Anatomic Organization of the Basilar Pontine Projections from Prefrontal Cortices in Rhesus Monkey

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Volume 17, Number 1, Issue of January 1, 1997 pp. 438-458
Copyright ©1997 Society for Neuroscience

Anatomic Organization of the Basilar Pontine Projections from Prefrontal Cortices in Rhesus Monkey

Jeremy D. Schmahmann¹ and Deepak N. Pandya²
¹ Department of Neurology, Massachusetts General Hospital and Harvard Medical School, Boston, Massachusetts 02114, and ² Harvard Neurological Unit, Beth Israel Hospital, Boston, Massachusetts 02114, and Department of Anatomy and Neurobiology, Boston University School of Medicine, Boston, Massachusetts 02114

ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

In our ongoing attempt to determine the anatomic substrates that could support a cerebellar contribution to cognitive processing,we investigated the prefrontal cortical projections to the basilarpons. A detailed understanding of these pathways is needed, becausethe prefrontal cortex is critical for a number of complex cognitiveoperations, and the corticopontine projection is the obligatoryfirst step in the corticopontocerebellar circuit. Prefrontopontineconnections were studied using the autoradiographic techniquein rhesus monkey. The pontine projections were most prominentand occupied the greatest rostrocaudal extent of the pons whenderived from the dorsolateral prefrontal convexity, includingareas 8Ad, 9/46d, and 10. Lesser pontine projections were observedfrom the medial prefrontal convexity and area 45B in the inferiorlimb of the arcuate sulcus. In contrast, ventral prefrontal andorbitofrontal cortices did not demonstrate pontine projections.The prefrontopontine terminations were located preferentiallyin the paramedian nucleus and in the medial parts of the peripeduncularnucleus, but each cortical area appeared to have a unique complementof pontine nuclei with which it is connected. The existence ofthese corticopontine pathways from prefrontal areas concernedwith multiple domains of higher-order processing is consistentwith the hypothesis that the cerebellum is an essential node inthe distributed corticosubcortical neural circuits subservingcognitive operations.
Key words: frontal lobe; pons; cerebellum; connections; anatomy; behavior; cognition

INTRODUCTION

The corticopontine projection is the obligatory first step in the feedforward limb of the cerebrocerebellar circuit. Severalinvestigators have described pontine projections from cerebralassociation areas (Nyby and Jansen, 1951; Brodal, 1978; Wiesendangeret al., 1979; Glickstein et al., 1985; May and Andersen, 1986;Fries, 1990). Our recent investigations have revealed that thereare projections to the pons from unimodal as well as multimodalassociation areas in the posterior parietal, superior temporal,and occipitotemporal cortices as well as from the parahippocampalgyrus (Schmahmann and Pandya, 1989, 1991, 1993). Vilensky andVan Hoesen (1981) have demonstrated pontine connections from thelimbic system arising in the cingulate gyrus.

Recent functional neuroimaging data in human subjects (Petersen et al., 1989; Dolan et al., 1992; Ryding et al., 1993; Jenkinset al., 1994; Kim et al., 1994; Parsons et al., 1995) and clinicalevidence derived from patients with cerebellar lesions (Baumanand Kemper, 1994; Silveri et al., 1994; Sherman and Schmahmann,1995) have provided supportive evidence for earlier physiological(Reis et al., 1973; Cooper et al., 1974) and behavioral investigations(Berman et al., 1978), suggesting a role for the cerebellum incognitive operations and affective processes (Dow and Moruzzi,1958; Dow, 1974; Snider and Maiti, 1976; Heath, 1977; Watson,1978; Schmahmann, 1991, 1996). Cerebellar patients have difficultieswith executive function (Grafman et al., 1992) and verbal fluency(Fiez et al., 1992), problems generally seen in the setting offrontal lobe dysfunction (Fuster, 1980). This has been interpretedas representing a disruption of cerebellar modulation of functionssubserved by the frontal lobe. Implicit in this hypothesis isthat the cerebellum is part of a distributed neural system (Mesulam,1981; Goldman-Rakic, 1988; Posner et al., 1988) that incorporatesthe higher-order areas including the prefrontal cortices (Leineret al., 1986, 1993; Schmahmann and Pandya, 1987, 1989, 1991, 1993;Botez et al., 1989; Schmahmann, 1991, 1996; Grafman et al., 1992;Ito, 1993; Middleton and Strick, 1994).

