Evidence for Brainstem and Supra-Brainstem Contributions to Rapid Cortical Plasticity in Adult Monkeys

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The Journal of Neuroscience, September 1, 1999, 19(17):7578-7590

Evidence for Brainstem and Supra-Brainstem Contributions to Rapid Cortical Plasticity in Adult Monkeys
J. Xu and J. T. Wall
Department of Neurobiology and Anatomy, Medical College of Ohio, Toledo, Ohio 43699-0008

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cortical maps can undergo amazingly rapid changes after injury of the body. These changes involve functional alterations innormal substrates, but the cortical and/or subcortical location(s)of these alterations, and the relationships of alterations indifferent substrates, remain controversial. The present studyused neurophysiological approaches in adult monkeys to evaluatehow brainstem organization of tactile inputs in the cuneate nucleus(CN) changes after acute injury of hand nerves. These data werethen compared with analogous data from our earlier cortical area3b studies, which used the same approaches and acute injury, toassess relationships of cuneate and cortical changes. The resultsindicate that cuneate tactile responsiveness, receptive fieldlocations, somatotopic organization, and spatial properties ofrepresentations (i.e., location, continuity, size) change duringthe first minutes to hours after injury. The comparisons of cuneateand area 3b organization further show that some cuneate changesare preserved in area 3b, whereas other cuneate changes are transformedbefore being expressed in area 3b. The findings provide evidencethat rapid reorganization in area 3b, in part, reflects mechanismsthat operate from a distance in the cuneate nucleus and, in part,reflects supracuneate mechanisms that modify brainstemchanges.

Key words: neuronal plasticity; somatosensory cortex; dorsal column nuclei; lemniscal mechanisms; disinhibition; sensitization; tactile processing; primate cuneate nucleus

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cortical and subcortical substrates of the CNS contain organized maps of tactile inputs from the skin. Long-standing peripheralinjury in adult primates causes map reorganization in corticalarea 3b that, in part, reflects subcortical and cortical anatomicalchanges that slowly develop over months to years (Florence etal., 1998; Jones and Pons, 1998). These slow changes are precededby functional changes in normal anatomical substrates, the firstof which can be expressed with surprising quickness; for example,initial functional alterations of tactile inputs in area 3b beginwithin minutes to hours after various hand injuries (Merzenichet al., 1983; Calford and Tweedale, 1991; Kolarik et al., 1994;Silva et al., 1996). In contrast to long-standing changes, thereis little understanding of whether or how subcortical alterationscontribute to these rapid cortical changes (for review, see Florenceet al., 1997). The contributions of brainstem substrates remainespecially unclear because studies of the cuneate, gracile, andtrigeminal nuclei present a controversial mix of positive (Dostrovskyet al., 1976; Millar et al., 1976; Pettit and Schwark, 1993, 1996;Panetsos et al., 1995; Faggin et al., 1997) and negative (McMahonand Wall, 1983; Waite, 1984; Northgrave and Rasmusson, 1996; Zhangand Rowe, 1997) evidence for acute reorganization in thebrainstem.

A recent study indicates that functional changes appear in the main cuneate nucleus (CN) of adult monkeys within minutes afterhand injury (Xu and Wall, 1997a). This finding prompted the presentexperiments to further study CN changes during this initial postinjuryperiod and to evaluate whether initial CN and cortical changesare related. To examine these issues, neurophysiological approacheswere used to evaluate how tactile inputs from the hand and adjacentbody are organized in the CN of adult squirrel monkeys after acutesection of nerves (median and ulnar) to the hand. These data werethen compared with corresponding area 3b data from our previousstudies of adult squirrel monkeys that had the same acute injuryand that were assessed using identical approaches (Kolarik etal., 1994). The following questions were addressed: how are featuresof tactile input organization in the CN of adult primates changedin the first minutes to hours after injury, and how are functionalchanges in CN and area 3b hand maps related during thisperiod?

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

All protocols followed the guidelines of the National Institutes of Health Guide for the Care and Use of Laboratory Animalsand were approved by the Institutional Animal Care and Use Committeeat the Medical College ofOhio.

Samples and animal preparation. All data are from adult squirrel monkeys. Postinjury CN data were derived from five monkeysthat had ipsilateral acute sections of the median and ulnar nerves.Data from these monkeys were compared with preinjury data fromthese monkeys and with CN data from an additional 10 monkeys thathad normal nerves (Xu and Wall, 1999). In CN studies, systematicgrids of recording sites were made around rostrocaudal levelswhere the nucleus and its pars rotunda subdivision are largest.These levels contain the main part of the CN hand representation(Florence et al., 1991; Xu and Wall, 1996, 1999) and thus themain ascending lemniscal substrates for hand inputs. Area 3b datawere derived from 12 monkeys, 5 that had contralateral acute sectionsof the median and ulnar nerves (Kolarik et al., 1994) and 7 thathad normal nerves (Wall et al., 1993; our unpublishedobservations).

Except for differences in surgeries to expose the medulla versus cortex, all monkeys were prepared with comparable proceduresthat have been described previously (Wall et al., 1993; Kolariket al., 1994; Xu and Wall, 1996, 1997a, 1999). Briefly, for initialsurgical and subsequent recording procedures, monkeys were maintainedat a surgical plane of anesthesia with a mixture of ketamine hydrochloride(25-50 mg/kg, i.m.) and acepromazine (0.4-0.8 mg/kg, i.m.). Afterthe head was secured in a frame, the dorsal medulla or parietalcortex was exposed, covered with silicone fluid, and photographed(30-40×).

