A Novel Skilled-Reaching Impairment in Paw Supination on the "Good" Side of the Hemi-Parkinson Rat Improved with Rehabilitation

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The Journal of Neuroscience, January 15, 2003, 23(2):579-586

A Novel Skilled-Reaching Impairment in Paw Supination on the "Good" Side of the Hemi-Parkinson Rat Improved with Rehabilitation
Patricia Vergara-Aragon¹, Claudia L. R. Gonzalez², and Ian Q. Whishaw¹
¹ The Canadian Centre for Behavioural Neuroscience, University of Lethbridge, Lethbridge, Alberta, Canada, T1K 3M4, and ² Departamento de Fisiologia, Facultad de Medicina Universidad Nacional Autonoma de Mexico, Mexico, D.F. CP 07010

  ABSTRACT

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Parkinson's disease is characterized by tremor, rigidity, bradykinesia, and postural abnormalities ascribed to the loss ofnigrostriatal dopamine (DA). Symptoms similar to the human conditioncan be produced in the rat by DA-depleting 6-hydroxydopamine injectionsmade into the nigrostriatal system. After a unilateral lesion,the rat symptoms include sensory and motor impairments and turningbiases reflecting motor abnormalities to the contralateral-to-depletionside of the body. In addition, a number of studies on skilledreaching report impairments in the use of the ipsilateral limb.It is suggested that the ipsilateral deficit is secondary to thecontralateral motor impairments however. Here we re-examine howrats with unilateral DA depletion use their ipsilateral limb forskilled reaching for food. We provide the first description ofan impairment on the ipsilateral-to-depletion side of the bodyof the rat and the first demonstration of amelioration of thedefect using behavioral therapy. Video analysis of rats reachingfor single pellets of food with the ipsilateral limb revealedthat, although limb advancement and food grasping were normal,paw supination and food release to the mouth were impaired. Consequently,the animals were unable to transport a grasped food pellet tothe mouth. Behavioral therapy, consisting of training in a simplerreaching task, strikingly lessened the impairment and improvedreaching movements to the point that the rats could transportthe food to the mouth. The results are discussed in relation topossible causes of the ipsilateral impairment, its treatment,and to relevant research on human Parkinson patients, indicatingthat they display bilateral improvements after unilateraltreatments.

Key words: dopamine depletion; dopamine and skilled movement; 6-hydroxydopamine; nigrostriatal lesion; Parkinson analog rat; Parkinson's disease; Parkinson's disease rat model; skilled reaching; Parkinson's therapy; rehabilitation and Parkinson's disease

  Introduction

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Parkinson's disease is a neurological disorder that affects human movement, balance, and fine motor control, impairments thatare related to the degeneration of dopaminergic (DA) neurons inthe substantia nigra (Martin, 1967; Duvoisin, 1978). The humancondition can be modeled by reducing striatal DA levels in nonhumananimals with the injection of the neurotoxin 6-hydroxydopamine(6-OHDA). The injections are made unilaterally and affect thesensorimotor behavior of the contralateral side of the body, stillallowing the animals to eat and drink and care for themselves(Schultz, 1982; Robinson et al., 1990; Schwarting and Huston,1996; Cenci et al., 2002). The DA-depleted rats display abnormalitiesin turning biases, impairments in locomotion and posture, andimpairments in skilled limb movements that are analogous to humandeficits, so they are useful in assessing therapeuticmeasures.

A method used to evaluate symptoms and treatments in the rat analog is skilled reaching, in which animals reach with a forepawfor food (for review, see Whishaw et al., 1986; Montoya et al.,1990; Whishaw et al., 1997; Nikkhah, 1993). Reaching consistsof a number of movement subcomponents that include adjusting posture,aiming the limb, pronating the paw over the food, grasping, andsupinating the paw during withdrawal to present the food to themouth. After unilateral DA depletion, there is reduced successaccompanied by abnormalities in the way that movements are performed,including changes in posture, shortened reaches, and loss of pronationand supination (Miklyaeva et al., 1994; Whishaw et al., 1997;Metz et al., 2001).