There is evidence from earlier indirect observations (Kievit and Kuypers, 1977; Sasaki et al., 1979; Stanton, 1980) and frommore recent direct transsynaptic experiments (Middleton and Strick,1994) that the cerebellar dentate nucleus has a feedback projectionto the prefrontal cortex (PFC). There is a paucity, however, ofanatomic evidence demonstrating a feedforward contribution tothe cerebellum from prefrontal cortices concerned with complexcognitive operations. There is a substantial body of literaturethat has evolved since the last century that deals with the frontopontineprojection in the nonhuman primate. The principal findings ofthese earlier investigations are summarized in Table 1. For themost part, however, this work has not focused on the PFC specificallyand, consequently, a number of essential details are still unavailable.

Table 1. Summary of previous principal findings

Our interest in the pontine projections from the PFC is part of a larger investigation of the input to the feedforward limbof the cerebrocerebellar system from nonmotor cerebral regionsconcerned with higher-order behavior. Using the same techniquesand methodology as in our previous investigations, we conducteda systematic study in the rhesus monkey of the prefrontopontinepathways. We sought to determine the precise origins of the pontineprojections within the PFC, as well as the detailed pattern ofterminations within the nuclei of the basilar pons. The PFC issegregated into functionally distinct regions that are matchedby a connectional heterogeneity, such that each of the prefrontalsubdivisions has a different set of connections with corticalas well as subcortical structures (Pandya and Yeterian, 1991).We wished to determine whether the differential organization ofthe prefrontopontine projection reflects this cortical anatomicand functional heterogeneity. Preliminary results of these investigationshave been presented elsewhere, but the precise arrangement withinthe basilar pons of the prefrontopontine terminations have notbeen previously published. The pons is the intermediate step inthe feedforward limb of the cerebrocerebellar circuit and, therefore,this detailed topographic map is essential for determining theanatomic relationship between nonmotor areas of the cerebral hemispheresand the cerebellum. Furthermore, we were interested in establishinghow the projections from the prefrontal association cortices differfrom those derived from the posteriorly situated association areas.Therefore, in the present report, we have investigated the corticopontineprojections from functionally and architectonically distinct prefrontalareas using the anterograde tracer technique.

Preliminary results of our investigations have been presented previously. (Schmahmann and Pandya, 1995).

