A Focal Zone of Thalamic Plasticity

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The Journal of Neuroscience, January 1, 1998, 18(1):548-558

A Focal Zone of Thalamic Plasticity
Jayson L. Parker¹^,³, Michael L. Wood², and Jonathan O. Dostrovsky¹
Departments of ¹ Physiology and ² Medical Imaging, University of Toronto, Toronto, Ontario, Canada M5S-1A8, and ³ Cognitive Neurology Unit, Sunnybrook Hospital, Toronto, Ontario, Canada M4N-3M5

  ABSTRACT

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

In this study, sensory maps in the thalamus were investigated by examining their volume and shape. We determined the forelimbrepresentation in adult rats after the removal of hindlimb inputby nucleus gracilis lesions. Three-dimensional reconstructionsof thalamic sensory maps were obtained from a grid of electrodepenetrations. We found that the volume of the shoulder sensorymap contracted >50% at an acute time interval (n = 6), followedby a robust volumetric sensory map expansion of 25% at 1 week(n = 8) and 1 month (n = 8) after lesion relative to controls(n = 8). The topology of the volumetric increase was scrutinizedby slicing functional maps in the coronal, sagittal, and horizontalplanes. The equivalence of such slices from each animal was establishedby virtue of their distance from either a functional or neuroanatomicallandmark. Surprisingly, all of the volumetric increase unequivocallyoccurred in a circumscribed coronal slice 300 µm thick. This focalzone was located toward the rostral pole of the thalamic tactilerelay, the ventroposterolateral nucleus. Analysis in the sagittalplane revealed that, unexpectedly, the shoulder map volume expandedby superimposing its representation on that of the forepaw, viaan advancement of the shoulder representation by 0.6 mm medially.We propose a "hot spot" hypothesis in which focal zones of plasticitymay not be specific to the thalamus but may have manifestationselsewhere in the nervous system, such as the cerebral cortex ordorsal column nuclei.

Key words: hot spot; plasticity; thalamus; receptive field; VPL; somatotopy; lemniscal; nucleus gracilis; visualization; topographic overlap; focal zone

  INTRODUCTION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Plasticity of sensory maps in adult animals was first reported at the thalamic level (Nakahama et al., 1966; Wall and Egger,1971; Fadiga et al., 1978; Pollin and Albe-Fessard, 1979). Plasticityof somatotopic maps has subsequently been discovered at otherlevels of the neuraxis in adult animals. With respect to cutaneouspathways, plasticity in somatotopic maps has been demonstratedin the dorsal horn (Basbaum and Wall, 1976; Devor and Wall, 1978),dorsal column nuclei (Dostrovsky et al., 1976; Millar et al.,1976), cerebral cortex (Kalaska and Pomeranz, 1979; Merzenichet al., 1983), and the ventroposteromedial nucleus (Rhoades etal., 1987; Nicolelis et al., 1993). The principle that has emergedfrom this research is that once a brain region is denervated,adjacent representations expand into the deafferented zone.

In our view, thalamic sensory map plasticity is difficult to detect reliably and has remained polemical. A report of thalamicplasticity by Wall and Egger (1971) has been questioned, in partbecause of the sparse data presentation given in the paper (Snowand Wilson, 1991; Jaine et al., 1995) and the small magnitudeof the forelimb border shift relative to the spacing of electrodepenetrations.

Various laboratories have investigated thalamic plasticity after either deafferentation or the reversible blockade of a receptivefield and have examined the consequences with a manifold of dependentmeasures (Nakahama et al., 1966; Fadiga et al., 1978; Pollin andAlbe-Fessard, 1979; Garraghty and Kaas, 1991; Shin et al., 1995;Alloway and Aaron, 1996; Rasmusson, 1996a). Comparisons of mapborder relationships between control and lesioned animals havebeen difficult, given the three-dimensional (3-D) character ofthalamic sensory maps (Pollin and Albe-Fessard, 1979). The proportionof neurons reported to respond to new input after blockade oftheir original receptive field has ranged from 15 to 70% (Nakahamaet al., 1966; Fadiga et al., 1978; Shin et al., 1995; Allowayand Aaron, 1996). Such variation makes it difficult to use thisplasticity as a baseline in which to test hypotheses relatingto its mechanism or role in nervous system function.

In this study we have used a protocol that quantifies thalamic plasticity based on a single measure: the volume of somatosensorythalamus responsive to a given body region. It is assumed thatincreased volume of a thalamic sensory map corresponding to aspecific body region, in lesioned animals relative to controls,reflects a change in the receptive field of the neurons sampled.Following the method of Wall and Egger (1971), hindlimb inputwas removed with lesions of nucleus gracilis. Histology was usedto verify electrode placements and to obtain length estimatesof certain thalamic nuclei. All volumetric estimates and cross-sectionalanalysis were performed on a computer displaying the three-dimensionaldistribution of recording sites for each body region throughoutthe ventroposterolateral nucleus (VPL).

We asked whether the forelimb, composed of shoulder and forepaw sensory maps, would increase in volume after nucleus gracilislesions compared with intact controls at various times after lesion.Second, we asked whether our 3-D reconstructions of thalamic sensorymaps would reveal any characteristic topological feature behindthe volumetric expansion of the forelimb representation. Comparisonsof shape were obtained by sectioning functional maps in each planeand comparing the profile of their cross-sectional area.

A preliminary form of these results has been presented (Parker and Dostrovsky, 1996).

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Subjects and anesthesia. Thirty male Wistar rats with weights ranging from 250 to 350 gm were used. Four groups of rats weremapped at various times after nucleus gracilis lesions: unoperatedcontrols (n = 8), acute group (n = 6), 1 week after lesion (n= 8), and 1 month after lesion (n = 8). Rats in the acute groupwere mapped immediately after their gracile lesion, without recoveryfrom anesthesia. Because mapping takes at least 12 hr to complete,our acute condition covers this span of time immediately aftergracile lesions.

Nucleus gracilis lesions. Rats were anesthetized with intraperitoneal ketamine hydrochloride xylazine. The rat's head wastilted forward in the stereotaxic frame, and the obex was exposedsurgically. Under a dissecting microscope, lesions were made ofthe gracile nucleus with jeweler's forceps. Pilot work had establisheda clear correspondence between the morphological boundary separatingnucleus cuneatus and gracilis, with the perimeter of the hindlimbresponsive zone as delineated by multiunit recordings. The nucleuswas completely macerated with jeweler's forceps down its length.Animals appeared fully recovered from this procedure within 1hr. At no time after lesion was discomfort observed.

