids. As was the case for the animals with crushlesions, the Monodelphis with spinal cords that had been cut showedsignificant differences in grid-crossing performance when errorsfor hindlimbs and forelimbs were compared, but importantly, theoperated individuals could still perform these tasks althoughnot quite as rapidly as the controls. In fact these operated (cut)animals performed as well as the animals with crushed spinal cords,and the differences between operated and controls in the cut groupof animals were mainly attributable to the fact that the controlsin this group were faster than the controls for the crushed group(compare Tables 3, 4). This was presumably a function of thedifference in age of the two groups of animals; i.e., the younger(6 months) controls were faster and less inclined to make mistakesthan the older (2-3 years) controls.

Morphology of spinal cord lesions at 3 months after crush

At 3 months of age the cross-sectional appearance of the control spinal cords (n = 3) resembled that of the adult (compareFigs. 7a, 8a). In eight animals subjected to complete transectionof the cord by crushing at 1 week of age, by 3 months the normalstructure of the cord was largely restored, as illustrated inFigure 7, which shows low-power views of transverse or longitudinalsections of the spinal cord from three operated animals and twocontrols. Two of the cords that had been crushed appear normal(Fig. 7c,e). The other operated cord has an obvious deficit (Fig.7b, arrow) but otherwise appears normal. It is noteworthy thatin longitudinal sections through the region of the crush the structureof the cord appeared normal (Fig. 7e).

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Figure 7. Transverse (a-c) and longitudinal (horizontal) (d, e) silver-stained sections of spinal cords of 3-month-old Monodelphis atthe level of a complete crush lesion made at P7-P8. a, From anunoperated control. In one animal (b) some deficit in the cross-sectionalarea was apparent (arrow). Otherwise the structure looked remarkablynormal. Scale bar for a-c, 0.5 mm. d, From a control; e, froman operated (crush) animal. For these longitudinal sections, therostral end of the spinal cord is at top. Scale bar for d, e,1 mm. Lesions were made at T1-T2.

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Figure 8. Transverse [a, (i)-(iii)] and longitudinal (b-f) silver-stained sections from the spinal cord of adult Monodelphis that hadbeen completely transected by a crush at P7. a, (i)-(iii) arefrom the same animal. (i), Rostral to the site of the lesion.(ii), At the level of the lesion (note the structural deficitindicated by the arrow). (iii), Caudal to the site of the lesion.Scale bar in (iii), 0.5 mm; (i) and (ii) are at same scale. Behavioraldata for this animal are shown in Figure 5 (). b-f, Longitudinal sections of one control (b) and four operated(c-f) spinal cords of adult Monodelphis that were subjected tocomplete crushing of the cord (T1-T2) at P7-P8. In f there isan obvious deficit (arrow) in the gross structure, which correlatedwith a greater degree of impaired function on behavioral testing(this is the spinal cord from the only animal with a sciatic functionindex that was outside of the normal limits (Fig. 6). Scale barin f, 1 mm; b-e are at same scale.

Morphology of spinal cord in adult opossums after crushing at P7-P8

Eight adult animals with cords that had been crushed at P7-P8 were examined in serial sections (transverse or longitudinal)stained with silver; they showed substantially normal gross structure.Figure 8a shows the appearance of one of the adult crushed spinalcords in transverse sections above, at, and below the site ofthe lesion. As was the case for crushed cords at 3 months afteroperation, in these older animals in most cases the gross appearanceof the cord appeared normal, although two cords (one illustratedin Fig. 8a) showed a partial deficit, as was observed in the youngeranimals with cords that had been crushed (compare Figs. 7b, 8a).Figure 8 also shows longitudinal sections (cut serially from dorsalto ventral surfaces) from one control (Fig. 8b) and from fourspinal cords that had been crushed at P7-P8 (Fig. 8c-f). One ofthese (Fig. 8f) showed a partial deficit. This animal was theonly one with an abnormal SFI (Fig. 6).

The longitudinal sections show clearly that numerous nerve fibers (including many myelinated fibers) extended in well organizedtracts, which spanned the length of the cord examined, includingthe site of the original lesion. At higher magnification in transversesections there were mature-looking anterior horn cells with motoraxons extending to form the ventral roots leaving the cord (resultsnot shown).

Morphology of spinal cord after cut lesions

The spinal cords of animals that had been transected completely by cutting and were examined morphologically at 2 months (resultsnot shown) or 6 months (Fig. 9) after the operation showed moreobvious deficits in gross structure than the cords of 3 monthor adult animals with crush lesions made in the neonatal period(compare Figs. 7, 8, 9). In the animals with cords that had beencut, the cord was clearly thinned at the site of the originallesion, as illustrated in Figure 9. The appearance of the spinalcord lesion sites in the three animals studied at 2 months aftercutting was similar.