Nerve injury. Transection of the median and ulnar nerves was performed as described previously (Kolarik et al., 1994). Oneor two incisions were made along the wrist, the median and ulnarnerves were localized and freed from surrounding tissue, and aloop of suture was passed beneath each nerve. Incisions were closedexcept for openings for each loop. Both nerves were subsequentlyrapidly and simultaneously transected by elevating the loops andcutting the nerves with scissors. From previous nerve recordings(Wall et al., 1993), and from the locations of residual fieldsafter injury (see Results), this injury denervated all glabrousskin and parts of the dorsal (hairy) surface on the little fingerand adjacent edge of the hand. Radial nerve innervation to theother parts of the dorsal hand remainedintact.

Neurophysiological recording, stimulation, and receptive field definition. Tungsten or stainless steel microelectrodes (1-4M $Omega$ ) were inserted perpendicular to the dorsal surface of the medullaor area 3b, and the entry points were marked on the photograph.For CN recording, up to four electrodes that were coupled in arow with tips aligned and 100-200 µm apart were used to samplemediolateral rows of recording sites. Use of coupled electrodessimplified reconstructions of tracks because distances betweenelectrodes were fixed and measurable. Receptive fields were definedfrom multiunit and occasionally single unit activity encounteredat successive dorsal-to-ventral recording sites. When responsesindicated that electrodes had advanced below the CN, marking lesionswere made at selected sites (3-8 µA, 2-4 sec). These procedureswere reiterated with the aim of producing a transverse plane gridthat sampled responses at intervals of ~50-100 µm in the dorsoventraland 100-200 µm in the mediolateral dimensions. The multiunit methodswere capable of detecting changes in tactile responsiveness (e.g.,responsive vs nonresponsive) and extents or locations of receptivefields with recording site shifts of 50-70 µm, indicating thatneurons were sampled over a diameter of 100-140 µm (or area of0.008-0.015 mm²).

The procedures for area 3b recording have been described (Wall et al., 1993; Kolarik et al., 1994). Area 3b hand maps in fourmonkeys with acutely sectioned nerves and three monkeys with normalnerves were studied in detail (Wall et al., 1993; Kolarik et al.,1994). In these cases, recording sites were uniformly spaced ~200-300µm apart across the entire area 3b hand representation. In oneadditional monkey with acute injury and four monkeys with normalnerves, delimited parts of the area 3b hand map were studied indetail. In all area 3b studies, receptive fields were definedfrom multiunit, or occasionally single unit, activity encounteredaround the middle layers, 400-900 µm below the surface. Afterrecording, selected sites were marked to permit reconstructionof recording sites with respect to the histological borders ofarea3b.

Equivalent stimulation procedures and criteria for defining tactile receptive fields were used in the CN and area 3b. As describedpreviously (Wall et al., 1993; Kolarik et al., 1994; Xu and Wall,1996, 1999), stimuli were hand-delivered punctate contacts orbrushes of the skin, hairs, or deep tissues. To define cutaneousreceptive fields, light tactile stimuli were presented to activatelow-threshold cutaneous inputs directly beneath the probe. A cutaneousreceptive field was defined as the area of skin from which responseswere elicited to light cutaneous stimulation; i.e., both preinjuryand postinjury fields reflected the total skin area that evokedaction potentials. Each field was judged to reflect a maximal,low-threshold cutaneous field area. These maximal fields are somewhatlarger than minimal cutaneous fields as defined in other studiesin squirrel monkeys (Sur et al., 1982; Merzenich et al., 1987).

The procedures for delineating and measuring tactile receptive fields on the hand have been described (Xu and Wall, 1999).Fields were drawn on diagrams that illustrated the borders ofeach hand part and measured with a computerized planimeter. CNand area 3b fields were normalized in the same way to percentagesof the total hand surface. These procedures permitted comparisonsof the relative sizes of CN and area 3b fields without confoundsattributable to differences in absolute hand size. Receptive fielddata were mainly derived from multiunit responses; however, singleunit fields were also encountered and were similar to multiunitfields.

Histological reconstructions and delineation and measurement of representations. These procedures have been described (Wallet al., 1993; Kolarik et al., 1994; Xu and Wall, 1996, 1999).In brief, after recording, monkeys were overdosed with barbiturateand perfused with saline and paraformaldehyde. In all CN experiments,the medulla was frozen and cut into 50-µm-thick transverse sections.All sections were co-processed with cytochrome oxidase (CO) toidentify CN borders and CO dense patches in the pars rotunda,and with the Prussian blue method to distinguish iron depositsmade with stainless steel microelectrodes from electrolytic marksmade with tungsten microelectrodes. Grids of CN recording siteswere reconstructed using depth estimates from microdrive readingsand camera lucida images of histologically observed track artifactsand fiducial marks. In all area 3b experiments, the parietal cortexwas frozen and cut into 50-µm-thick parasagittal sections. Allsections were stained with cresyl violet, and the architectonicborders of area 3b were related to track artifacts and fiducialmarks. All CN and area 3b neuronal data were histologically confirmedto be in thesestructures.

CN and area 3b responses were used to define representations of the hand and adjacent parts of the body (Wall et al., 1993;Kolarik et al., 1994; Xu and Wall, 1996, 1999). Briefly, eachrecording site was labeled according to its receptive field location.Borders delimiting groups of recording sites with fields on atargeted skin area(s) (e.g., digits, dorsal hand, forelimb) wereplaced either midway between sites with fields that did and didnot include the targeted area(s) or, alternatively, on sites havingfields that partly included the targeted area(s). The same bordercriteria were applied in the CN and area 3b, thus providing ameans of comparing spatial sizes, continuities, and adjacenciesof representations of particular skin areas. Areas within bordersof representations were measured with a computerized planimeter.Only fully mapped representations of the hand in area 3b and inCN transverse planes were used for analyses of representations(postinjury: CN = 11 maps, area 3b = 4 maps; normal: CN = 14 maps,area 3b = 3 maps). For analyses in which extensive bracketingof representations was not necessary (e.g., analyses of receptivefields), data from maps that were incompletely defined were usedto supplement data from full maps (postinjury: CN = 6 maps, area3b = 1 map; normal: CN = 5 maps, area 3b = 4maps).