Surgery. Animals were water-deprived overnight before mapping of the thalamus. Five minutes before anesthesia, atropine sulfate(300 mg/kg, s.c.) was injected. Five minutes later, ketamine hydrochloride(200 mg/kg, i.p.) and xylazine (50 mg/.kg, i.p.) were administered.Maintenance doses of ketamine hydrochloride and xylazine wereadministered every hour at one-fourth the size of the respectiveloading dose for the animal. Anesthetic level was maintained byensuring that there was no response to tail pinch while gentletouch to the eye yielded a weak corneal reflex. Atropine sulfatewas administered every 2 hr (300 mg/kg, s.c.). Body temperaturewas monitored with a rectal thermometer and kept at ~37°C by athermostatically controlled heating pad underneath the animal.A hole in the trachea was cut, and periodic cleaning with papertissue followed for at least 20 min until secretions stopped accumulating.A polyethylene tube was then inserted into the trachea. A unilateralcraniotomy contralateral to the side of the gracile lesion wasmade, extending to all suture lines and the rhinal fissure. Thedura was subsequently removed with forceps. Throughout the experiment,the exposed cortex was covered in mineral oil.

Recordings. Multiunit recordings were conducted with glass-coated tungsten microelectrodes with a tip diameter of 35 µm, possessingan impedance between 2.5 and 3.0 M $Omega$ at 1000 Hz. Low- and high-passfilters with cutoff frequencies of 6000 and 300 Hz, respectively,were used. The amplifiers, filters, and oscilloscope had the samesettings across recording sessions for every animal. The initialelectrode penetrations of each session were performed at anteroposterior $-$ 0.35 cm and mediolateral ±0.33 cm corresponding to the VPL (Paxinosand Watson, 1997). The electrode was lowered 0.45 cm relativeto the surface of the cortex. Normally, two or three penetrationswere required to locate sites responsive to stimulation of theforelimb or hindlimb (and subsequently confirmed histologically).Mapping was performed by making successive penetrations in a two-dimensionalgrid of electrode penetrations in the rostrocaudal and mediolateralplanes in 0.2 mm increments, with successive recordings in thedorsoventral plane in the same increments. To reduce the mappingtime, a restricted number of body regions was examined. For eachrecording site (Fig. 1) we tested whether the units dischargedafter the application of brush stimuli to the forepaw (from elbowto paw), shoulder (from elbow to upper extremity of the arm),or hindlimb (thigh or foot). We use the term forelimb to referto forepaw and shoulder body regions. If a site failed to respondto stimulation of one of these body regions, we classified itas blank. If a site responded to more than one body region, eachone was indicated. At the end of the mapping session, two electrolyticlesions were placed (one caudal and one anterior, at the samedepth) and the coordinates recorded. The rat was then killed byanesthetic overdose.

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Figure 1. Sample data from control (top) and lesioned (bottom) animals mapped with vertical electrode penetrations. This is a coronalview of a functional map, depicting classifications of recordingsites for all body regions examined (H, hindlimb; F, forepaw;S, shoulder). The forepaw centroid in this plane is the cell witha bold border. For clarity, "blank" recording site designationsare omitted.

Mapping rules. We developed a mapping protocol that produced consistent sensory map data across pilot animals with respectto volume and shape. The rules were (1) successive penetrationsalong the mediolateral axis were terminated with two contiguousblank penetrations; (2) successive rows of penetrations alongthe rostrocaudal axis were terminated if an additional row oftracks was blank at each recording site, including one additionalpenetration medially and laterally for each track; (3) recordingcommenced in a new track 0.6 mm above the most dorsal positivelyidentified site obtained in any adjacent electrode track; and(4) if no units were encountered within an electrode track, thepenetration continued until it was 0.6 mm below the most ventralpositively identified site in any adjacent electrode track. Suchrules generated an aggregate map in the VPL representing all threebody regions examined that required 80-100 penetrations per animaland contained ~400 positively identified sites per animal. Onaverage, from tracheotomy to perfusion, the procedure took 12-14hr per animal.

Sensory maps. The forepaw sensory map includes any site responsive to forepaw stimulation, regardless of whether the samesite was also responsive to other body regions (Fig. 1). Likewise,the shoulder sensory map includes all sites responsive to shoulderstimulation, ignoring the fact that some sites may have been responsiveto other body regions. However, the zone of overlap between shoulderand forepaw includes those sites responsive to both shoulder andforepaw stimulation, regardless of its responsiveness to the stimulationof other body regions.

Histology. Animals were perfused transcardially with saline followed by 4% paraformaldehyde. Brains were removed, placed ina 30% sucrose solution of 4% paraformaldehyde, and sectioned inthe horizontal plane with a slice thickness of 0.1 mm. This planeof sectioning allowed us to discern the entire pattern of electrodetracks. Dorsal column nuclei were sectioned coronally with a slicethickness of 40 µm. All tissue was Nissl-stained.

Volumetric and spatial analysis. Sensory maps were rendered and visualized with Interactive Data Language (Boulder, CO) ona Sun Ultra 170 Sparcstation (Sun Microsystems, Mountain View,CA) from data recorded onto a 3-D spreadsheet. The volume of eachsensory map was calculated from the number of recording sitesobtained per body region multiplied by the volume element (0.008mm³) of the grid. Volumetric analysis allowed us to ascertain whichbody representations underwent expansion. We then conducted spatialanalysis on these sensory maps to explore for any characteristictopological features mediating the volumetric changes. Profilesof successive cross-sectional areas of the maps in the coronal,sagittal, and horizontal planes were compared between groups.Equivalent slices of a given sensory map across animals were identifiedby virtue of their distance from neuroanatomical or functionallandmarks. The neuroanatomical landmark was the midpoint of thelength of the ventrobasal complex (VB) along the anteroposterioraxis. The functional landmark was the centroid of the sensorymap image. For a single axis, the centroid is simply the averagecoordinate of recording sites (nonblank) along that axis. In 3-Dspace the centroid is a vector with x, y, and z coordinates. Forreasons that will become clear in Results, we relied on the centroidreference point for most of our spatial analysis.

Statistics. If the requirements of normality and homogeneity of variance were unsatisfied for a given ANOVA, a correctionwas performed to the number degrees of freedom with Huynh-Feldt $epsilon$ , making the required level of significance more stringent. Allstatistics were performed with SPSS version 6.1 for Macintosh(SPSS Inc., Chicago, IL). Post hoc unpaired t test (two-tailed)comparisons that followed ANOVA models are reported as being lessthan or greater than a 0.05 significance level.

  RESULTS

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Volumetric analysis of each sensory compartment is reported first. Sensory maps that exhibited volumetric changes were analyzedin the topology of their expansion. In our topological analysis,we also examined the decrease of hindlimb input in detail.

Volumetric analysis

Three thalamic sensory map volumes are depicted in Figure 2. The shoulder-forepaw representational overlap refers to any recordingsite that responded to brush stimuli of both shoulder and forepaw.For each sensory map, all treatment groups are included. An overallmultivariate ANOVA of all three sensory map volumes (Fig. 2) revealeda main effect of group (Pillias_(9,78) = 0.99; p < 0.001). We thenexamined the effect of group on each individual sensory map volumewith a one-factor ANOVA.