A puzzling finding is that, although severe symptoms are found contralateral to unilateral dopamine depletions, there aresome reports of an ipsilateral impairment. A chronic impairmentoccurs when rats reach for single pellets (Miklyaeva et al., 1994),but the impairment is acute when they reach into a tray for food(Whishaw et al., 1986, 1992). An ipsilateral impairment has beenreported in some studies using the staircase test (Dunnett etal., 1988; Montoya et al., 1990, 1991; Olsson et al., 1995; Whishawet al., 1997; Henderson et al., 1999; Döbrössy et al., 2000)but not in others (Abrous et al., 1993a,b; Nikkhah et al., 1993;Lee et al., 1996; Barnéoud et al., 2000; Glavan et al., 2001;Jeyasingham et al., 2001; Moore et al., 2001). In a study examininglesions given at different ages, an ipsilateral impairment isreported in rats given lesions at 3 d of age but not in rats givenlesions at 7 and 21 d of age (Abrous et al., 1993b). An ipsilateralimpairment is also reported after unilateral ibotenic or quinolinicacid lesions of the striatum (Montoya et al., 1990; Fricker etal., 1996; Jeyasingham et al., 2001) and brain infarction (Grabowskiet al., 1993). Finally, there are also reports that therapiesincluding grafts of embryonic tissue (Montoya et al., 1990) andsubthalamic nucleus lesions (Henderson et al., 1999) improve theipsilateral but not the contralateral impairment, whereas treatmentwith quinpirole aggravates the deficit (Olsson et al., 1995).

Although the ipsilateral impairment has been interpreted as being secondary to postural abnormalities on the side of the bodycontralateral to the lesion, there has been no previous directinvestigation of the cause of the ipsilateral impairment. Giventhe number of reports of an ipsilateral impairment and the potentialfor its remediation, this was the purpose of the presentstudy.

  Materials and Methods

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Subjects
Twenty female Long-Evans rats (University of Lethbridge vivarium) weighing 250-310 gm at the time of surgery were used. Therats were housed in groups of four to six animals in a 12 hr light/darkcycle, with lights on at 8 A.M. and with water available ad libitum.For the skilled-reaching task, the animals were food-deprivedfor 2 weeks before training or testing began. Each day, the ratsreceived supplemental food to maintain their body weight at 95%of the initial body weight. All procedures were approved by theUniversity of Lethbridge animal carecommittee.

Surgery
Thirty minutes before surgery, the rats received desmethylimipramine (25 mg/kg, i.p.; Sigma, St Louis, MO). The rats werethen anesthetized with 60 mg/kg sodium pentobarbital. Twelve ratsreceived 6-OHDA lesions (Ungerstedt, 1971), and eight receivedno additional procedures. The neurotoxic lesions of the nigrostriatalbundle were performed with injections of 6-OHDA hydrobromide (2µl of 4 mg/ml in 0.9% saline with 0.02% ascorbic acid) (Whishawet al., 1986; Miklyaeva et al., 1995) at the following coordinates:4.0 mm posterior to bregma, 1.5 mm lateral to the midline, and8.5 mm ventral to the skull surface, with the skull flat betweenthe lambda and bregma, according to coordinates outlined by Paxinosand Watson (1998). Infusion took place over 5 min, with 5 minfordiffusion.

Video recording
Video records were made with a Sony (Tokyo, Japan) Video 8 CCD VII portable camera with a shutter speed of 1/2000 sec. Illuminationfor high-shutter-speed filming was provided by a two-arm Nikon(Tokyo, Japan) MII cold light source. Frame-by-frame analysisat 30-60 frames per second was provided by a Sony Video 8 recorderor through a computer-based frame grabber (Whishaw and Pellis,1990).

Skilled reaching
Two types of test boxes were used (Fig. 1). Food tray boxes (10 × 18 × 10 cm high) were constructed of Plexiglas with a faceconsisting of 2 mm bars spaced 9 mm edge to edge. A 4-cm-wideand 5-cm-deep tray containing granules of food (20-40 mg of chickfeed) was mounted in front of each box and extended for the lengthof the box. To obtain food, the rat had to reach through the bars,grasp the food, and retract it. The floor was made of grids sothat if a rat dropped the food, it fell through the grids andwas lost (Whishaw et al., 1986).

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Figure 1. Tasks used to assess skilled reaching. A, In the single-pellet task, a rat was required to reach for a single food pellet. The floor of the cage is Plexiglas; therefore, lost food could be retrieved. B, In the food-tray task, the rat could reach through a slot to grasp food from a tray that was filled with food. If the rat dropped the food, it was lost through the floor of the cage.