MATERIALS AND METHODS
In 18 adult rhesus monkeys, the prefrontopontine projections were studied using radiolabeled anterograde tracers. Two closelyadjacent injections of 0.5 µl of tritiated leucine and proline(volume range, 0.4-1.2 µl, specific activity range, 40-80 µCu,aqueous solution) were made in each case. Animals were anesthetizedwith ketamine hydrochloride (10 mg/kg) and sodium pentobarbital(30 mg/kg), and the cerebral cortex was exposed by craniotomyand reflection of the dura. Regions of the PFC defined previouslyby cytoarchitectonic criteria (Petrides and Pandya, 1994) (Fig.1D) were identified by inspection of the sulcal pattern, and injectionswere made under direct visual guidance with a 1 µl Hamilton syringeand a microdrive attachment. Cortical injections were made ata depth of 2 mm, and sulcal injections were made at a depth of4-6 mm. After a survival period of 7 d, the animals were killedunder deep Nembutal anesthesia by transcardial perfusion of saline.The animals were then perfused with 10% formalin and the brainsremoved. The brainstem was separated from the cerebral hemispheresrostral to the level of the inferior colliculus at 90° to thelong axis of the pons. The brainstem and cerebellum were embeddedin paraffin and cut in transverse section at a thickness of 10µm and mounted on glass slides. The slides were immersed in KodakNTB-2 nuclear track emulsion, exposed for 4-6 months, developedin Kodak D-19, fixed in Kodak Rapid-Fix, then counterstained withthionin, and coverslipped (Cowan et al., 1972). Transverse sectionsthrough the rostrocaudal extent of the pons were drawn with theaid of a magnifier, the distribution of terminal label studiedwith dark-field microscopy, and axon termination fields were plottedon these drawings using a side-arm viewer. Nine levels of thepons at approximately equal intervals were selected in each caseto depict the findings. These levels, I to IX from rostral tocaudal pons, and the cytoarchitectonic characteristics and boundariesof the pontine nuclei correspond to those described by Nyby andJansen (1951) and Schmahmann and Pandya (1989, 1991) (Fig. 2).The nomenclature used for describing the location of the PFC injectionsites in this study follows the architectonic parcellation ofPetrides and Pandya (1994) (Fig. 1D). Many of the cases used inthis study have been analyzed in other investigations of corticaland subcortical projections of the prefrontal region (Barbas andPandya, 1989; Yeterian and Pandya, 1991).
Fig. 1. Diagrams of the cerebral hemispheres of rhesus monkey illustrating the architectonic areas of the prefrontal cortices accordingto the designations of Brodmann (1909) (A), Walker (1940) (B),von Bonin and Bailey (1947) (C), and Petrides and Pandya (1994)(D). This figure illustrates the extent of the PFC, and the earliernomenclature is presented to assist in the interpretation of theresults of the studies that are cited in Table 1.
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Fig. 2. Diagram showing the subdivisions of the pontine nuclei in the transverse plane (perpendicular to the long axis of the pons)according to Nyby and Jansen (1951), with modifications accordingto our observations (Schmahmann and Pandya, 1989, 1991). I-IXrepresent the rostrocaudal levels at equal intervals through thepons.
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RESULTS