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Figure 2. Volume of three thalamic sensory maps at different times after nucleus gracilis lesions. A different group of animals wasused for each time point. The recording sites included in thecalculation of each sensory map are depicted. Asterisks indicatesignificant differences between a given treatment group comparedwith controls. Columns indicate mean; error bars indicate ±SE.

The shoulder sensory map showed an initial contraction in volume relative to controls, followed by a robust volumetric expansionat 1 week and 1 month after lesion. An ANOVA on shoulder sensorymap volumes by group revealed a clear treatment effect of lesion(F_(3,29) = 9.78; p < 0.001). Post hoc unpaired t test comparisonsindicated that acute and 1 week and 1 month postlesion groupsall had significantly different volumes compared with controls(all p < 0.05). Post hoc t test comparisons did not reveal anysignificant difference between 1 week and 1 month postlesion shouldermap volumes (p > 0.05).

The data for forepaw sensory map volumes suggest some contraction after lesions of the gracile nucleus. However, this trendwas not statistically significant (ANOVA, F_(3,29) = 2.03; p >0.1). Therefore, the forepaw sensory map did not show any significantchange in volume as a function of time after lesion.

The pattern of results suggested by the volume of representational overlap between the forepaw and shoulder sensory maps appearedto mirror the time course of the shoulder sensory map volumetricchanges. Accordingly, an ANOVA revealed a main effect of group(F_(3,29) = 15.1; p < 0.001) on representational overlap. Posthoc t test comparisons indicated that 1 week and 1 month postlesiongroups had significantly elevated volumes compared with controls,whereas the acute group significantly decreased in volume relativeto controls (post hoc t test). Again, post hoc t tests did notshow any significant difference between the volumes obtained at1 week and 1 month after lesion.

In summary, the shoulder sensory map volume, after an initial period of contraction at an acute time interval, expanded ina robust and consistent manner at 1 week and 1 month after lesion.The volume of sensory map overlap between forepaw and shoulderdisplayed the same time-dependent changes as the shoulder sensorymap after nucleus gracilis lesions. These findings suggest thatthe shoulder may be increasing its volume by expanding mediallyand overlapping with the forepaw representation.

Topological analysis of volumetric changes

We examined the cross-sectional profile of the shoulder sensory map in the coronal, sagittal, and horizontal planes. Alongthe rostrocaudal axis we discovered a circumscribed region inwhich all coronal cross-sectional area increases occurred anddesignated this region a "focal zone." Subsequent analysis insagittal and horizontal planes focused on this region of interest.Data from the coronal plane were used to compare two differentforms of slice alignment from sensory maps: neuroanatomical andfunctional.

We asked whether the volumetric increase in the shoulder sensory map reflected uniform increases in the cross-sectional areaof the map along the anteroposterior axis (Fig. 3A). Because itwas not always possible to discern the border between the ventroposteromedialnucleus (VPM) and the VPL by histology, we used the boundariesof the VB (which includes VPM and VPL) for anatomical measurements.Anatomically, VPM and VPL occupy similar rostrocaudal borders.Each coronal slice from the functional map of a rat is referencedbased on its distance from the VB midpoint. In horizontal histologicalsections the midpoint of VB was identified between the most rostralborder of VB with the reticuler nucleus and caudally with itsborder against the superior thalamic radiation (Paxinos and Watson,1997, their Fig. 100). On the abscissa, zero refers to the midpointof VB. Negative spatial offsets are caudal to the VB midpoint,whereas positive distances are anterior. Using this alignment,the average coronal area of all slices from animals at a givendistance from the VB midpoint within a treatment group was obtained.

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Figure 3. A, Coronal plane area of the shoulder sensory map as a function of anteroposterior distance. Maps from each animal are alignedwith respect to the anatomically determined anteroposterior midpointof the VB (anatomical registration). Lateral view of a rat brainindicates the plane of sectioning used on functional shouldermaps. The bar indicates a focal zone of robust change common toboth 1 week and 1 month postlesion groups. Asterisks indicatethat both 1 week and 1 month postlesion groups are significantlydifferent from controls. Error bars indicate ±SE. B, Coronal planearea of the shoulder sensory map as a function of the anteroposteriordistance. Maps from each animal are aligned with respect to thecentroid of the forepaw (functional registration). Asterisks indicatethat both 1 week and 1 month postlesioned groups are significantlydifferent from controls. Compared with anatomical alignment ofcoronal slices (A), differences emerge more clearly with the functionalalignment. All subsequent planar analysis is on coronal slicescorresponding to the focal zone. Error bars indicate ±SE.

The increases in coronal area at 1 week and 1 month after lesion occurred almost exclusively at the rostral pole of the shouldersensory map (Fig. 3A). A two-factor repeated measures ANOVA ofgroup by distance revealed a significant effect of group (F_(3,26)= 10.4; p < 0.001) and distance (F_(6.47,168.2) = 41.3; p < 0.001)and an interaction (F_{(19.41,168.2)} = 2.9; p < 0.001). Post hoct test comparisons revealed that both 1 week and 1 month postlesiongroups at 0.6 and 0.8 mm from the VB midpoint were significantlydifferent from the control group. At a rostral distance of 0.4mm, a post hoc t test comparison between 1 week postlesion andcontrol was significant, but 1 month postlesion versus controlwas not. Post hoc t test comparisons between control and 1 weekor 1 month postlesion were not significant at any other distance.The acute group displays a trend toward decreased area at almostall distances from the VB midpoint compared with controls, butwith post hoc t tests this was only significant at a distanceof $-$ 0.6 mm relative to VB.

We conducted the same type of comparisons in the coronal plane again with one difference; the identity of a coronal sliceand the alignment of shoulder sensory maps was achieved by referenceto the centroid of the forepaw representation (Fig. 3B). Becauseit appears that the forepaw representation is unaffected by nucleusgracilis lesions at the time intervals under inspection, we usedits centroid as an alternative reference point.

For each animal, slices of the shoulder sensory map were identified by virtue of their anteroposterior distance from the centroidof the forepaw (Fig. 3B). For each animal within a treatment group,coronal slices of the same distance from the forepaw centroidwere averaged. These coronal areas were plotted as a functionof their distance from the forepaw centroid. With functional alignment,differences in this graph are consistent with differences detectedwith neuroanatomical alignment (Fig. 3A) but emerged more clearly.