Single-pellet boxes were made of clear Plexiglas so that the rats could be filmed from any perspective (Whishaw and Pellis,1990; Whishaw, 2000). A box was 25 × 35 × 30 cm high. Five centimetersfrom the side of each front wall was a 1-cm-wide slit that extendedfrom the floor to a height of 15 cm. On the outside of the wall,in front of the slit, mounted 3 cm above the floor, was a 2-cm-wideby 4-cm-long shelf. Food pellets (90 mg of Rodent Chow food pellets;Bioserve Inc., Frenchtown, NJ) were placed in one of two smallindentations on the floor of the shelf. The indentations were2 cm away from the inside wall of the box and were centered onthe edges of the slit through which the rats reached. For eachrat, food was placed in the indentation contralateral to the limbwith which the rat reached. Training was administered in sucha way that when a rat made a successful reach, a short pause precededpresentation of the next food pellet, during which another foodpellet was dropped into the back of the box. This was done toensure that a rat left the food aperture after each reach andrepositioned itself at the food aperture for the next foodpellet.

Scoring reaching success
Reaching performance was scored by counting misses and successful reaches for each limb. If a rat made a reaching movementin which a paw was inserted through the bars/aperture of the cage,the movement was scored as a "reach." If the rat obtained a pieceof food and then consumed it, the reach was scored as a "hit."For each rat, two success scores were obtained: (1) success onfirst reach: if a rat obtained the food pellet on the initiallimb advance, this reach was scored as a hit. If the rat mademore than one limb advance before obtaining the food, this wasnot counted as a hit. (2) Total success: if a rat obtained a pieceof food either on the first limb advance or after a number oflimb advances, the reach was counted as a hit. Success scoreswere computed as follows: success percentage = (number of hits/numberof reaches) ×100.

Qualitative reaching analysis
Reaching movements were analyzed using a rating scale derived from an Eshkol-Wachmann movement notation (Eshkol and Wachmann,1958; Miklyaeva et al., 1994) analysis of reaching. Five reachesfor each limb by each rat were rated for qualitative featuresof the movement (Miklyaeva et al., 1994). The movement ratingscale is shown in Table 1, and 10 component movements of a reachwere rated. (1) Digits to the midline: Using primarily the upperarm, the reaching limb is lifted from the floor so that the tipsof the digits are aligned with the midline of the body. (2) Digitsflexed: As the limb is lifted, the digits are flexed, the pawis supinated, and the wrist is partially flexed. (3) Elbow in:Using an upper arm movement, the elbow is adducted to the bodymidline and the tips of the digits retain their alignment withthe midline of the body. (4) Advance: The limb is advanced directlythrough the slot toward the food target. (5) Digits extend: Duringthe advance, the digits extend so that the digit tips are pointingtoward the target. (6) Arpeggio: When the paw is over the target,the paw pronates from digit 5 (the outer digit) through to digit2, and at the same time, the digits open. (7) Grasp: The digitsclose and flex over the food, with the paw remaining in place,and the wrist is slightly extended to lift the food. (8) SupinationI: As the paw is withdrawn, the paw supinates by almost 90°. (9)Supination II: Once the paw is withdrawn from the slot to themouth, the paw further supinates by ~45° to place the food inthe mouth. (10) Release: The mouth contacts the paw, and the pawopens to release the food.


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Table 1. Skilled reaching rating scale

Each of the movements was rated on a two point scale. If the movement was performed normally, a score of 0 was given. If themovement was abnormal, a score of 1 was given. In cases in whichthere was some ambiguity concerning the occurrence of a movement,or if the impairment was mild, a score of 0.5 wasgiven.

Reaching posture
On each reach, the posture used by the rat was rated on a two point scale (Miklyaeva et al., 1994). If a rat supported itselfon the contralateral-to-reaching paw forelimb and its diagonalhindlimb as the reach was initiated, a score of 0 was given. Ifa rat failed to use this supporting posture, a score of 1 wasgiven.

Cylinder test
The cylinder (30 cm high, 16 cm inner diameter) was made of 3-mm-thick Plexiglas. The cylinder was mounted on a glass tablebeneath which was positioned an inclined mirror (Bland et al.,2001) for filming. A rat was placed in the cylinder and left toexplore for 5 min. Contacts of the forepaws with the wall of thecylinder were counted on a replay of the videotape. If a rat contactedthe wall when it reared, a score of 1 was assigned each time apaw was used for support. Each rat's score was calculated as thepercentage of preference for the paw ipsilateral to the lesionor, for the control rats, the paw that was used for reaching:preference = [ipsilateral paw/(ipsilateral paw + contralateralpaw)] ×100.