Injections that resulted in pontine terminations
Medial prefrontal cases The isotope injections in cases 1 and 2 (Figs. 3C,D, 4) were placed in the medial PFC and involved area 32. The resultinglabel was present in the rostral third of the ipsilateral ponsand was distributed primarily in the medial portion of the peduncularand peripeduncular nuclei and in the paramedian nucleus.
Fig. 3. Light-field photographs of coronal sections through isotope injections in three representative cases (left), and dark-fieldphotomicrographs of the resulting anterogradely transported terminallabel in the nuclei of the ipsilateral basis pontis (right). A,Area 10 injection in case 5, with terminal label seen in B inlevel III of the pons in the paramedian (PM) and peripeduncular(P) nuclei. C, Isotope injection in case 2 in area 9 at the medialconvexity, with terminal label seen in D in level II of the ponsin the median (M) and paramedian nuclei. E, Injection site incase 9, in area 9/46d, with terminal label in level II of thepons (F) in the paramedian nucleus. Injection sites (A, C, E):scale bar (shown in E), 20 mm; pontine terminations (B, D, F):scale bar (shown in F), 2 mm.
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Fig. 4. Diagram illustrating the medial surface of the cerebral hemisphere of case 1, in which the isotope injection (shown in black)was placed in the medial PFC and involved area 32. The resultingfibers (small black dots) were present in the rostral third ofthe ipsilateral pons. The terminal label (large black dots) wasdistributed primarily in the medial portion of the peduncularand peripeduncular nuclei and in the paramedian nucleus. Abbreviationsfor cerebral hemispheres (Figs. 4, 5, 6, 7, 8, 9, 10, 11, 12, 13,14, 15, 16, 17): AS, arcuate sulcus; CING S, cingulate sulcus; CC,corpus callosum; CF, calcarine fissure; CS, central sulcus; IOS,inferior occipital sulcus; IPS, intraparietal sulcus; LF, lateral(Sylvian) fissure; LS, lunate sulcus; Orb S, orbital sulcus; OTS,occipitotemporal sulcus; POMS, parieto-occipital medial sulcus;PS, principalis sulcus; Rh F, rhinal fissure; STS, superior temporalsulcus. Abbreviations for brainstem sections (Figs. 4, 5, 6, 7,8, 9, 10, 11, 12, 13, 14, 15, 16, 17): Br Conj, brachium conjunctivum;D, dorsal pontine nucleus; DL, dorsolateral pontine nucleus; DM,dorsomedial pontine nucleus; EDL, extreme dorsolateral pontinenucleus; IPN, interpeduncular nucleus; L, lateral pontine nucleus;M, median pontine nucleus; ML, medial lemniscus; NRTP, nucleusreticularis tegmenti pontis; P, peduncular nucleus (peripeduncularvs intrapeduncular not differentiated in the diagrams); PM, paramedianpontine nucleus; R, nucleus reticularis tegmenti pontis; RN, rednucleus; SN, substantia nigra; V, ventral pontine nucleus.
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In case 3, the injection was placed above the cingulate sulcus in the rostral part of the superior frontal gyrus and involvedthe rostral and medial part of area 9 (Fig. 5). The terminal labelwas distributed in the rostral two-thirds of the ipsilateral pons.This was the only case in the series in which label was observedin the median nucleus. Additionally, grains were detected in theparamedian nucleus, as well as in the nucleus reticularis tegmentipontis (NRTP). The contralateral NRTP also had a small projectionlocated between pontine levels IV and V.
Fig. 5. Diagram illustrating the medial surface of the cerebral hemisphere of case 3, in which the isotope was placed above the cingulatesulcus in the rostral part of the superior frontal gyrus and involvedthe rostral and medial part of area 9. Terminal label was distributedin the rostral two-thirds of the ipsilateral pons and was presentin the median nucleus, the paramedian and dorsomedial nuclei,and the NRTP. The contralateral NRTP also had a small projectionin between pontine levels IV and V.
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In case 4, the injection was placed in the medial surface of the hemisphere above the cingulate sulcus at a level correspondingto the rostral tip of the corpus callosum and involved area 8B(Fig. 6). Terminations were noted in the rostral half of the ipsilateralpons in the paramedian nucleus, the medial part of the peripeduncularnucleus, and the NRTP.
Fig. 6. Diagram illustrating the medial surface of the cerebral hemisphere of case 4, in which isotope was injected in the medialsurface of the hemisphere above the cingulate sulcus at a levelcorresponding to the rostral tip of the corpus callosum and involvedarea 8B. The terminal label was distributed in the rostral halfof the ipsilateral pons and in the paramedian nucleus, the medialpart of the peripeduncular nucleus, and the NRTP.
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In case 5, the injection was placed in the rostral part of the PFC and involved the medial and dorsal sectors of area 10 (Figs.3A,B, 7). The terminal label in this case was observed throughoutthe rostro-caudal extent of the ipsilateral pons and involvedthe paramedian, peripeduncular, and dorsomedial nuclei and theNRTP. Caudally, some label was also noted in the ventral and lateralpontine nuclei as well.
Fig. 7. Diagram illustrating the medial and lateral surfaces of the cerebral hemisphere of case 5, in which the isotope was placedin the rostral part of the PFC and involved the medial and dorsalsectors of area 10. Terminal label was observed in levels I-IXof the ipsilateral pons and involved the paramedian, peripeduncular,and dorsomedial nuclei and the NRTP. A small amount of label wasnoted in the ventral and lateral nuclei at caudal levels of thepons.
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Dorsolateral prefrontal cases