A two-factor repeated measures ANOVA of the data depicted in Figure 3B revealed a significant effect of group (F_(3,26) = 9.8;p < 0.001) and distance (F_(7.6,196.5) = 47.4; p < 0.001) and aninteraction (F_(22.7,196.5) = 4.5; p < 0.001). When 1 week and1 month postlesion groups were compared with controls, they weresignificantly larger at distances of 0.2 and 0.4 mm, respectively,rostral to the forepaw centroid (post hoc t tests). At a distanceof 0.6 mm, the 1 month postlesion group was significantly differentfrom control, whereas the 1 week postlesion group was not (posthoc t test). At the midpoint, only the 1 week postlesion groupwas significantly different from controls (post hoc t test). Finally,significant differences emerged between acute and control groupsfrom 0.2 mm rostral to 1.0 mm caudal to the centroid (except atthe midpoint, with post hoc t tests). At no point was there asignificant difference between 1 week and 1 month postlesion (posthoc t tests).

Displayed in Figure 4 are data from a control and 1 week postlesion animal for the shoulder sensory map. Each cube representsa recording site that was responsive to shoulder stimulation.The control map may on first inspection appear as two separaterepresentations. However, minor discontinuities in sensory mapswere not uncommon across animals and did not display any spatialconsistency in their manifestation. If one averaged representationsacross animals, the composite map would appear solid in its entirety.

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Figure 4. Spatial distribution of recording sites responsive to shoulder stimulation from control and 1 week postlesion animals. Thisis a caudal perspective of the sensory map. Lesion-induced changesare most marked at the rostral pole, toward the anterior end ofthe display. Much of the shoulder expansion appears to occur alongthe mediolateral axis after gracilis lesions.

Functional alignment generated the same pattern of results as neuroanatomical registration of coronal slices, but differencesappeared clearer. For this reason, and the relative ease withwhich a functional reference point permits comparisons in otherplanes, we used functional alignment for the remainder of theanalysis. The region of interest with focal changes common toboth 1 week and 1 month postlesion occurred at distances of 0.2and 0.4 mm, respectively, rostral to the forepaw centroid (Fig.3B). We identify this region of interest as a focal zone of reorganization.

Perhaps, however, our focal zone of expansion of the shoulder representation near the rostral pole is related to a massiveloss of hindlimb input compared with more caudal segments of themap. In Figure 5, hindlimb data are plotted in the same manneras in Figure 3B using functional alignment. An extensive lossof hindlimb input occurred in regions rostral and caudal to theforepaw centroid.

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Figure 5. Plot of residual hindlimb input as a function of the anteroposterior axis. Abscissa coordinates are the same as those in Figure3B. The area of hindlimb input corresponding to the focal zonerelative to the forepaw centroid is indicated by the bar. Asterisksindicate significant differences between all treatment groupscompared with control values. Error bars indicate ±SE.

Statistical comparisons confirmed the extensive loss of hindlimb input rostrally and caudally to the forepaw centroid (Fig.5). A two-factor repeated measures ANOVA revealed a main effectof group (F_(3,26) = 32.9; p < 0.001) and distance (F_(9.1,237)= 28.2; p < 0.001) and an interaction (F_(27.3,237) = 5.5; p <0.001). The interaction suggests that the loss of hindlimb inputwas not constant with distance from the centroid. This resultis largely attributable to the fact that relatively more hindlimbinput remained intact at the caudal part of the map. The lossof hindlimb input at distances corresponding to the focal zone(0.2 and 0.4 mm anterior to centroid; Fig. 5, bar) was similarto that observed (e.g., >60% loss) at more caudal distances of $-$ 0.2 to $-$ 0.6 mm. Yet, at these caudal positions, from $-$ 0.2 to $-$ 0.6 mm, extensive loss of hindlimb responses did not producean expansion of the shoulder sensory map at corresponding coronalplanes (as in Fig. 3B). Overall, post hoc t test comparisons revealeda significant reduction of hindlimb input for all groups from0.6 to $-$ 1.2 mm.

We asked how strong a predictor the reduction of hindlimb input would be of the ensuing shoulder expansion in the designatedfocal zone. We extracted from the functional shoulder map of eachanimal the two coronal slices corresponding to our focal zoneof expansion (0.2 and 0.4 mm from the forepaw centroid; referto Fig. 3B). For each animal we averaged the counts from thesetwo slices and in turn averaged those values across animals withina group.

We looked at whether residual hindlimb volume in this focal zone (0.2-0.4 mm) could predict the degree of shoulder expansion.A linear regression, which combined 1 week and 1 month postlesionfocal zones of each rat into a group large enough for this analysis,failed to reach significance (F_(1,14) = 3.6; p > 0.08). Repeatingthe same analysis by looking at residual hindlimb input in theentire functional map as a predictor of shoulder expansion inthe focal zone also failed to reach significance (F_(1,14) = 0.35;p > 0.5). Thus, the level of hindlimb loss did not predict theextent of shoulder expansion.

The spatial distribution of recording sites that were responsive to hindlimb stimulation is depicted in Figure 6. The intacthindlimb map in the control is restricted along the mediolateralaxis but extends some distance in the dorsoventral direction.The extant hindlimb representation after a gracilis lesion indicateda number of punctate zones in which input appears to have remainedintact, but overall the map is considerably reduced (>60%) insize.

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Figure 6. Control and 1 week postlesioned animals. Spatial distribution of recording sites that were responsive to hindlimb stimulationare depicted from the caudal vantage point.

For the remainder of the planar analysis we continued to analyze the two coronal slices corresponding to the focal zone ofshoulder expansion at 0.2 and 0.4 mm (Fig. 3B). Figure 7 depictsa profile of sagittal slices of the shoulder representation inthis focal zone, taken along the mediolateral axis. Sample mappingdata from a control animal from which Figure 6 was derived aredisplayed in Figure 1. The coronal slice taken in Figure 1 wastaken at a distance from the forepaw centroid corresponding tothe focal zone seen in lesioned animals. The identified unit correspondingto the centroid of the forepaw is enclosed in a box. To the leftof the centroid (medially) are forepaw recording sites, and tothe right of the centroid are shoulder and hindlimb recordingsites.

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Figure 7. Cross-sectional area profile of shoulder representation. The focal zone is represented as a dark band in the coronal plane,which was cut sagittally with reference to the intact rat brain.Asterisks indicate significant differences between control versus1 week and 1 month groups after lesion. As far as 0.6 mm medialto the forepaw centroid, 1 month postlesion was significantlyelevated compared with control. Error bars indicate ±SE.

Visual inspection of Figure 7 suggests that expansion of the shoulder representation at 1 week and 1 month after lesion progressedmedially with reference to the forepaw centroid. A two-factorrepeated measure ANOVA revealed a significant effect of group(F_(3,26) = 16.4; p < 0.001) and distance (F_(6,155.5) = 39.7; p< 0.001) and an interaction (F_(17.9,155.5) = 4.1; p < 0.001).Compared with controls, 1 week and 1 month postlesion groups weresignificantly elevated in zones progressing from the centroid(zero) to 0.4 mm medially (post hoc t tests). At 0.6 mm the 1month postlesion group was significantly increased (post hoc ttest). The acute group did not reveal any significant contractionor expansion (post hoc t tests). It appears that along the mediolateralaxis, expansion of the shoulder sensory map extended its borderup to 0.6 mm medially. The small lateral expansion to the rightof the forepaw centroid appears to be confined within the zoneof the forepaw representation (Fig. 1).