Apomorphine-induced rotation
The animals were placed individually into 39-cm-diameter round rotometer bowls for a period of 30 min. A cuff was wrappedaround the trunk of the rat, and this was connected to a leadand swivel, which in turn was connected to a computer. A customcomputer program recorded the turns in the direction ipsilateraland contralateral to the lesion in 5 min intervals. Apomorphine-hydrochloride(0.05 mg/kg, s.c.) was dissolved in 0.9% saline solution with2% ascorbic acid. Ipsilateral and contralateral turns were countedvia a microcomputer and, using previous criteria, the turningbias was used as one of the measures of lesion size (Marshalland Ungerstedt, 1977; Hefti et al., 1980)

Histology
After behavioral testing, animals were anesthetized and perfused through the heart with a 0.9% sodium chloride solution andpicric acid (Lana's fix). The brains were cut in 50 µm sectionson a vibratome and mounted on gelatin-coated slides. For tyrosinehydroxylase (TH) immunocytochemistry, the sections were washedin 1 M phosphate buffer and then incubated overnight at room temperaturewith anti-TH monoclonal antiserum (1:10,000; Sigma). The sectionswere processed by the ABC method (Vectory, Vectastain; VectorLaboratories, Burlingame, CA) with anti-mouse antiserum IgG andhorse serum and reacted with 3,3'-diaminobenzidine tetrahydrochloride(0.06%), hydrogen peroxide (0.03%), and nickel solution. Somesections were processed to control for either monoclonal antiserumor antibody stain (Lee et al., 1996).

Statistical analysis
Statistical analysis was performed using ANOVA with follow-up Newman-Keuls tests (Abacus Concepts, Calabasas, CA). Differencesin between-group comparisons were assessed with unpaired t tests,with p < 0.05 set as the significancelevel.

Procedure
The rats were deprived of food for 2 weeks before the commencement of training in the single-pellet task. Training continueduntil the animals were consistently reaching. Thereafter, eachrat reached for at least 20 food pellets each day throughout thetesting period, with the exception of designated rest days. Oncethe rats were consistently reaching for food and achieving dailyscores of at least 50% (10 of 20 pellets), 12 of the 20 rats received6-OHDA lesions ipsilateral to their preferred paw. The followingtesting and training procedures were then given to eight 6-OHDArats and eight control rats:
Single-pellet reaching. The rats were tested each day for 21 d (days 1-21; 20 pellets per day) on the single-pellet reachtask. The performance of the rats was video-recorded before surgery,periodically throughout testing, and on day 21. Each rat was alsotested in the cylinder test on days 7, 14, and21.
Tray reaching. The rats were placed in the food-tray apparatus each day for 14 d (days 22-36; 30 min/d). On day 36, reachperformance was video-recorded, and performance was evaluatedfrom the videorecord.
Single-pellet test. On day 37, the rats were returned to the single-pellet testing apparatus and underwent a 20 pellet reachingtest that was video-recorded. The rats were also tested in thecylinder test on day37.
Single-pellet retest. On days 38-43, the rats remained in their home cage and received no testing. On day 44, the rats werereturned to the single-pellet testing apparatus and underwenta 20 pellet reaching test that was video-recorded.
Rotation tests. At the completion of the behavioral testing, the rats received a rotational test after the administrationofapomorphine.
Single-pellet training control group. Four 6-OHDA rats comprised a supplementary group that received all of the training describedabove, except that they continued to receive single-pellet training/testingin the period during which the other rats were reaching in thetray task. After day 36, their treatment was the same as thatgiven to the rats that received the tray-taskexperience.

  Results

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ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

Histology

TH immunostaining indicated that the nigrostriatal 6-OHDA injections reduced the number of dopaminergic cells in the substantianigra and the terminals and fibers in the caudate putamen. Figure2 illustrates a section through the mesencephalon of a lesionanimal with representative lesion extent. The lesion resultedin an almost complete unilateral loss of nigrostriatal neuronsand the loss of TH-positive fibers throughout the substantia nigrapars compacta. In most rats, cells in the lateral portions ofthe ventral tegmental area were also absent. A cell-count analysisrevealed a significant reduction of TH-positive cells in the lesionmesencephalon in all areas compared with the intact hemisphere(p < 0.001). Figure 2 also illustrates a section through the forebrainshowing a marked reduction of TH fiber stain in the caudate putamenof the lesion versus the intact hemisphere.