Previous studies of CN organization in normal squirrel monkeys demonstrated that tactile inputs from all or most of the handsurface map onto a transverse plane through the pars rotunda andthat similar organization is repeated in planes at different rostrocaudallevels (Florence et al., 1991; Xu and Wall, 1999). A similar conceptapplies to hand maps in tangential planes parallel to the layersof area 3b. Thus, two-dimensional hand maps through the respectivetransverse and tangential planes of the CN and area 3b provideestimates of spatial properties of maps in these structures. Theresults define organization in theseplanes.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

CN postinjury organization

Receptive fields and tactile responsiveness
Median and ulnar nerve section, which denervated the glabrous hand, triggered rapid shifts in locations of cutaneous receptivefields and losses of tactile responses. In experiments in whichthe same or similar neurons were recorded before and after injury,CN sites with preinjury tactile responses on the hand underwentreceptive field shifts from the glabrous to dorsal hand, acrossthe dorsal hand, or infrequently, from the hand to forelimb. Preinjuryneuronal responses that were restricted to glabrous skin shiftedto dorsal skin fields within minutes and remained apparent orcontinued to develop over the next several hours (Fig. 1). Theseshifts commonly involved changes from the glabrous to dorsal sideof the same and/or adjacent digit(s), suggesting that preinjuryand postinjury fields were in rough register (Fig. 1A, 4, 7, 8,11; 1B, 1, 5, 6, 8). In contrast to neurons that had shifted fields,neurons at other CN sites lost tactile responsiveness after injury(Fig. 1) (see below).

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Figure 1. Shifts in tactile receptive field locations and responsiveness during the first minutes after nerve section. Top, Transverse plane camera lucida drawings of reconstructed tracks in the CN (shaded) of two monkeys (A, B). Hand pictures of the glabrous (left) and dorsal (right) sides of the hand indicate abbreviations for digits (D1-D5), palmar pads (P), and the dorsal hand area opposite the palm (DH). Bottom, The indicated preinjury receptive fields (Pre) were recorded as two coupled electrodes were advanced stepwise from dorsal (i.e., sites 1 + 9 in A and 1 + 8 in B) to ventral (i.e., immediately below sites 8 + 16 in A and 7 + 14 in B) locations in the preinjury glabrous hand representation. Nerve section was then performed (each nerve was previously looped with suture to permit simultaneous sectioning), and postinjury responses (Post) were assessed as the electrodes were immediately retracted stepwise up the same tracks over the subsequent 34-49 min (Min). Note (1) preinjury tactile receptive fields that were restricted to glabrous skin shifted to dorsal hand skin within minutes, (2) shifts frequently involved changes from the glabrous to dorsal side of the same and/or adjacent digit(s), and (3) some sites became unresponsive to tactile stimuli (U). Scale bar, 500 µm.

The representation of the hand and sizes of receptive fields on the hand
In experiments in which CN planes were mapped in high detail after injury (Fig. 2), receptive field shifts to the dorsal handwere further reflected by increased incidences of dorsal handfields and by consistent changes in the location, continuity,size, and somatotopic organization of CN representations of thedorsal hand. In transverse planes of the CN, the representationof the glabrous hand is normally a large, continuous representationoccupying all or most of the pars rotunda, distinguished by itsdensely stained CO patches; in contrast, the representation ofthe dorsal hand is normally distributed in discontinuous smallareas, mainly along the lateral, or lateral and medial, edgesof the glabrous hand representation (Fig. 3E) (Xu and Wall, 1996,1999). After injury, the CN dorsal hand representation consistentlybecame more continuous and enlarged by approximately 2.4 timesfrom a normal mean of 14.6% to a postinjury mean of 35.1% of theCN transverse plane (t[11] = 4.1; p < 0.002) (Fig. 3, compareE, A-D,F; Table 1). These enlarged dorsal hand representationsconsistently spanned pars rotunda patches in central CN locationswhere the glabrous hand representation is normally located (Figs.3,4).

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Figure 2. Postinjury recording sites and related receptive fields for a representative CN transverse plane map. Top left, Transverse plane camera lucida drawing of the CN (shaded). Vertical lines indicate 15 electrode penetrations, small black dots indicate CN recording sites, hash marks indicate sites outside the CN, and larger black and white circles indicate marker lesions (dorsal = up; medial = right). Scale bar, 1 mm. Bottom, Tactile receptive fields (black areas) for CN sites with corresponding number. Numbered sites for which no field is shown were not responsive to tactile stimulation. Note that neurons with tactile fields involving the hand were in central CN locations (e.g., tracks below sites 14, 26, 38, and 50), and all hand fields were on the dorsal (hairy) hand.

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Figure 3. Consistently observed features of hand maps in the CN (A-F) and area 3b (G, H). Note that (1) normally in both the CN (E) and area 3b (G), the glabrous representation (gray) is continuous and large, whereas the dorsal representation (striped) occupies adjacent, discontinuous, small patches, and (2) after injury, the dorsal representation in the CN (striped) enlarged and became continuous across central CN locations normally representing glabrous inputs (A-D and F vs E), whereas the dorsal representation in area 3b also enlarged into area 3b locations normally representing glabrous inputs, but remained discontinuous and patchy (striped; H vs G) (see Fig. 7 for further examples). For CN maps, dorsal = up and medial = right. Scale bar, 1 mm. For area 3b maps, anterior = up and medial = right. Scale bar, 1 mm.