In the horizontal plane, changes in cross-sectional area along the dorsoventral axis reveal that expansion occurs essentiallyat all depths in the focal zone (Fig. 8). This analysis examinedthe same two slices containing the focal zone that were scrutinizedin the sagittal plane described above. A two-factor repeated measureANOVA revealed a main effect of group (F_(3,26) = 11.2; p < 0.001)and distance (F_(5.9,154.4) = 29.1; p < 0.001) and an interaction(F_(17.8,154.4) = 4.8; p < 0.001). Both 1 week and 1 month postlesiongroups were significantly elevated compared with controls in themajority of horizontal planes, from 0.4 mm dorsal to the centroidto $-$ 0.4 mm ventral (post hoc t tests). At 0.6 mm dorsal to thecentroid, 1 week postlesion was significant, whereas 1 month postlesionwas not (post hoc t tests). There was no significant differencebetween 1 week and 1 month postlesion at any horizontal level(post hoc t tests). With regard to the acute group, there wasa significant depression at the centroid when compared with controls(post hoc t test).

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Figure 8. Profile of shoulder sensory representation, revealed by cross-sectional slices in the horizontal plane. The focal zone isindicated as a dark coronal band, sectioned with reference tothe intact rat brain. Asterisks indicate significant differencesfor both 1 week and 1 month postlesion groups versus control.Error bars indicate ±SE.

Histology

Figure 9 is a photomicrograph of the dorsal column nuclei 1 week after lesion and shows that the damage to the gracile isvery extensive. The cuneate nucleus on the right is very closeto the medial edge of the left gracile nucleus with a small barof gliotic tissue in between. Such damage was present along thelength of the nucleus. There was also some suggestion of gliosisin the cuneate nucleus, although this appeared weak.

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Figure 9. Photomicrograph depicting a coronal view of the dorsal column nuclei stained with Nissl 1 week after lesion. The damage observedin the gracile nucleus existed along the length of the nucleus.The accompanying diagram is a schematic rendering of the photomicrograph,barring tissue-processing artifacts. The zone of gliosis is indicatedby the stippled area. cu fasc, Cuneatus fasciculus; Cu, cuneatenucleus; Gr, gracile nucleus.

Figure 10 presents a photomicrograph of a Nissl-stained section of the thalamus in the horizontal plane of a lesioned animal(1 month after lesion). Sectioning the brains this way allowedus to visualize the entire pattern of electrode penetrations.Because the VPL is crescent-shaped in the coronal plane, penetrationsat the presented slice level that appear too medial actually contactthe VPL at more ventral levels. Consistently, our shoulder expansionappeared to occur at medial electrode penetrations at the rostralpole of the VPL.

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Figure 10. Photomicrograph of a 1 month postlesion rat brain sectioned in the horizontal plane and stained with cresyl violet. Arrowsare interposed between two rows of electrode penetrations correspondingto the focal zone.

  DISCUSSION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Volumetric analysis indicated that expansion of the forelimb representation was confined to the shoulder region. However,such expansion in sensory map volume observed at 1 week and 1month after lesion occurred after an unexpected transient contractionin volume at an acute time interval. Measures of representationaloverlap between forepaw and shoulder demonstrated the same temporalchanges in volume as the shoulder sensory map. This latter dataset suggested that the shoulder expanded by overlapping the forepawrepresentation, rather than expanding laterally into the denervatedhindlimb zone.

Thalamic representation changes illustrated by volumetric data presaged similar findings in a detailed topological analysis.Remarkably, a focal zone of shoulder expansion was common at both1 week and 1 month after lesion at ~0.2-0.4 mm rostral to theforepaw centroid. Surprisingly, analysis of this focal zone inthe sagittal plane clearly indicated that expansion progressedmedially, overlaying the forepaw representation. As detailed inResults, there was no gradient or zone of hindlimb denervationthat corresponded uniquely to our focal zone of shoulder expansion.

A schematic summary of the somatotopic changes occurring in our identified focal zone at 1 week and 1 month after lesion ispresented (Fig. 11). The medial progression of the shoulder forepawsensory map is derived from the volumetric data of compartmentaloverlap between shoulder and forepaw representations that increasedafter an acute time interval (Fig. 2). Additionally, when thefocal zone was sectioned in the sagittal plane (Fig. 7) as describedabove, a clear medial progression of the shoulder sensory mapinto the forepaw representation was revealed. Qualitatively thisis consistent with what we observed in our raw data from the focalzone (Fig. 1B).

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Figure 11. Schematic of the topographic overlap between shoulder and forepaw in the focal zone at 1 week and 1 month after lesion. Thisis a coronal view of forepaw, shoulder, and hindlimb sensory mapsin the VPL. The plasticity depicted is derived from data on thevolume of shoulder-forepaw overlap (Fig. 2) and planar analysis(Figs. 7, 8).

It is unlikely that our results are a product of the type of anesthetic used or subcortical bleeding. All groups were exposedto the same mapping protocol. Therefore, such an explanation failsto explain the different results obtained for each time pointwith respect to control. Furthermore, such an artifact is notconsistent with our observed changes localized to the rostralpole of the VPL, rather than occurring throughout the length ofthe nucleus. Finally, since the acute group showed the oppositechanges to later time points also suggests that our results arenot the product of mapping-induced neuronal injury or anesthesia.

It was not necessary to control for possible morphological differences in the size of thalamic nuclei across animals. Althoughsuch differences may exist, there is no reason to believe thatthere are systematic differences between groups. If one arguedfor lesion-induced atrophy in the size of thalamic nuclei producingsuch differences, one would have to postulate increases in sizeof the VPL, because the absolute dimensions of the shoulder sensorymap enlarged with time.

It may be possible that damage was caused to the shoulder input, as reflected in the contraction in its sensory map volumeat an acute time interval. Histology did reveal some gliosis inthe nucleus cuneatus. However, no statistically significant differencewas seen between control and any of the lesioned groups for theforepaw sensory map volume. One would have expected damage tothe forepaw sensory map if this hypothesis was correct, becauseit is interposed between the gracile nucleus and the shoulderfunctional map (Nord, 1966). Additionally, coronal slices of theshoulder sensory map outside of the focal zone at 1 and 4 weeksafter lesion have exactly the same cross-sectional area as controls,suggesting that the contraction observed at an acute time intervalis not a product of damage.