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Figure 9. Longitudinal sections of two 6-month-old Monodelphis with spinal cords that had been transected completely by a cut (T1-T2)at P4. Note the considerable narrowing of the spinal cords atthe site of the lesion; there is an artifactual break in sectionb. Numerous nerve fibers cross the site of the original lesion.Scale bar, 1 mm.

Conduction through lesioned spinal cord

To test for restoration of conduction after recovery and growth to adulthood, stimuli were applied to five animals 2-3 yearsafter the spinal cord had been crushed and to three controls ofsimilar age. The operated and control animals had been testedbehaviorally before the experiment. The records of Figure 10 showvolleys recorded in the spinal cord above the lesion and in thecerebral cortex after stimulation of the sciatic nerve. The recordingelectrode was moved over the exposed cortical surface to obtaina maximal signal amplitude. The traces were very similar in operatedanimals and in controls. Differences such as those that occurredcould be attributed to slight variations in the placement of therecording electrode; movements of 1-2 mm produced, as expected,changes in amplitude and configuration. Similar traces were recordedfrom the sciatic nerve when stimuli were applied to the cortexor the spinal cord above the lesion (data not shown). Acute transectionof the cord rostral or caudal to the chronic lesion abolishedall conduction of signals such as those shown in Figure 10.

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Figure 10. Electrophysiological recordings in an anesthetized adult Monodelphis with spinal cord crush made at P7 (C, D) compared withan anesthetized control adult (A, B). Recording conditions wereas described in Materials and Methods. In A and C the stimulatingelectrodes were placed on the sciatic nerve with recording electrodeson the spinal cord. In B and D the recording electrodes were movedto the sensory cortex. Similar records were obtained in all fiveoperated and three control (unoperated) animals that were testedfor impulse conduction across the site of the crush lesion.

Neural pathways in adults across the site of a cord lesion made at P5-P7

To obtain morphological evidence of the contribution of supraspinal neurons to the population of fibers crossing the siteof the lesion, pathway-labeling experiments using dextran aminewere performed in animals with spinal cords that had been lesionedin the first week of life. Four animals with spinal cords thathad been crushed or cut in the neonatal period were reanesthetizedand received injections into the spinal cord of dextran amine,as described in Materials and Methods; two control animals wereused for comparison. Seven days after an injection distal to thesite of the lesion, the animals were terminally anesthetized,and brains and spinal cords were fixed. The distribution of fluorescent-labeledneurons was mapped in serial sagittal sections through brain stemand midbrain as described in Materials and Methods. Figure 11 showscomposite camera lucida drawings obtained from the serial sectionsfrom a control animal and an operated animal. Several clearlydelineated nuclei could be seen (Fig. 11). As shown in Figure 11,regions with neurons retrogradely labeled with dextran amine-Fluororubyincluded midbrain central gray, nucleus Darkschewitsch, dorsalmedullary reticular field, Edinger Westphal nucleus, gigantocellularreticular nucleus, intermediate medullary reticular field, interstitialnucleus of the medial longitudinal fasciculus, locus coeruleus,lateral tegmental area, lateral vestibular nucleus, raphe magnus,red nucleus, and the ventral medullary reticular nucleus. Themicrograph in Figure 11, inset, shows an example of the appearanceof retrogradely labeled neurons, in this case in the lateral vestibularnucleus.

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Figure 11. Spaced serial coronal sections showing the location of brainstem and midbrain neurons retrogradely labeled after injectionof Fluororuby dextran amine into the lumbar spinal cord of adultMonodelphis. The series on the left is from an animal in whichthe spinal cord was crushed on P7; on the right is an unoperatedcontrol. Inset, Micrographs show retrogradely labeled neuronalsomata in the lateral vestibular nucleus (LV). Magnification,5 × bar). CG, Midbrain central gray; DK, nucleus Darkschewitsch;DR, dorsal medullary reticular field; EW, Edinger Westphal nucleus;GR, gigantocellular reticular nucleus; IR, intermediate medullaryreticular field; IN, interstitial nucleus of the medial longitudinalfasciculus; LC, locus coeruleus; LT, lateral tegmental area; RM,raphe magnus; RN, red nucleus; VR, ventral medullary reticularnucleus.