The injection in cases 6 (Fig. 8) and 7 (data not shown) were placed in the PFC above the midportion of the principal sulcusand involved lateral area 9. The resulting label was essentiallyidentical in both cases and was noted throughout the rostrocaudalextent of the ipsilateral pons occupying a thin dorsal-ventrallamella adjacent to the midline. The lamella spanned the paramediannucleus and the medial part of the peripeduncular nucleus, aswell as the dorsomedial and ventral nuclei and the NRTP.
Fig. 8. Diagram illustrating the lateral surface of the cerebral hemisphere of case 6, in which the isotope was injected into thePFC above the midportion of the principal sulcus and involvedlateral area 9. The resulting label throughout the rostrocaudalextent of the ipsilateral pons occupied a thin dorsal-ventrallamella adjacent to the midline, spanning the paramedian nucleusand the medial part of the peripeduncular nucleus as well as thedorsomedial and ventral nuclei and the NRTP.
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In case 8, the injection was placed in the rostral part of the dorsolateral PFC and included the rostral part of area 9 anddorsal area 10 (Fig. 9). Label was restricted to the rostral halfof the ipsilateral pons and was located primarily in the paramedianand peripeduncular nuclei. Some label was also noted in the NRTP.
Fig. 9. Diagram illustrating the lateral surface of the cerebral hemisphere of case 8, in which isotope was placed in the rostralpart of the dorsolateral PFC and involved the rostral part ofarea 9 and dorsal area 10. Label was restricted to the rostralhalf of the ipsilateral pons and was located primarily in theparamedian and peripeduncular nuclei, with some grain also inthe NRTP.
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The injection in case 9 was placed in the caudal part of the upper bank of the principal sulcus and the adjacent gyral cortexand involved area 9/46d (Figs. 3E,F, 10). The label was distributedthroughout the rostrocaudal extent of the ipsilateral pons andwas observed somewhat more laterally when compared with previouscases. Label was seen predominantly in the peripeduncular, paramedian,and dorsomedial nuclei, as well as in the NRTP and the medialpart of the ventral nucleus.
Fig. 10. Diagram illustrating the lateral surface of the cerebral hemisphere of case 9, in which isotope was placed in the caudal partof the upper bank of the principal sulcus and the adjacent gyralcortex and involved area 9/46d (Fig. 9). The label was distributedthroughout the rostrocaudal extent of the ipsilateral pons andwas present in the peripeduncular, paramedian, and dorsomedialnuclei as well as in the NRTP and the medial part of the ventralnucleus.
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In case 10, the isotope injection was placed in the cortex lying in the rostral bank of the upper limb of the arcuate sulcusand adjacent gyral cortex and involved area 8Ad (Fig. 11). Theresulting label was distributed throughout the rostrocaudal extentof the ipsilateral pons. Terminations were present primarily inthe paramedian and dorsomedial nuclei and in the medial and ventralparts of the peripeduncular nucleus. Additionally, in the caudalpons, grains were noted in the ventral and lateral nuclei, andsome were also observed in the NRTP.
Fig. 11. Diagram illustrating the lateral surface of the cerebral hemisphere of case 10, in which the isotope injection was placedin the cortex lying in the rostral bank of the upper limb of thearcuate sulcus and adjacent gyral cortex and involved area 8Ad.Terminal label was present throughout the rostrocaudal extentof the ipsilateral pons, involving primarily the paramedian anddorsomedial nuclei and the medial and ventral parts of the peripeduncularnucleus. In the caudal pons, grains were noted in the ventraland lateral nuclei, with some in the NRTP.
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The injection in case 11 was placed within the caudal part of the ventral bank of the principal sulcus and the adjacent gyralcortex and involved area 9/46v (Fig. 12). Terminal label occupiedthe rostral half of the ipsilateral pons and was detected primarilyin the paramedian nucleus, with some label seen in the dorsomedialnucleus and in the medial part of the peripeduncular nucleus.
Fig. 12. Diagram illustrating the lateral surface of the cerebral hemisphere of case 11, in which isotope was injected into the caudalpart of the ventral bank of the principal sulcus and the adjacentgyral cortex, and involved area 9/46v. Terminal label was presentin the rostral half of the ipsilateral pons in the paramediannucleus, with some label in the dorsomedial nucleus and the medialpart of the peripeduncular nucleus.
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In cases 12 and 13, the isotope injections were placed in the cortex lying in the rostral bank of the lower limb of the arcuatesulcus and involved area 45B. The injection in case 12 (Fig. 13)was slightly dorsal to that in case 13 (Fig. 14). The label inboth these cases was restricted to the rostral third of the ipsilateralpons and was localized in the paramedian nucleus and in the medialand ventral parts of the peripeduncular nucleus.
Fig. 13. Diagram illustrating the lateral surface of the cerebral hemisphere of case 12, in which the isotope injection was placedin the cortex lying in the rostral bank of the lower limb of thearcuate sulcus and involved area 45B. Label was restricted tothe rostral third of the ipsilateral pons and was localized inthe paramedian nucleus and in the medial and ventral parts ofthe peripeduncular nucleus.