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Table 1. Mean (SD) sizes of representations as percentages of CN transverse areas in normal and postinjury animals

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Figure 4. Cytochrome oxidase (CO) stained transverse section of the brainstem showing the CN (solid border) and the postinjury dorsal hand representation (areas indicated by * between dotted lines). The postinjury dorsal hand representation occupies pars rotunda locations containing CO dense patches that are normally associated with glabrous hand inputs (Xu and Wall, 1999). Arrows indicate marker lesions at the bottoms of some of the penetrations made in this transverse plane. Dorsal = up; medial = right.

The normal CN hand map occupies a mean area of 53.1% of CN transverse planes (Table 1). Thus, relative to this area, thedorsal hand representation expanded from a normal mean area equivalentto 27.4% (i.e., 14.6/53.1) to a postinjury mean area equivalentto 66.1% (i.e., 35.1/53.1) of the mean size of normal CN handmaps (Fig. 5). These findings, and the above changes in locationand continuity of the dorsal hand representation, suggest thatapproximately two-thirds of the normal CN hand representationwas taken over by dorsal hand inputs. This postinjury expansionwas seen in most CN planes; i.e., dorsal hand representationsthat were at or above the upper 95% confidence interval size ofnormal dorsal hand representations were seen in 9 of 11 postinjuryCN maps (Fig. 5).

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Figure 5. Normal and postinjury sizes of dorsal hand representations in the CN and area 3b. For CN measures (left), NORMAL MEAN indicates mean and 95% confidence interval sizes of normal CN dorsal hand representations [14 maps; Xu and Wall (1999)]; POSTINJURY 1-11 and MEAN indicate postinjury sizes of dorsal hand representations for 11 maps and their mean. For area 3b measures (right), NORMAL MEAN indicates mean and 95% confidence interval sizes of normal area 3b dorsal hand representations [3 maps; Wall et al. (1993)]; POSTINJURY 1-4 and MEAN indicate postinjury sizes of dorsal hand representations for four maps and their mean. See Results for details.

Representations of inputs from subregions of the dorsal hand underwent variable changes in size. Expansions of the representationsof the digit skin and radial (thumb) half of the dorsal hand werelarger than expansions of representations of complementary regionson the proximal and ulnar (little finger) half of the dorsal hand(Fig. 6A). The smaller enlargement of the ulnar, as compared withthe radial representation, likely reflects the partial denervationof the ulnar dorsal hand attributable to the ulnar nerve injury.Consistent with this, receptive fields in each postinjury CN maptypically covered most (mean = 75%) of the dorsal hand surface;however, inputs from all or most of digit 5 and/or the adjacentulnar hand, which are commonly part of the ulnar nerve innervationterritory, were usually not represented in CN maps (Fig. 6B).The differences in enlargements of representations of digit versusproximal hand regions are not attributable to differential denervationbecause the ulnar sides of both regions were denervated. Together,these findings suggest that CN representations of dorsal handsubregions did not enlarge uniformly, partly because of denervationgradients and partly because of other factors that remain lessclear.

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Figure 6. Analyses of CN and area 3b representations of subregions of the dorsal hand. A, Enlargement ratios (Postinjury/Normal) for representations of distal, proximal, radial, and ulnar subregions. Note that in both the CN and area 3b, representations of distal (i.e., digit) and radial subregions had larger postinjury enlargements than proximal and ulnar subregions. B, C, Examples of composite receptive field areas (hatching) that were represented in each of three CN (B) and three area 3b (C) postinjury maps. Note that (1) similar locations and extents of the dorsal hand were represented in individual maps at both levels, and (2) the ulnar edge was usually not represented (because of ulnar nerve section). See Results for further details.

Several features of somatotopic organization were consistently observed in postinjury CN representations of the dorsal hand.(1) As described above, acute injury resulted in expression ofa largely continuous postinjury dorsal hand representation. Thisdecreased the somatotopic fracturing inherent in the normal discontinuous,patchy representation of this skin. (2) Tactile inputs from thedigits tended to activate neurons at more dorsal CN sites, whereasinputs involving more proximal locations on the back of the handusually activated more ventral sites (Fig. 7A-F). (3) Inputs fromthe radial half of the dorsal hand usually activated neurons atmore lateral to lateroventral sites, whereas ulnar inputs usuallyactivated more mediodorsal sites (Fig. 8A-F). (4) CN areas withinputs from different dorsal digits were represented in a partiallyshifted but overlapping manner. Digit 1 was represented most lateroventrally,digit 5 (when present) or digit 4 was represented most mediodorsally,and intervening digit representations overlapped in between (Fig.9A-C). (5) Finally, postinjury CN somatotopic gradients for distal-proximal,radial-ulnar, and digit inputs were in rough register with somatotopicgradients of normal inputs from these hand parts (Figs. 7-9).

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Figure 7. Somatotopic gradients of receptive fields on the dorsal digits and proximal dorsal hand in CN (A-H) and area 3b (I-L) maps. A-F, Within postinjury CN dorsal hand representations (dark shading), recording sites with fields on the digits ( $open circle$ ) typically occupied more dorsal locations, whereas sites with fields on the proximal hand () or that extended from the digits onto the proximal hand ( $closed-open-circle$ ) typically occupied more ventral locations. G, H, Normal CN maps of the glabrous (light shading) and dorsal (dark shading) hand have a similar gradient. I-L, Analogous somatotopic gradients across the distal-proximal dorsal hand are seen in postinjury (I-K) and normal (L) dorsal hand representations (dark shading) in area 3b. For CN maps, dorsal = up and medial = right. Scale bar, 1 mm. For area 3b maps, anterior = up, medial = right. Scale bar, 1 mm. In all maps, equal density recording sites in white areas are not indicated.