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Figure 2. Coronal photomicrographs of the striatum (top) and substantia nigra (bottom) on the side of 6-OHDA depletion (A, B) and on the nonlesion side (C) as revealed by TH immunohistochemistry. Note the loss of TH staining in the caudate putamen and in the substantia nigra.

Apomorphine-induced rotation

After apomorphine injections, the rats with 6-OHDA lesions displayed an asymmetry in rotation, turning predominantly in thedirection contralateral to the lesion. ANOVA indicated a significantgroup effect (F_(1,14) = 10.5; p < 0.001), with the lesion apomorphinegroup displaying pronounced rotation and the control group displayingfew rotations. The groups also differed in the direction of rotation(F_(1,14) = 22.1; p < 0.001), with the 6-OHDA group rotating predominantlycontralateral to the lesion (>6 rotations per minute), indicatingan extensive DA depletion (Marshall and Ungerstedt, 1977; Heftiet al., 1980).

Cylinder test

Figure 3 illustrates the rat's percentage of limb preference for the ipsilateral paw in the cylinder test on days 7, 14, 21,and 35 (the test given after 14 d of training in the food-traytask) after lesion. A repeated-measures ANOVA gave a significantgroup difference (F_(1,14) = 33; p < 0.0.001). The performanceof the rats was similar across test days (F_(3,42) = 1.6; p > 0.5),and the groups remained different across test days (F_(3,42) =2.3; p > 0.05).

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Figure 3. Relative percentage of paw preference of the ipsilateral paw at different time points in the cylinder test in rats with 6-OHDA lesion relative to control rats. Note that the 6-OHDA-treated rats display a significant preference in the use of the paw ipsilateral to the lesion (good paw). *p < 0.5. The dotted line equals chance.

Single-pellet skilled reaching

Figure 4 indicates performance on the skilled-reaching tests for total-reach success scores (Fig. 4, top) and single-reachsuccess scores (Fig. 4, bottom). ANOVAs gave similar results onboth measures; the two groups were significantly different (F_(1,14)> 11; p < 0.001). The effect of test days (F_(5,60) = 2.7; p <0.01)was significant, as was the group-by-test-day interaction (F_(5,60)= 3.1; p < 0.001). Follow-up tests (Newman-Keuls; p <0.05) indicatedthat the performance of the lesion group was inferior to thatof the control group on all of the postoperative test days. Nevertheless,after 2 weeks of training in the tray-reaching task, the lesiongroup showed a significant improvement in performance on the single-pellettask on tests given both immediately after the tray-reach trainingand on a test given 1 week after the tray-reach training (p <0.5).

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Figure 4. Reaching success (number of pellets obtained out of 20; mean ± SE) by control rats and rats with 6-OHDA lesion in the single-pellet task before and after training on the tray task (after rehabilitation; vertical dotted line). Top, Total success equals the number of pellets obtained of the 20. Bottom, Number of pellets obtained of the 20 on the first reach attempt. Note that the 6-OHDA group is impaired on both measures and displays significant improvement after the tray-reach (rehabilitation) experience.

Tray-task skilled reaching

The rats were allowed to reach for food in the tray task for 30 min each day for 14 d. On day 15, their performance was filmedand evaluated for 5 min of reaching. Rats in both groups usedonly the paw used in the single-pellet task, which, in the caseof the 6-OHDA group, was the paw ipsilateral to the lesion. Overall,there were no differences in the number of reaches made by thetwo groups [t_(1,14) = 0.1; p > 0.05; control, 124.3 ± 20.8; 6-OHDA,124.13 ± 19.9 (mean ± SE)]. There were also no differences inreaching success percentage (t_(1,14) = 0.2; p > 0.05; control,62.8 ± 13.2; 6-OHDA, 61.9 ± 28.7).