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Fig. 14. Diagram illustrating the lateral surface of the cerebral hemisphere of case 13, in which the injection in area 45B was slightlyventral to that in the previous case. The pattern of terminationsin this case was similar to case 12 and involved the paramediannucleus and the medial and ventral parts of the peripeduncularnucleus.
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Injections that did not result in pontine terminations
Orbitofrontal and adjacent ventral lateral prefrontal cases In the next four cases (Fig. 15), the isotope injection involved area 46 below the principal sulcus (case 14); the caudal partof the orbital cortex, area 47/12 (case 15); the midlateral portionof the orbital cortex, area 47/12 (case 16); the rostral partof the orbital cortex, area 11 (case 17); and the ventral regionof the medial PFC, area 14 (case 18). In each case, labeled fiberswere seen to leave the injection site and travel toward differentcortical destinations within the same and opposite hemispheres.Some subcortically directed fibers entered the anterior limb ofthe internal capsule and terminated in the thalamus. None of thesecases, however, demonstrated labeled fibers conforming to theexpected trajectory of the prefrontopontine fiber system (Schmahmannand Pandya, 1994), traversing the anterior limb of the internalcapsule and descending into the cerebral peduncle. None of thesecases resulted in the distribution of terminal label in the pontinenuclei.
Fig. 15. Diagrams illustrating the lateral, ventral, and medial surfaces of the cerebral hemispheres of a rhesus monkey, demonstratingthe sites of injection that did not result in the transport ofterminal label into the basilar pons. In case 14, the isotopewas placed in the rostral aspect of ventral area 46; case 15,in the caudal part of the orbital cortex in area 47/12; case 16,in the midlateral part of the orbital cortex in area 47/12; case17, in the rostral part of the orbital cortex in area 11; andcase 18, in the ventral region of the medial PFC in area 14.
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Summary of anatomic results
The results of our investigations confirm many of the earlier reports and extend these observations by defining both the originsand the differential terminations of the prefrontopontine projection.Cortical areas that contribute most heavily to the pons includearea 9/46d located above the principal sulcus, area 8Ad in thearcuate concavity, area 9 at the dorsolateral convexity, and area10 at the rostral parts of the dorsolateral and medial convexities.Area 8B and area 32 at the medial surface of the hemisphere, area9 at the medial convexity, and area 9/46v contribute a distinctbut somewhat less intense pontine projection. A minor pontineprojection also arises from area 45B in the rostral bank of theinferior limb of the arcuate sulcus. Pontine projections are notobserved after isotope injection in area 46 below the principalsulcus or the orbitofrontal cortices including areas 11, 47/12,and 14 (see Fig. 16).
Fig. 16. Diagrams and table illustrating the medial (A), lateral (B), and orbital (C) surfaces of the frontal lobe of a rhesus monkeyto show the sites of injection of the isotope-labeled amino acidtracer in 18 animals and the resulting distribution pattern ofterminations within the nuclei of the ipsilateral basilar pons.The numbers in the injection sites correspond to the individualcases. Injections that resulted in terminations in the basilarpons are shaded in black. Those that did not result in label inthe pons are unshaded. Terminations were present in differentrostro-caudal levels of the pons (I-IX), as well as in characteristicsets of pontine nuclei. The strength of projection in each pontinenucleus is graded absent ( $-$ ), mild (+), moderate (++), or strong(+++). The injections in cases 1 and 2 were placed in area 32;case 3, in area 9 medially; case 4, in area 8B medially; case5, in area 10 at both the medial and dorsolateral convexities;cases 6 and 7, in area 9 at the lateral convexity; case 8, inthe rostral part of area 9 (lateral) and dorsal area 10; case9, in area 9/46d; case 10, in area 8Ad; case 11, in area 9/46v;and cases 12 and 13, respectively, in the dorsal and ventral partsof area 45B. In case 14, the isotope was injected in area 46 belowthe principal sulcus; case 15, in area 47/12 (caudal part of theorbital cortex); case 16, in area 47/12 (midlateral portion ofthe orbital cortex); case 17, in area 11; and case 18, in area14. Cortex within the walls of the cingulate sulcus, principalsulcus, and arcuate sulcus is represented by the dotted lines.9(med), area 9 at the medial convexity; 9(lat), area 9 at thedorsolateral convexity; 46(vent), area 46 below the principalsulcus.
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The general organization of the prefrontopontine projections is in agreement with the pattern observed in previous corticopontinestudies (Levin, 1936; Sunderland, 1940; Nyby and Jansen, 1951;Brodal, 1978, 1980; Künzle, 1978; Wiesendanger et al., 1979;Glickstein et al., 1980; Hartmann-von Monakow et al., 1981; Mayand Andersen, 1986; Tusa and Ungerleider, 1988; Schmahmann andPandya, 1989, 1991, 1993). Each cortical region has terminationfields scattered through the pons in patches that may be discontinuousat a given transverse pontine level or that may form part of acurvilinear patch resembling the layer of an onion. Many of theseapparently discontinuous patches can be traced from one levelto the next. The pontine terminations were strictly ipsilateralin this study, with the exception of terminations in the mediannucleus, which borders each side of the basilar pons, and theNRTP, which has a small contralateral termination in some instances(for example, in case 3).