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Figure 8. Somatotopic gradients of receptive fields on the radial and ulnar dorsal hand in CN (A-H) and area 3b (I-L) maps. A-F, Within postinjury CN dorsal hand representations (dark shading), recording sites with fields on the radial hand () typically occupied more lateral to lateroventral locations, whereas sites with fields on the ulnar hand ( $open circle$ ) or that extended from the radial to ulnar hand ( $circle-filled-left$ ) typically occupied more mediodorsal locations. G, H, Normal CN maps of the glabrous (light shading) and dorsal (dark shading) hand have a similar gradient. I-L, Analogous somatotopic gradients across the radial-ulnar hand are seen in postinjury (I-K) and normal (L) dorsal hand representations (dark shading) in area 3b. For CN maps, dorsal = up and medial = right. Scale bar, 1 mm. For area 3b maps, anterior = up and medial = right. Scale bar, 1 mm.

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Figure 9. Somatotopic organization of digit representations in the CN (A-D) and area 3b (E-H). A-C, Shading and labeling of areas in three postinjury CN maps indicate postinjury representations of dorsal digits (Dor D) 1, 3, and, where seen, 5 in the first column, and of dorsal digits 2 and 4 in the second column. Note (1) the partially shifted and overlapping locations of these representations from D1 lateroventrally to D5 (or 4) mediodorsally and (2) their rough in-register relation to normal glabrous digit representations (D). E-G, Shading and labeling of areas in three postinjury area 3b maps indicate postinjury representations of dorsal digits 1 and 3 in the third column and 2 and 4 in the fourth column. Note that, similar to the CN, postinjury area 3b representations of dorsal digits occupied areas that were partially shifted and overlapping from D1 laterally to D4 medially and were in rough register with normal glabrous digit representations (H). For CN maps, dorsal = up and medial = right. Scale bar, 1 mm. For area 3b maps, anterior = up and medial = right. Scale bar, 1 mm.

The above changes did not lead to major changes in sizes of CN dorsal hand receptive fields. Postinjury dorsal fields, likenormal dorsal fields, involved one or more digits and/or an adjacentarea on the dorsal hand (Fig. 10A,B) and occupied a mean area of6.7% of the hand surface. This is similar to the size of normaldorsal hand fields (mean = 7.7%; t[11] = 0.26, p = 0.80) (Fig.11) (Xu and Wall, 1999).

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Figure 10. Tactile receptive fields on the hand, as seen in normal (A) and postinjury (B) conditions in the CN and in the postinjury condition in area 3b (C). See Results for details.

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Figure 11. Postinjury and normal CN receptive fields on the dorsal hand were similar in size. Flower petal graph on the left shows sizes of all postinjury dorsal hand receptive fields in five monkeys (1 petal in each flower = 1 receptive field). The bottom line indicates mean size, and the top line indicates the upper 95% confidence interval distinguishing the main part of the sample from outlier fields. The histogram on the right indicates mean and 95% confidence interval (CI) sizes for normal dorsal hand fields from 10 monkeys.

Forelimb and other representations
Preinjury receptive fields on the glabrous hand occasionally shifted to forelimb locations after injury; however, the postinjurysizes of the forelimb and other representations were similar tonormal [postinjury: forelimb mean = 23.4% (SD = 2.2) and trunk-face-hindlimbmean = 13.9% (SD = 2.1) of CN transverse area; normal: forelimbmean = 27.6% (SD = 8.1) and trunk-face-hindlimb mean = 10.5% (SD= 4.9) of CN transverse area (Table 1)]. In addition, postinjuryforelimb and other representations were in their normal lateraland medial CN locations and had a normal somatotopic organization,with representations of the forelimb, shoulder, neck, and facelocated lateral to the hand representation, and inputs from theforelimb, trunk, and proximal hindlimb located medial to the handrepresentation (Fig. 12) [compare with Xu and Wall (1999)]. Takentogether, these results suggest that forelimb and other nonhandtactile representations did not undergo major changes. In viewof the above magnitude and consistency of changes in dorsal handrepresentations, these findings indicate that there was an anisotropyin CN reorganization mechanisms that favored expansion of dorsalhand over forelimb or other, cutaneous inputs.

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Figure 12. Postinjury CN representations of tactile inputs from the forelimb-trunk-face in two maps (A, B). Top, Camera lucida tracings of two CNs. Dorsal = up; medial = right. Scale bar, 1 mm. Stippling indicates CN areas that contained recording sites with forelimb, trunk, and face receptive fields. These areas are located lateral and medial to the dorsal hand representation (white) and adjacent to areas with recording sites that were not responsive to tactile stimulation of the skin (black). Middle, Composite of the receptive field areas of all recording sites with forelimb-trunk-face fields that were located in the area lateral to the hand representation for the above CN. In each case, note that this skin included the forelimb, shoulder, neck, and face. Bottom, Composite of the receptive field areas of all recording sites with forelimb-trunk fields that were located medial to the hand representation for the above CN. In each case, note that this skin included the forelimb, trunk, and proximal hindlimb.