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Morphology and functional recovery of adult spinal cord lesioned at P4-P8

In most 3-month-old and adult animals with spinal cords that had been completely crushed when newborn, the gross structureof the spinal cord appeared remarkably normal. A few had an obviousdefect at the lesion site (Figs. 7b, 8a,f, arrows). In only twocomponents of the runway test were there statistically significantdifferences between the control and operated animals; the overwhelmingimpression was that these animals were nearly normal (Table 3).Only one showed any visually obvious or statistically significantbehavioral deficits that correlated with a structural deficit(compare Figs. 6, 8f). Electrophysiological testing of the animalsgave clear evidence of impulse conduction in both directions acrossthe lesion (Fig. 10). This, coupled with evidence from dextranamine pathway-tracing experiments (Fig. 11 and next section), indicatesthat the morphological repair at the site of the injury was accompaniedby significant functional recovery that involved development ofsupraspinal connections.

Neonates with cut lesions of the spinal cord (Fig. 9), showed less morphological recovery and growth of the cord and moreimpaired behavior than after crushing (Figs. 7, 8). This is hardlysurprising, because the pia mater, which normally provides a pathwayfor growth, has been severed (Varga et al., 1996); moreover, agreater separation occurs between the two segments of spinal cordafter a cut. The principal reason for making cuts in additionto crushes was to establish unequivocally the completeness oftransection of all fibers. Most of our studies involved crushes,because there is a greater delay in outgrowth of fibers aftercutting; this is more complex to analyze, because the abilityof the spinal cord to support the outgrowth of new axons declineswith age (see Varga et al., 1995a).

Recovery occurred in animals with both types of lesion without implants of fetal spinal cord, as used in neonatal rats (e.g.,Bregman et al., 1993; Iwashita et al., 1994). The latter studyis one of the few in which substantial functional recovery wasreported after a complete lesion of the spinal cord; however,their data are insufficiently comprehensive or quantitativelydescribed for it to be clear how well these neonatal rats comparewith our neonatal opossums. In our study, presumably because ofthe greater immaturity of the opossum neonatal spinal cord comparedwith that of the neonatal rat, recovery and growth occurred withoutany fetal implant. Miya et al. (1997) published a more detailedreport of similar experiments in neonatal rats and found thatthere were greater behavioral differences between control andoperated animals when adult than in our studies of the opossum.Also in their rat studies, the morphological repair appears tohave been both less substantial and more variable.

A preliminary report of the structure of the spinal cord of Monodelphis at P3-P8 has been published (Møllgård et al., 1994).A more detailed description is in preparation (G. W. Knott andP. Kitchener, unpublished data). From these studies it is clearthat the stage of development of the P4-P8 Monodelphis cord issimilar to the E12-E13 chick embryo spinal cord (see Hasan etal., 1993), although the developmental timetable seems to be appreciablyfaster in the chick.

New growth and regeneration

Injection of dextran amine caudal to the lesion with subsequent examination of brainstem and midbrain (Fig. 11) in four lesionedanimals compared with two controls revealed retrogradely labeledneurons in many nuclei shown previously to project to the spinalcord in Monodelphis (Holst et al., 1991; Wang et al., 1992). Developmentof descending projections to the spinal cord by retrograde tracingusing fast blue injections into cervical or lumbar regions hasbeen described by Wang et al. (1992). All major brainstem andmidbrain nuclei that make descending projections in the adult(including medullary and pontine reticular nuclei, lateral, medial,and inferior vestibular nuclei, the locus coeruleus, and the rednucleus) were labeled by both cervical and lumbar injections inP7 pups (some were labeled as early as P0). In contrast, the corticospinaland colliculospinal projections were not labeled retrogradelyby cervical or lumbar injections made at P14 or earlier. Thisindicates that the red nucleus and brainstem nuclei have madesubstantial projections, even as far as lumbar segments, by thetime we made spinal lesions (P7), but colliculospinal and corticospinalprojections have not yet reached the spinal cord at this time.However, the possibility that some descending projections frombrainstem and the red nucleus are also made after P7 cannot beruled out. Consequently, any fiber growth across the site of thelesion is likely to have been a mixture of regeneration from injuredaxons and growth of new axons that were not present at that levelof the spinal cord at the time of making the lesion.

Martin and colleagues have obtained evidence similar to that presented in this paper for growth of axons across a spinal cordlesion made in the early neonatal period in Didelphis (Termanet al., 1996; Wang et al., 1996, 1997), but they were also notable to distinguish between regeneration and growth of new fibers.By direct visualization of injured axons in isolated neonatalMonodelphis CNS preparations, Varga et al. (1995b) were able todemonstrate regeneration of dorsal root fibers and axons in ventralspinal cord tracts. From double-labeling studies after spinallesions in chick embryos (Hasan et al., 1993), neonatal opossums(Xu and Martin, 1991), and neonatal rats with implanted fetalCNS (Bernstein-Goral and Bregman, 1993), it was concluded thatfiber growth across the lesion was a mixture of new fibers andregeneration. In our studies it is also likely that new growthand regrowth combined to produce a spinal cord that appeared normalat the site of the lesion, particularly after crushing at P7-P8.