Qualitative evaluation of single reach movement

At least five reaches from each rat were scored for tests given on days 21, 37, and 44 after surgery. Analysis of the rats'movement scores indicated that the lesion group had significantlyhigher scores on all of the tests than did the control group (F_(1,14)= 14.9; p < 0.001), but there was also a significant group-by-movementcomponent interaction (F_(1,126) = 4.2; p < 0.05). Follow-up analysesindicated that 2 of the 10 movement components were impaired inthe lesion group (Supination II and Release). As is illustratedin Figure 5, comparisons of the rats' scores on Supination IIand Release on day 21 versus day 36 indicated that the 6-OHDAgroup displayed significant improvement. Figure 6 illustratesthe reaching movements made by a rat before surgery, after the6-OHDA lesion, and after rehabilitation training on the tray-reachingtask. Before surgery, the rat grasps the food, supinates the pawto withdraw the food through the slot (Supination I), supinatesthe paw further to place the food in its mouth (Supination II),and releases the food (Release). After the 6-OHDA lesion, therat successfully grasps the food, displays a partial SupinationI to withdraw the food through the slot, but fails to displaySupination II to bring the food to the mouth. Rather, the pawadducts so that the rat's mouth comes in contact with the dorsalsurface of the wrist/paw. Eventually the paw contacts the tableand the food is released onto the floor of the test apparatus.After tray training, the rat displays a complete Supination Iand Supination II and releases the food into the mouth.

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Figure 5. Scores for supination and food release (mean ± SE) in control rats and in rats with 6-OHDA lesion before and after tray-reach training (rehabilitation). Note that performance after tray reach is significantly (**p < 0.01) improved compared with performance before rehabilitation.

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Figure 6. Illustration of supination and release by a rat before 6-OHDA lesion (Control), after the lesion (Lesion), and after training on the tray task (Rehab). Note that after the lesion, a failure to supinate the paw results in adduction of the paw, with the mouth contacting the outer surface of the wrist/paw. The paw eventually contacts the floor, and the food pellet is dropped. After rehabilitation, the rat is able to supinate the paw and eat the food while remaining in a sitting posture but uses a slight compensatory head tilt to retrieve the food pellet.

Although the rats appeared to have recovered the ability to make the Supination II movement, we were concerned that the movementmay not have been independent, but rather assisted with the badpaw. Therefore, the tapes were carefully examined to determinewhether Supination II was performed independently or was assisted.This analysis indicated that Supination II was completed beforethe contralateral paw was brought toward the mouth. In addition,all of the rats displayed reaches in which the contralateral pawwas not used at all to assist eating. Thus, Supination II didappear to have recovered as an independent movement. When therats were allowed a 7 d no-reach period after the day 36 test,a retest on day 42 indicated that the rats were still able tosupinate and bring the paw to the mouthsuccessfully.

Although tray-reach training appeared to serve as rehabilitative experience for all of the rats, a careful observation ofthe rats' movements indicated that a subtle deficit persisted.The 6-OHDA rats, although still able to bring the food to theirmouths, tilted their heads slightly to the ipsilateral side, withtheir snouts directed slightly medially to assist in taking thefood from the paw. This subtle difference suggested that therewas a residual deficit in supinating the paw despite the rehabilitationexperience.

Posture

The rat's posture was scored on days 21 and 36. There was a significant group difference (F_(1,12) = 5.6; p < 0.01) but nogroup-by-day interaction. The control rats typically supportedtheir weight during a reach on the forepaw contralateral to thereaching paw and on the ipsilateral hindpaw. During limb withdrawaland eating, the weight was supported relatively symmetricallyon both hindpaws. Weight support by the 6-OHDA group was moreobviously shifted to the ipsilateral hindpaw both during limbtransport to the food and during limb withdrawal andeating.

Single-pellet-training control group

Because the improvement in performance produced by reaching in the tray task was unexpected, an additional group of DA-depletedrats received training only on the single-pellet task. All ofthe rats received daily training for 5 d each week for 45 d. Theirperformance did not improve over this period of training, andtheir success scores were 6.2 ± 2 on day 22 and 5.4 ± 3 on day43, a difference that was not significant. Thus, these rats showedno improvement as a function of training on the single-pellettask. Inspection of the video records of the rats' performanceindicated that across all testing they displayed the same impairmentin supination displayed by the previously tested DA-depleted group,except that they did not show improvements as did the previousgroup in response to their additional experience on the single-pellettask.