Cutaneously unresponsive areas
As indicated above, injury led to a loss of low-threshold cutaneous responsiveness at some CN recording sites. Normally, amean of 8.8% of the CN transverse plane area is occupied by sitesthat are not responsive to low-threshold tactile stimulation ofthe skin (Table 1). These sites are located outside the handrepresentation, usually near the CN borders. After injury, cutaneouslyunresponsive areas enlarged to a mean of 27.6% of the CN transversearea, an increment of 18.8% above normal (t[11] = 3.3, p = 0.008)(Table 1). This increment involved CN locations where the glabroushand is normally represented and locations around postinjury representationsof the dorsal hand (Figs. 1, 12). Given that the normal hand representationoccupies a mean area of 53.1% of the CN transverse area (see above),this increment is equivalent to ~35.4% (i.e., 18.8/53.1) of thenormal CN hand representation. Although neurons at these siteswere not responsive to tactile stimulation of the skin, they wereoften responsive to harder tap stimuli, to stimulation of deeptissues, and/or to movement of joints. Taken together with theabove results on the dorsal hand and forelimb representations,these findings suggest that, after injury, approximately two-thirdsof the normal CN hand representation was activated by dorsal handinputs, and approximately one-third lost responsiveness to lowthreshold cutaneous inputs. In contrast, representations of tactileinputs from the forelimb and other body parts either did not changeor had small, less consistentchanges.

Relationships between CN and area 3b postinjury organization

Immediate postinjury changes have been defined in area 3b after this injury (Kolarik et al., 1994), but no attempts have beenmade to relate acute cortical and subcortical organization. Assummarized next, there were interesting similarities, and differences,in postinjury organization in the CN and area 3b (Table 2).


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Table 2. Similarities and differences in acute postinjury CN and area 3b organization

Similarities in CN and area 3b organization

Time course for changes
At both CN and area 3b levels, initial changes in receptive fields were seen within minutes, and related changes in representationswere apparent within hours after this injury (Fig. 1) [and seeKolarik et al. (1994)]. These findings suggest that initial CNand area 3b functional changes occur concurrently (Table 2).

Hand receptive fields
At both levels, the main postinjury change in tactile receptive fields involved shifts from preinjury glabrous to postinjurydorsal hand locations. Postinjury dorsal receptive fields occupiedsimilar combinations of hand regions at both levels (Fig. 10B,C).

Hand representations
Postinjury CN and area 3b representations of the hand were similar in several ways (Table 2). First, at both levels, enlargementof the normally small dorsal hand representation was the predominantchange. Second, similar locations and extents of the dorsal handwere represented in the postinjury hand representation at eachlevel; in addition, each level had relatively larger expansionsof representations of the digits and radial dorsal hand than ofthe complementary proximal and ulnar hand (Fig. 6). Third, postinjurydorsal hand representations at both levels had analogous somatotopicgradients. This was reflected, for example, by the distributionsof CN and area 3b recording sites with inputs from proximal-digit(Fig. 7, compare A-F, I-K) and radial-ulnar (e.g., Fig. 8A-F vsI-K) hand regions. Finally, both levels had partially shiftedand overlapping postinjury representations of dorsal digits thatwere in rough register with normal glabrous digit representations(Fig. 9). Taken together, these similarities suggest that somepostinjury features of CN dorsal hand representations were consistentlypreserved in area 3b (Table 2).

Forelimb representations
This injury resulted in a small expansion of forelimb inputs into a mean area of 5% of the area 3b hand representation (Kolariket al., 1994). In the CN, receptive fields occasionally shiftedfrom glabrous hand to forelimb locations; however, postinjuryCN representations of the forelimb were not larger than normal(see above). Given this and the small extent of the area 3b changes,it would appear that any differences in enlargements of CN andarea 3b forelimb representations were small. Thus, despite similaradjacencies of forelimb and hand inputs at both levels, forelimbrepresentations did not enlarge like dorsal hand representations(Table 2). This suggests that CN and area 3b reorganizationsshared a similar anisotropy that led to larger expansions of dorsalhand inputs than forelimbinputs.

Differences in CN and area 3b organization

Sizes of hand receptive fields
The size distributions of postinjury CN and area 3b dorsal hand fields overlapped; however, area 3b fields were smaller interms of mean (3b: 4%; CN: 6.7%; t[7] = 2.7; p < 0.03), mode (3b:2%; CN: 5%), and upper 95% confidence interval (3b: 11.6%; CN:16.3%) sizes (Fig. 13). In addition, area 3b had a lower incidenceof multidigit dorsal fields (3b: mean = 23.9%; CN: mean = 48%;t[7] = 3.8; p < 0.007). Taken together, these findings indicatethat postinjury fields on the dorsal hand tend to be smaller inarea 3b (Table 2). This suggests that postinjury tactile fieldsundergo sharpening transformations between the CN and area 3b.

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Figure 13. Histograms of the sizes of postinjury dorsal hand receptive fields in the CN (top) and area 3b (bottom). The distributions of CN and area 3b fields overlap; however, area 3b fields were smaller in terms of mean (arrows), mode (CN = 5%, area 3b = 2%), and upper 95% confidence (arrowheads) sizes. See Results for details.