We have recently completed a preliminary study of the thalamus after nerve transection at 1 week after lesion (J. L. Parkerand J. O. Dostrovsky, unpublished data). We have observed changesafter nerve transection similar to those described in this study.This suggests that possible damage to nucleus cuneatus causedby gracile lesions or residual hindlimb input to VPL is not alikely explanation for the pattern of reorganization describedherein.

Concordant with the results of Wall and Egger (1971), our lesions of nucleus gracilis failed to block hindlimb input completely.It is likely that the extant hindlimb sensory map was receivinginput from pathways independent of the dorsal column nuclei. Thespinocervical tract can convey cutaneous information and doesso independently of the dorsal column nuclei (Morin, 1955; Giesleret al., 1979). In addition, in the rat it appears that many spinothalamictract neurons respond to innocuous inputs, and at least some ofthese neurons terminate in the VPL (Dado et al., 1994). Eitherone of these pathways may have been responsible for mediatingthe residual hindlimb input observed in this study.

There were also clear differences in this report from that of Wall and Egger (1971). The most poignant difference is thatshoulder expansion did not appear to progress into the denervatedhindlimb zone but rather annexed territory by superimposing itselfon the existing forepaw representation. Importantly, this changewas contained in a 300 µm coronal slice toward the rostral poleof the VPL. Such discrepancies may be related to differences inthe choice of the control group. Wall and Egger (1971) used thehemisphere ipsilateral to their gracile lesion as a within-subjectcontrol. However, we now know that there are ipsilateral consequencesfrom a lesion (before its decussation), such as somatotopic plasticity(Calford and Tweedale, 1990) and changes in acetylcholine bindingin the cortex (Hanisch et al., 1992). In comparing our treatmentgroups against a separate group of nonlesioned animals, we haveavoided possible misinterpretation in using the contralateralhemisphere as a control.

One mechanism that may account for the contraction of the shoulder functional volume is the emergence of inhibitory receptivefields, which are known to result from deafferentation (Dostrovskyet al., 1976; Rasmusson et al., 1993). After digit amputationin the raccoon, neurons that have suffered loss of input acquireinhibitory receptive fields on adjacent intact digits ("off-focusinhibition"), which depress spontaneous activity when stimulated(Northgrave and Rasmusson, 1996). Consistent with the transientcharacter of our shoulder map volume contraction, inhibitory receptivefields are observable at acute time intervals but appear to beabsent in chronic preparations (Dostrovsky et al., 1976; Northgraveand Rasmusson, 1996; Rasmusson, 1996b).

A decrease in shoulder map volume at an acute time interval may be the product of off-focus inhibition by neurons that previouslyhad receptive fields for shoulder and hindlimb. Single-unit characterizationof VPL neurons has encountered neurons with large receptive fieldsthat can cover virtually half of the body surface of the rat (Shermanet al., 1998). In mapping acutely lesioned animals, off-focusinhibition generated by a few neurons with receptive fields coveringthe shoulder and hindlimb would cause a decrease in spontaneousactivity of other neurons at the recording site. Accordingly,reduced background activity attenuates the discharge probabilityof other neurons that are responsive to shoulder stimulation.Off-focus inhibition generated by a few units at a recording sitereduces the number of recording sites responsive to shoulder stimulation,which in our paradigm is reflected as an overall decrease in theshoulder map volume.

An overview of the literature might suggest that the direction of our shoulder expansion is inconsistent with the maxim thatincreased somatotopic representation occurs via border extensionsinto an adjacent deafferented zone (Wall and Egger, 1971; Kalaskaand Pomeranz, 1979; Merzenich et al., 1983, 1987; Wall and Cusick,1984). However, there may be an unusual relationship between forelimband hindlimb somatotopic maps that may warrant the suspensionof this maxim in this case. Research at the cortical level thathas examined changes in somatotopy after fasciculus gracilis lesionsfailed to find any expansion of the forelimb into hindlimb (Jaineet al., 1995). Investigations with optical imaging of the cerebralcortex in rats have found considerable topographic overlap betweendifferent skin regions within either the forelimb or hindlimb(Godde et al., 1995). In contrast, Godde et al. (1995) found nooverlap between the forelimb and hindlimb representations, leadingto the speculation that these two somatotopic domains may be functionallyinsulated from each other in the context of plasticity. One mightargue that cortical and thalamic somatotopic changes may be independent(Wang et al., 1995) or question whether somatotopic territorycan be exchanged between hindlimb and forelimb.

If we accept provisionally that border shifts between forelimb and hindlimb representations do not occur, it is not immediatelyobvious why the loss of hindlimb input would induce topographicoverlap between shoulder and forepaw. There is good evidence supportingthe view (Merrill and Wall, 1972) that inhibition is importantin restricting receptive field size, and this has been confirmedat the cortical (Hicks and Dykes, 1983; Dykes et al., 1984) andthalamic levels (Lee et al., 1994). Interestingly, recordingsfrom the VPL revealed mutual inhibition between forelimb and hindlimbunits in 45% of the neurons tested in response to electrical stimulation(Roberts and Wells, 1990). Perhaps the loss of the hindlimb representationremoved inhibition acting on units in the forepaw representationof the VPL, leading to an increase in their receptive field size,enabling these units to respond to shoulder stimulation.

Hot spot model

The plastic focal zone we have described in the thalamus after nucleus gracilis lesions appears to have four properties: (1)it is a subregion of a sensory map defined by low-threshold mechanicalinput that appears to display somatotopic reorganization; (2)it reveals reorganizational events that occur over chronic ratherthan acute time intervals; (3) reorganizational events take placein a zone that is a slice; and (4) this slice appears to be orientedorthogonally to columns of cells possessing the same receptivefields.

Property 4 is partly an inference drawn from the literature. Jones et al. (1979, 1982) and Jones and Friedman (1982) havebuilt a persuasive case that the columnar organization of thecerebral cortex (Mountcastle, 1957) is also found in the VB ofthe thalamus. These "thalamic rods" are analogous to the columnarorganization of the cortex, because within a rod cells possessedthe same receptive field properties (Jones et al., 1982). Furthermore,these rods were proposed to be oriented along the anteroposterioraxis in the thalamus. If thalamic rods exist, they intersect ourslice of plasticity at approximately a 90° angle (Fig. 12).

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Figure 12. Hot spot model of neural plasticity. A depiction of our identified focal zone or hot spot of reorganization in the thalamus.It is proposed that hot spots exist at other levels of the somatosensorypathway such as the cortex. Cortically, the hot spot is a sliceoriented orthogonally to the cortical columns of Mountcastle (1957),in the same way the thalamic hot spot is orthogonally orientedwith respect to the thalamic rods of Jones et al. (1979, 1982)and Jones and Friedman (1982). The somatotopy of the thalamusis rotated compared with that of the cortex, given the differencein the orientation of thalamic rods and cortical columns. SeeDiscussion.