  Discussion

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

The objective of the present experiment was to determine why rats display a skilled-reaching impairment on the side of thebody ipsilateral to the DA depletion. A quantitative evaluationof skilled reaching for single food pellets confirmed that theDA-depleted rats displayed reduced success in retrieving foodpellets with the paw ipsilateral to the lesion. A qualitativeanalysis indicated that the deficit was attributable to a failureto supinate the paw and to release the food to the mouth. Afterrehabilitative training in a simpler reaching task, the rats displayedsubstantial improvement on the single-pellet task, and the impairmentin supination was significantly reduced. The results clarify thenature of the unilateral skilled-reaching impairment and alsodemonstrate that rehabilitative procedures can lessen theimpairment.

A number of studies have reported that unilateral DA-depleted rats display impairment in skilled reaching not only with thepaw contralateral to the lesion but also with the paw ipsilateralto the lesion. On the expectation that deficits should be displayedonly on the contralateral side of the body, Montoya et al. (1990)have suggested that the ipsilateral impairment may be secondaryto "a nonspecific postural deviation rather than a specific impairmentin skilled motor use of the ipsilateral limb." Similarly, Miklyaevaet al. (1994) ascribe the ipsilateral impairment to compensatorypostural adjustments for postural abnormalities in which the DA-depletedrats relied excessively on the ipsilateral hindlimb for supportand movement. In neither study was a specific examination undertakenof the way that the ipsilateral limb isused.

We confirm that unilateral DA-depleted rats have an impairment in their success in retrieving food pellets using the ipsilaterallimb on a demanding criterion, in which a success was countedonly if the food was retrieved on a single reach, and a less demandingcriterion, in which all successes were counted. A video analysisof the reaching movements indicated that the rats displayed animpairment in supinating the paw to bring food to the mouth. Ratherthan supinating, the paw was adducted across the snout so thatthe mouth contacted the upper surface of the wrist/paw. Food waslost because the paw was eventually placed on the floor of thecage. Thus, the impairment appeared to be referable to the proximalmusculature of the body that might assist in supinating and holdingthe limb in a midline position to present food to themouth.

The finding that unilateral DA depletion in the rat produces an ipsilateral impairment is consistent with findings in humanParkinson patients. Patients with unilateral posteroventral medialpallidotomy display improvements in ipsilateral bradykinesia andfinger tapping (Lozano and Lang, 1995; Lang et al., 1997). Inaddition, patients receiving unilateral deep-brain stimulationexperience improvement in the ipsilateral symptoms of tremor andrigidity (Kumar et al., 1999; Merello et al., 1999; Obwegeseret al., 2001). The neural pathways mediating either deficits orimprovements are not known in the rat or inhumans.

There are a number of potential explanations of the ipsilateral impairment. First, ~5-10% of DA fibers are crossed (for review,see Fallon and Loughlin, 1995; Heimer et al., 1995), so damageto this crossed projection may be related to the impairment inthe ipsilateral paw. Second, rats with unilateral amino acid neurotoxiclesions of the caudate putamen display an ipsilateral reachingimpairment (Montoya et al., 1990; Jeyasingham et al., 2001), whichcould be taken as evidence that it is the uncrossed DA projectionsto the striatum that may be related to the ipsilateral reachingdeficit. Third, DA depletion may indirectly impair some of theuncrossed projections of the extrapyramidal system to the spinalcord, or crossed projections within basal ganglia circuitry (Parentand Hazrati, 1995). Fourth, the deficit may be related to musculoskeletalasymmetry, such as scoliosis, which reportedly follows unilateralDA depletions (Herrera-Marschitz et al., 1990). With respect tothis point, however, it is noteworthy that the limb impairmentis manifested immediately after the lesion, before scoliosis mightbe expected to be severe. In addition, the brief period of rehabilitationthat the rats received in the tray task would have been unlikelyto have remediated scoliosis. Fifth, the DA-depleted rats obviouslydisplayed postural abnormalities in relying excessively on theipsilateral hind limb for support, which may have contributedto the limb impairment. However, rehabilitation ameliorated theimpairment in limb use but not in postural support, which weakensthis possibility. In addition, after unilateral pyramidal tractlesions at the medullary pyramids, postural changes similar tothose observed after DA depletions occur, but the animals do notdisplay an ipsilateral deficit in skilled reaching (Whishaw andMetz, 2002).