Hand representations
Postinjury CN and area 3b dorsal hand representations differed in the following ways (Table 2). First, representations inarea 3b were consistently discontinuous, occupying three to sixpatches, whereas CN representations were more continuous (Fig.7, compare I-K, A-F). Under normal conditions, the dorsal handrepresentation is discontinuous at both levels (Fig. 7G,H,L);thus, injury resulted in greater CN than area 3b merging of thenormal discontinuous representation of the dorsal hand (Table2). Second, a larger percentage of the hand map was activatedby dorsal hand inputs in the CN than in area 3b. The area 3b representationof the dorsal hand normally occupies a mean area of 15% of thearea 3b hand representation, whereas the CN representation normallyoccupies a mean area of 27% of the CN hand representation (Fig.5). After injury, the mean dorsal hand representations expandedby approximately 2.5 times at both levels, which resulted in theseinputs being represented in a mean area equal to 66% of the normalCN hand map area but only 37% of the normal area 3b hand map area(Fig. 5). Thus, postinjury dorsal hand inputs in the CN activateda larger percentage of the hand map space than the same inputsin cortex (Table 2). With few exceptions, this difference wasconsistently seen. For example, 9 of 11 CN postinjury dorsal handrepresentations were larger than the largest postinjury representationin area 3b (Fig. 5). These findings suggest that relatively largeand continuous postinjury CN representations of the dorsal handwere attenuated or incompletely expressed as relatively smaller,less continuous representations in area 3b. Thus, some featuresof CN hand representations were transformed before being expressedin area3b.

Cutaneously unresponsive areas
Denervation of the glabrous hand resulted in acute losses of tactile responses at both levels; however, different extentsof loss occurred at each level. Neurons at all recording sitesin the area 3b hand representation are normally responsive totactile inputs, whereas after injury a mean area of 58.5% (SD= 8.3) of this representation became unresponsive to tactile inputs(Kolarik et al., 1994). In contrast, the CN had postinjury incrementsin tactilely unresponsive sites that involved a mean area equalto 35.4% of the normal CN hand map (see above), indicating thatCN maps underwent less extensive losses of tactile responsivenessthan area 3b maps (Table 2). These results further support theview that changes in CN tactile input organization were not fullyexpressed in area3b.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The results suggest that the CN of adult monkeys undergoes rapid functional changes after hand injury and that concurrentchanges in area 3b reflect preservations and transformations ofCN changes. These findings, their limitations, and their significanceare discussed inturn.

How do features of CN tactile input organization change immediately after injury?

Several CN changes emerged after this injury. First, CN neurons lost glabrous receptive fields and within minutes acquireddorsal hand fields or, less frequently, lost tactile responsiveness.Second, the dorsal hand representation enlarged, became more continuous,and occupied CN locations where the glabrous hand is normallyrepresented. Third, enlarged dorsal hand representations weresomatotopically organized, with distal-to-proximal inputs activatingdorsal-to-ventral CN locations, radial-to-ulnar inputs activatinglateral-to-medial locations, and representations of dorsal digitsactivating partially shifted but overlapping areas that were inrough register with normal representations of glabrous digits.Fourth, other representations did not undergo major changes, indicatingthat there were anisotropies in the capacities of hand and othertactile inputs to reorganize. Finally, this injury deprived ~74%of the CN hand map of normal tactile inputs; approximately two-thirdsof the map became driven by radial nerve inputs from the dorsalhand, whereas about one-third lost tactile responsiveness. Thus,CN tactile responsiveness, receptive fields, somatotopic organization,and properties of representations (i.e., location, size, continuity)clearly changed within minutes to hours after this injury. Weadd the cautionary note that these changes were defined in a limitednumber of CN maps; however, they appeared consistently in mapsof different monkeys. These findings extend previous results thatindicate that CN hand representations in monkeys rapidly changeafter injury (Xu and Wall, 1997a).

There is substantial disagreement about how acute peripheral manipulations in adults affect CN organization. In this regard,acute loss of CN tactile responses, but no receptive field reorganization,occurred after lidocaine block of nerves to fingers of raccoons(Northgrave and Rasmusson, 1996) and after cold block of forepawnerves in cats (Zhang and Rowe, 1997). In the only previous studyof acute injury, Zhang and Rowe (1997) tested several CN neuronsafter section of forepaw nerves and got similar negative results.These findings are consistent with losses of tactile responsesin the present study. In contrast, Pettit and Schwark (1993, 1996)assessed CN tactile responses after subcutaneous forepaw injectionsof lidocaine or capsaicin and found rapid field changes in alltested neurons. These changes are consistent with the presentshifts in fields [for similar mixed results in the gracile andtrigeminal nuclei, see Dostrovsky et al. (1976); Millar et al.(1976); McMahon and Wall (1983); Waite (1984); Panetsos et al.(1995, 1997); Faggin et al. (1997)].

There currently is no explanation for the above differences in results. Taken together with other data, the present findingssuggest that one factor in acute CN reorganization is how themanipulation interacts with residual CN afferents. In this regard,the present findings of rapid glabrous-to-dorsal field shiftscorrelate with anatomical and functional findings that dorsaland glabrous afferents normally terminate in closely adjacentCN CO patches (Florence et al., 1991; Xu and Wall, 1999). Moreover,preliminary findings further indicate that terminations of dorsalhand afferents span larger extents of the CN than normal functionalrepresentations of these afferents, thus suggesting that somedorsal afferents are normally not functionally expressed (Xu andWall, 1997b). In contrast, the lack of rapid field changes afterblockade of inputs from a finger in raccoons correlates with anatomicalfindings that afferents from each finger terminate in separateCN compartments (Rasmusson, 1988; Northgrave and Rasmusson, 1996).Thus, injury of glabrous inputs in monkeys may leave normallyunexpressed dorsal inputs as available substrates for CN synapticchange mechanisms, whereas blockade of inputs from a finger inraccoons may leave no comparable substrates. Other factors, includingthe nature of the peripheral manipulations, may also contribute(Northgrave and Rasmusson, 1996; Zhang and Rowe, 1997).