We speculate that this focal zone may be a hot spot that displays thalamic reorganization in general and may have manifestationselsewhere in the nervous system. This hot spot hypothesis hastwo predictions. First, the thalamic hot spot is not specificto nucleus gracilis lesions but may also be important in displayingsomatotopic reorganization after other types of neural trauma(e.g., nerve transection) (Parker and Dostrovsky, unpublisheddata). Second, the existence of a hot spot of plasticity is nota feature specific to the thalamus but may also exist in otherstructures such as the cerebral cortex or dorsal column nuclei.

If a hot spot exists in the cerebral cortex, properties 3 and 4 would predict the orientation of the slice that reveals reorganization.The existence of columns of cells with isomorphic receptive fieldproperties is organized vertically in the cortex (Mountcastle,1957), opposite to the orientation of thalamic rods (Fig. 12).According to property 4 of our hot spot description, the slicewould be oriented horizontally in the cortex, orthogonal to thecortical columns of Mountcastle (1957).

Properties 1 and 2 of the hot spot applied to the cortex would predict the existence of a circumscribed zone displaying plasticityover chronic time intervals. Although a consensus may not existwith respect to the role of each lamina in mediating plasiticity,it is clear that over time specific lamina seem to be particularlymodifiable (Diamond et al., 1994; Kirkwood and Bear, 1994). Interms of the hot spot hypothesis, a slice displaying plasticitymay include one or a subset of the six lamina in the cortex (property1). For illustrative purposes we have suggested layer IV (Fig.12), which seems to undergo plasticity over chronic rather thanacute time intervals (Jenkins et al., 1990; Recanzone et al.,1992; Diamond et al., 1994), consistent with property 2 of thehot spot.

Differences in the orientation of hot spots at each level of the neuraxis can determine how easily they are detected withstandard vertical electrode penetrations. Statistically, a largenumber of electrode penetrations would be required before thethalamic hot spot was detected, whereas in the cortex, every verticalelectrode penetration traverses this plastic slice (Fig. 12). Thisdifference may explain why learning-induced changes in corticalsomatotopy were not detected in the thalamus (Wang et al., 1995).In our view, a detailed 3-D reconstruction of the entire somatotopicmap in the thalamus would be necessary to detect such a zone.

In summary, the hot spot hypothesis can make predictions about the time course and orientation of a slice of plasticity atdifferent levels of the nervous system. We do not venture to speculateon what the inter-relationships may be between hot spots at differentlevels of the neuraxis, if they in fact exist outside of the thalamus.

Conclusions

To our knowledge, the contraction of sensory maps at acute time intervals after lesion followed by increased topographic overlaprepresent new properties of thalamic plasticity. Furthermore,such topographic overlap mediating shoulder sensory map expansionoccurred within a narrow coronal slice of the VPL that we havereferred to as a focal zone. Thus, it appears that thalamic sensorymaps defined by low-threshold mechanical input are not homogeneouswith respect to their potential for plasticity.

  FOOTNOTES

Received June 18, 1997; revised Oct. 21, 1997; accepted Oct. 23, 1997.

This research was supported by grants from National Institutes of Health and National Science and Engineering Research Councilof Canada. We appreciate the helpful comments on this manuscriptby Dr. Rasmusson. We also thank Karen Ma for technical assistance.
Correspondence should be addressed to Jonathan O. Dostrovsky, Department of Physiology, University of Toronto, Medical SciencesBuilding, Room 3305, Toronto, Ontario, Canada M5S-1A8.

  REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

Alloway KD, Aaron GB (1996) Adaptivechanges in the somatotopic properties of individual thalamic neuronsimmediately following microlesions in connected regions of thenucleus cuneatus. Synapse 22:1-14[Web of Science][Medline].
Basbaum AI, Wall PD (1976) Chronicchanges in the response of cells in adult cat dorsal horn followingpartial deafferentation: the appearance of responding cells ina previously non-responsive region. BrainRes 116:181-204[Web of Science][Medline].
Calford MB, Tweedale R (1990) Interhemispherictransfer of plasticity in the rat cerebral cortex. Science 249:805-807[Abstract/Free Full Text].
Dado RJ, Katter JT, Giesler GJJ (1994) Spinothalamicand spinohypothalamic tract neurons in the cervical enlargementof rats. II. Responses to innocuous and noxious mechanical mechanicaland thermal stimuli. JNeurophysiol 71:981-1002[Abstract/Free Full Text].
Devor M, Wall PD (1978) Reorganizationof spinal cord sensory map after peripheral nerve injury. Nature 275:75-76.
Diamond ME, Huang W, Ebner FF (1994) Laminarcomparison of somatosensory cortical plasticity. Science 265:1885-1888[Abstract/Free Full Text].
Dostrovsky JO, Millar J, Wall PD (1976) Theimmediate shift of afferent drive of dorsal column nucleus cellsfollowing deafferentation: a comparison of acute and chronic deafferentationin gracile nucleus and spinal cord. ExpNeurol 52:480-495[Web of Science][Medline].
Dykes RW, Landry P, Metherate RS, Hicks TP (1984) Functionalrole of GABA in cat primary somatosensory cortex: shaping receptivefields of cortical neurons. JNeurophysiol 52:1066-1093[Abstract/Free Full Text].
Fadiga E, Haimann C, Margnelli M, Sotgiu ML (1978) Variabilityof peripheral representation in ventrobasal thalamic nuclei ofthe cat: effects of acute reversible blockade of the dorsal columnnuclei. Exp Neurol 60:484-498[Medline].
Garraghty PE, Kaas JH (1991) Functionalreorganization in adult monkey thalamus after peripheral nerveinjury. NeuroReport 2:747-750[Web of Science][Medline].
Giesler GJJ, Urca G, Cannon T, Liebeskind JC (1979) Responseproperties of neurons of the lateral cervical nucleus in the rat. JComp Neurol 186:65-78[Medline].
Godde B, Hilger T, vonSeelen W, Berkefeld T, Dinse HR (1995) Opticalimaging of rat somatosensory cortex reveals representational overlapas a topographic principle. NeuroReport 7:24-28[Web of Science][Medline].
Hanisch U-K, Rothe T, Krohn K, Dykes RW (1992) Muscariniccholinergic receptor binding in rat hindlimb somatosensory cortexfollowing partial deafferentation by sciatic nerve transection. NeurochemInt 21:313-327[Medline].
Hicks TP, Dykes RW (1983) Receptivefield size for certain neurons in primary somatosensory cortexis determined by GABA-mediated intracortical inhibition. BrainRes 274:160-164[Web of Science][Medline].
Jaine NJ, Florence SL, Kaas JH (1995) Limitson plasticity in somatosensory cortex of adult rats: hindlimbcortex is not reactivated after dorsal column transection. JNeurophysiol 73:1537-1546[Abstract/Free Full Text].
Jenkins WM, Merzenich MM, Ochs MT, Allard T, Guic-Robles E (1990) Functionalreorganization of primary somatosensory cortex in adult owl monkeysafter behaviorally controlled tactile stimulation. JNeurophysiol 63:82-104[Abstract/Free Full Text].
Jones EG, Friedman DP (1982) Projectionpattern of functional components of thalamic ventrobasal complexon monkey somatosensory cortex. JNeurophysiol 48:521-544[Free Full Text].
Jones EG, Wise SP, Coulter JD (1979) Differentialthalamic relationships of sensory-motor and parietal corticalfields in monkeys. JComp Neurol 183:833-882[Web of Science][Medline].
Jones EG, Friedman DP, Hendry HC (1982) Thalamicbasis of place- and modality-specific columns in monkey somatosensorycortex: a correlative anatomical and physiological study. JNeurophysiol 48:545-568[Free Full Text].
Kalaska J, Pomeranz B (1979) Chronicpaw denervation causes an age-dependent appearance of novel responsesfrom forearm in "paw cortex" of kittens and adult cats. JNeurophysiol 42:618-633[Abstract/Free Full Text].
Kirkwood A, Bear MF (1994) Hebbiansynapses in visual cortex. JNeurosci 14:1634-1645[Abstract].
Lee SM, Friedberg MH, Ebner FF (1994) Therole of GABA-mediated inhibition in the rat ventral posteriormedial thalamus. I. Assessment of receptive field changes followingthalamic reticuler nucleus lesions. JNeurophysiol 71:1702-1715[Abstract/Free Full Text].
Merrill EG, Wall PD (1972) Factorsforming the edge of a receptive field: the presence of relativelyineffective afferent terminals. JPhysiol (Lond) 226:825-846[Abstract/Free Full Text].
Merzenich MM, Kaas JH, Wall JT, Nelson RJ, Sur M, Felleman DJ (1983) Progressionof change following medial nerve section in the representationof the hand in area 3b and 1 in adult owl and squirrel monkeys. Neuroscience 10:639-665[Web of Science][Medline].
Merzenich MM, Nelson RJ, Kaas JH, Stryker MP, Jenkins WM, Zook JM, Cynader MS, Schoppmann A (1987) Variabilityin hand surface representations in areas 3b and 1 in adult owland squirrel monkeys. JComp Neurol 258:281-296[Web of Science][Medline].
Millar J, Basbaum AI, Wall PD (1976) Restructuringof the somatotopic map and appearance of abnormal neuronal activityin the gracile nucleus after partial deafferentation. ExpNeurol 50:658-672[Web of Science][Medline].
Morin F (1955) A new spinal pathway for cutaneous impulses. AmJ Physiol 130:245-252.
Mouncastle VB (1957) Modality and topographic propertiesof single neurons of cat's somatic sensory cortex. JNeurophysiol 20:408-434[Free Full Text].
Nakahama H, Nishioka S, Otsuka T (1966) Excitationand inhibition in ventrobasal thalamic neurons before and aftercutaneous input deprivation. ProgBrain Res 21A:180-185[Medline].
Nicolelis MAL, Lin RCS, Woodward DJ, Chapin JK (1993) Inductionof immediate spatiotemporal changes in the thalamic networks byperipheral block of ascending cutaneous information. Nature 361:533-536[Medline].
Nord GN (1966) Somatotopic organization in the spinaltrigeminal nucleus, the dorsal column nuclei and related structuresin the rat. J Comp Neurol 130:343-356.
Northgrave SA, Rasmusson D (1996) Theimmediate effect of peripheral deafferentation on neurons of thecuneate nucleus in raccoons. SomatosensMot Res 13:103-113[Web of Science][Medline].
Parker JL, Dostrovsky JO (1996) Spatialdynamics of thalamic plasticity. CanPhysiol Soc 27:122.
Paxinos G, Watson C (1997) In: Therat brain in stereotaxic coordinates, Ed 3. NewYork: Academic.
Pollin B, Albe-Fessard D (1979) Organizationof somatic thalamus in monkeys with and without section of dorsalspinal tracts. BrainRes 173:431-449[Web of Science][Medline].
Rasmusson D (1996a) Changes in the organization of theventroposterior lateral thalamic nucleus after digit removal inadult raccoon. J CompNeurol 364:93-103.
Rasmusson DD (1996b) Changes in the response propertiesof neurons in the ventroposterior lateral thalamic nucleus ofthe raccoon after peripheral deafferentation. JNeurophysiol 75:2441-2450[Abstract/Free Full Text].
Rasmusson DD, Louw DF, Northgrave SA (1993) Theimmediate effects of peripheral denervation on inhibitory mechanismsin the somatosensory thalamus. SomatosensMot Res 10:69-80[Web of Science][Medline].
Recanzone GH, Merzenich MM, Jenkins WM, Grajski KA, Dinse HR (1992) Topographicreorganization of the hand representation in cortical area 3bof owl monkeys trained in frequency-discrimination task. JNeurophysiol 67:1031-1056[Abstract/Free Full Text].
Rhoades RW, Belford GR, Killackey HP (1987) Receptive-fieldproperties of rat ventral posterior medial neurons before andafter selective kainic acid lesions of the trigeminal brainstemcomplex. J Neurophysiol 57:1577-1600[Abstract/Free Full Text].
Roberts WA, Wells J (1990) Extensivedual innervation and mutual inhibition by forelimb and hindlimbinputs to ventroposterolateral nucleus projection neurons in therat. Somatosens MotRes 7:85-95[Medline].
Sherman SE, Luo L, Dostrovsky JO (1998) Altered Receptive Fields and sensory modalities of rat VPL Thalamic neuronsduring spinal strychnine-induced allodynia. J Neurophysiol, inpress.
Shin H-C, Park S, Son J, Sohn J-H (1995) Responsesfrom new receptive fields of VPL neurones following deafferentation. NeuroReport 7:33-36[Web of Science][Medline].
Snow PJ, Wilson P (1991) Plasticityand somatosensory thalamus. In: Plasticityin the somatosensory system of developing and mature mammals $---$ theeffects of injury to the central and peripheral nervous system (Autrum H, Ottoson D, Perl ER, Schmidt RF, Shimazu H, Willis WD, eds), pp 286-311. Berlin: Springer.
Wall PD, Egger MD (1971) Formationof new connexions in adult rat brains after partial deafferentation. Nature 232:542-545[Medline].
Wall PT, Cusick CG (1984) Cutaneousresponsiveness in primary somatosensory (S-1) hindpaw cortex beforeand after partial hindpaw deafferentation in adult rats. JNeurosci 4:1499-1515[Abstract].
Wang X, Merzenich MM, Sameshima K, Jenkins WM (1995) Remodellingof hand representation in adult cortex determined by timing oftactile stimulation. Nature 378:71-75[Medline].

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