Because previous studies have shown that there is improved performance with training on the simpler tray task (Whishaw etal., 1986), the rats in the present study were trained on thetray task for 2 weeks. At the end of this training, the controland DA-depleted groups performed equally well. Surprisingly, whenreturned to the single-pellet task, the rats with 6-OHDA lesiondisplayed significant improvement in success. The rats also displayedsignificant improvement in supinating the limb and in releasingthe food to the mouth. Thus, training on the simpler task provideda rehabilitative experience. The rats retained the benefits conferredby the rehabilitative experience over a number of tests givenover a couple of weeks. Other rats tested during the same periodin only the single-pellet task displayed norecovery.

The deficit in supination was not completely ameliorated, however. A careful inspection of the movements of the rats afterrehabilitation indicated that they were sometimes clumsy and thatthey also had slight impairment in supination. They compensatedfor the impairment by turning the head toward the paw to retrievethe foodpellet.

The tray-reaching task may be rehabilitative in that a tray full of food provides easier access to the food. The grids comprisingthe floor of the cage may also assist postural support by providingthe animals with purchase for their hind feet. The task may alsobe ameliorative by being negatively reinforcing, in that releasingthe food results in its loss through the floor of the cage (inthe single-pellet task, the food can be retrieved once released).We were concerned that rehabilitation may simply have been attributableto a compensatory process on the good side of the body, such asusing the bad paw to assist the good paw. Although the DA-depletedrats did use the bad paw to assist in holding retrieved food,an inspection of the videotapes indicated that rats successfullysupinated the paw before the bad paw was recruited. The preciseway in which the task is rehabilitative can be examined in futurework. Nevertheless, the finding that rehabilitation can amelioratea DA-related impairment opens the possibility that other impairmentsmay also be lessened through similar rehabilitativetraining.

Previous work has suggested that restraint of the good limb, forcing use of the limb contralateral to the lesion, can lessenDA-related impairments, possibly by reducing the lesion size (Tillersonet al., 2001). It is unlikely that the therapeutic effects ofthe rehabilitative experience given here are produced in the sameway. First, the rats were given a test of limb asymmetry in whichcontacts by the forepaws with the walls of a cylinder were measured(Tillerson et al., 2001), and on this test, the asymmetry wassimilar both before and after rehabilitative training. Becausethis test provides a measure of lesion size, the result suggeststhat lesion size was not affected by the testing/training procedures.In addition, the apomorphine test of rotation given at the endof the training/testing procedures and the histological proceduressuggested that the DA depletions were relativelycomplete.

In conclusion, there is growing realization that the impairments produced by DA depletion are complex and vary in their sensitivityto therapy (Metz et al., 2001). Some deficits (e.g., bradykinesia)can be improved by therapies such as brain grafts and L-3,4-dihydroxyphenylalanine(Schallert et al., 1979; Olsson, 1995), whereas other behaviors(e.g., skilled reaching with the contralateral paw) seem moreresistant to therapy (Dunnett et al., 1987; Olsson, 1995; Metzet al., 2001; but see Nikkhah et al., 1993; Glavan et al., 2001).Not only do the results of the present study suggest that unilateralDA depletion does affect some movements ipsilateral to the sideof DA depletion, but the results also suggest that rehabilitativetraining can ameliorate this DA-related impairment. This findingis novel and important and adds to previous reports that ipsilateralbut not contralateral skilled-reaching impairments are improvedby grafts of embryonic DA tissue (Montoya et al., 1990) and subthalamicnucleus lesions (Henderson et al., 1999). At present, there issome doubt concerning the efficacy of physiotherapy in human patientswith Parkinson's disease (Dean et al., 2001; de Goede et al.,2001), but the finding here that a specific treatment can havea specific beneficial effect could be considered in the designof future programs for humanphysiotherapy.

  FOOTNOTES

Received Oct. 28, 2002; revised Oct. 28, 2002; accepted Oct. 31, 2002.

This study was supported by the Canadian Institute for Health Research. We thank Bogdan Gorny and Paul A. Whishaw for assistancewith the videoproduction.

Correspondence should be addressed to Dr. Ian Q. Whishaw, Canadian Centre for Behavioural Neuroscience, University of Lethbridge,4401 University Drive, Lethbridge, Alberta, Canada, T1K 3M4. E-mail:whishaw{at}uleth.ca.

  References

TOP
ABSTRACT
Introduction
Materials and Methods
Results
Discussion
REFERENCES

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