Mechanism of functional recovery after a complete spinal cord lesion at P4-P8

Adult mammals with complete spinal transections do not show any signs of anatomical or functional repair of the lesion; however,they can, if adequate balance is maintained, walk unsupportedon treadmills; they can also compensate for treadmill speed changesand perturbations in the ground over which they walk (see Grillnerand Wallen, 1985). Thus lumbar spinal cord and afferent inputscan act as a locomotor system independent of supraspinal control.In the interpretation of our behavioral data on neonatally lesionedMonodelphis, the argument could be made that the lumbar spinalcord, isolated from the rest of the nervous system from P4-8 bythe cut or crush lesions, may function as an independent locomotorsystem. Our observations of swimming, climbing, and grid crossingin adults lesioned at P4-P8 suggest that supraspinal mechanismsmust be involved in these movements; thus in our experiments thehindlimbs were activated to produce locomotion, which itself requiresintact spinocerebellar ascending connections and intact rubrospinal,reticulospinal, and vestibulospinal tracts (Arshavsky et al.,1983); climbing would have required both interlimb coordinationand intact vestibulospinal tracts. This interpretation of thebehavioral observations is supported by the results of the electrophysiological(Fig. 10) and dextran amine pathway-tracing experiments (Fig. 11).

We were unsuccessful in establishing an upper limit to the period when fiber growth still follows injury in postnatal Monodelphisin vivo. This was because of extensive cannibalism by the mothers.In this respect, Didelphis may be a more favorable model, becausethe young are protected by the pouch in contrast to the vulnerabilityof the young of the pouchless Monodelphis. However, it is clearfrom the in vitro (Varga et al., 1995a) and in vivo (MacLarenand Taylor, 1995) experiments with Monodelphis, as well as inthe in vivo studies in Didelphis (Terman et al., 1996; Wang etal., 1996), that in our animals a marked decline in fiber outgrowthafter a spinal cord lesion would be expected to occur in lesionsof the upper thoracic cord made after ~P12-P14.

Establishment of functionally effective connections

We have not in this study attempted to answer the question of whether the connections made by axons that have grown throughthe lesion are normal or whether the animals cope with abnormalconnections by learning how to use them. Interspecies comparisonssuggest that the processes of fiber growth after injury and reachingappropriate targets may be evolutionarily separable; this is suggestedby work of Beazley et al. (1997), which showed that after lesioningof the optic nerve in lizards, although regenerating fibers crossedthe lesion, unlike in amphibians, the fibers failed to find functionallyeffective targets. Thus if it can be shown in Monodelphis in vivothat fibers growing through a lesion are able to reach normaltargets, then this species will be invaluable for studying thatprocess in addition to providing a model for fiber growth acrossa lesion in the spinal cord. An indication that this is so comesfrom recent in vitro Monodelphis studies showing that regeneratingdorsal root axons grow toward and terminate on motoneurons (M.Lepre and J. G. Nicholls, unpublished results).

Implications for spinal repair in adults

It is likely that changes in the spinal cord between an early developmental stage when fiber growth and functional recoveryoccur and the stage when this does not happen are complex (cf.Fawcett, 1992). In vitro studies (Varga et al., 1995a,b) suggestthat onset of expression of inhibitory factors described by Schwaband Bartholdi (1996) and Keirstead et al. (1992) in other speciesoccurs at P12-P14 in the lower cervical region of the cord ofMonodelphis. Morphological, including immunocytochemical, studiesof the developing spinal cord of this species confirm that oligodendrogliahave appeared by this age (Møllgård et al., 1994; Varga et al.,1995a). However, there are likely to be other factors that areexpressed and still others that are downregulated as part of normaldevelopment that are influencing the capacity of the injured immaturespinal cord to repair itself and to develop normally. An importantquestion is to what extent these changes can be identified, andif they are so identified, whether they can be re-expressed orin the case of inhibitory influences downregulated in the injuredadult spinal cord, so that some degree of repair might then occur.

  FOOTNOTES

Received Aug. 27, 1997; revised Oct. 9, 1997; accepted Oct. 15, 1997.

This work was supported by grants from the Australian Research Council and Workers Accident Compensation Board to N.R.S.,the Motor Accident Insurance Board to N.R.S., K.M.D., P.K., andG.W.K., and the Swiss National Research Fund and the Institutefor Research in Paraplegia to J.G.N.
Correspondence should be addressed to Prof. N. R. Saunders, Division of Anatomy and Physiology, University of Tasmania, G.P.O.Box 252-24, Hobart, Tasmania 7001, Australia.

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Results
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