The present findings provide insight into normal mechanisms of CN processing of hand inputs. For example, the rapid fieldshifts suggest that normal glabrous fields are not "hardwired"but are constructed physiologically by sharpening mechanisms thatsuppress dorsal hand inputs. At the scale of representations,the replacement of the representation of the glabrous surfacewith a colocalized large, continuous, somatotopic, and roughlyin-register representation of the dorsal surface suggests thatCN substrates contain overlapping representations of both surfacesthat are in a flexible state but normally set to express the glabrousrepresentation. There is a recognition that the CN normally transforms,rather than simply relays, tactile information from the hand;however, these transformations are not understood. The presentfindings suggest that CN transformations sharpen receptive fieldsand, on a larger scale, selectively promote (e.g., glabrous) andsuppress (e.g., dorsal) full expression ofrepresentations.

How are initial changes in CN and area 3b hand representations related?

Few studies have compared brainstem and cortical organization after acute peripheral manipulations in adults, and no consensushas emerged from the findings. In the only previous study involvingthe CN, finger denervations in raccoons caused acute changes insomatosensory (SI) cortex and thalamus but not in the CN (Turnbulland Rasmusson, 1990; Rasmusson et al., 1993; Northgrave and Rasmusson,1996). In contrast, Panetsos et al. (1995) recorded simultaneouschanges in receptive fields in the gracile nucleus and SI cortexof rats after lidocaine blockades of hindpaw inputs. Similaritiesobserved in receptive field changes at paired gracile and corticalsites suggested that brainstem changes were preserved in cortex.More recently, Faggin et al. (1997) [also see Nicolelis (1997)]observed new whisker responses from simultaneously recorded sitesin the trigeminal nucleus and SI cortex after lidocaine injectionsin face regions of rats. They also observed mismatches in thesets of whiskers that elicited new responses at each level, suggestingthat cortical changes were not just preservations of brainstemchanges.

The present findings indicate that CN and area 3b postinjury changes were similar in some respects but different in others(Table 2). Similarities included (1) the time course of fieldshifts, (2) expansions of normally small dorsal representationsinto glabrous representation locations in a somatotopic manner,(3) involvement of afferents from comparable regions of the dorsalhand, and (4) anisotropies in the capacity of hand versus otherinputs to reorganize. Organization at CN and area 3b levels alsodiffered in that in the CN (1) dorsal hand fields were larger,(2) representations of the dorsal hand were more continuouslydistributed across locations normally having glabrous inputs andinvolved larger extents of the hand map, and (3) cutaneously unresponsiveareas occupied smaller extents of the hand map. Again, we addthe cautionary note that these findings are based on limited numbersofmaps.

In primates, ascending connections through the CN and ventroposterolateral nucleus are essential for normal tactile drivingof area 3b receptive fields on the hand (Jain et al., 1997; Joneset al., 1997). This cortical dependence on lemniscal inputs doesnot appear to be reciprocated; preliminary results suggest thatnormal tactile fields and hand map organization are maintainedin the CN of monkeys after acute lesions of area 3b and parietalcortex (our unpublished observations). Similarly, with or withoutsomatosensory cortex, CN receptive fields undergo comparable rapidchanges after peripheral denervation (Pettit and Schwark, 1993).Thus, tactile driving in area 3b is dependent on CN driving, whichin turn is predominantly dependent on ascendinginputs.

Given this view, our interpretation is that the similarities in CN and area 3b changes reflect partial preservations of CNchanges in area 3b and that rapid area 3b reorganization partlyreflects mechanisms that operate from a distance in the CN. Thesharpening of receptive fields, different spatial properties ofthe dorsal hand representations (size, location, continuity),and differences in tactile unresponsiveness further suggest thatarea 3b changes are not simply copies of CN changes. Our interpretationis that these differences reflect supra-CN (thalamic and cortical)transformations that result in suppression or incomplete reexpressionof CNreorganization.

What mechanisms contribute to these multilevel changes? Calford and Tweedale (1991) proposed that acute area 3b reorganizationafter peripheral deafferentation reflects release of central inhibitionthat is triggered by changes in sensory afferent activity; however,the level(s) of the neuraxis where release mechanisms operatedremained unclear because analysis was restricted to area 3b. FromCN data, Pettit and Schwark (1993, 1996) subsequently suggestedthat changes in afferent activity trigger inhibition release inthe CN (see also Lue et al., 1996; Panetsos et al., 1997). Thepresent findings are consistent with peripherally triggered releaseof central inhibition; in addition, the findings suggest thatrelease of inhibition is graded at CN and higher levels, beinginitially greater in the CN than in area 3b. This could account,for example, for field sharpening between the CN and area 3b andfor concurrent but more limited area 3b enlargements of dorsalhand representations. Thus, a maintained greater, i.e., initiallysmaller, release of inhibition at higher neuraxis levels may partiallyattenuate CN mechanisms of change [for analogous developmentalconsequences after neonatal injury in rats see Stojic et al. (1998)].In addition to release of inhibition, further findings suggestthat sensitization (increased excitation), perhaps via mechanismslike those acting acutely in the spinal cord (Lin et al., 1997;Liu et al., 1997; Ma and Woolf, 1997), and complex bottom-up (e.g.,spinothalamic) and top-down (e.g., corticofugal) interactionsare also likely to contribute (Dykes, 1997; Dykes and Craig, 1998;Ergenzinger et al., 1998).

  FOOTNOTES

Received March 29, 1999; revised May 18, 1999; accepted June 15, 1999.

This work was supported by National Institutes of Health Grant NS21105. We thank Marshonna Forgues and Jessica Nguyen fortheir technical assistance, and Richard Lane and Andrey Stojicfor helpfuldiscussions.
Correspondence should be addressed to J. T. Wall, Department of Neurobiology and Anatomy, Medical College of Ohio, P.O. Box10008, Toledo, OH 43699-0008.

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RESULTS
DISCUSSION
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