All areas within the PFC project to the paramedian nucleus and the adjacent medial part of the peripeduncular nucleus. Thetermination patterns vary, however, according to the exact siteof origin both with respect to the rostrocaudal extent of theprojection as well as to the distribution within a given pontinelevel. Details of these pontine terminations are presented inFigure 16. When the terminations in each case are plotted on toa standard view of the pons (Fig. 17), it is apparent that thereis little or no overlap. Whereas the same pontine nucleus mayreceive input from multiple cortical sites, the precise locationof the projections is different for each cortical injection.
Fig. 17. Composite color-coded summary diagram illustrating the distribution within the basilar pons of the rhesus monkey of projectionsderived from the prefrontal associative cortices. Injections inthe medial (A) and lateral (B) surfaces of the cerebral hemisphereare shown at top left. The plane of section through the basilarpons is at bottom left. On the right, the prefrontopontine terminationsfor each case are shown in the rostrocaudal levels of the ponsI-IX. The dashed lines in the hemisphere diagrams represent thesulcal cortices. In the pons diagrams, the dashed lines representthe pontine nuclei and the solid lines depict the traversing corticofugalfibers. It is apparent that the prefrontopontine projection ischaracterized by a complex mosaic of terminations in the nucleiof the basilar pons. Each cerebral cortical region has preferentialsites of pontine terminations. There is considerable interdigitationof the terminations from some of the different cortical sites,but almost no overlap. The pontine terminations described in thiswork were mapped manually onto a standard outline of the pons.Inherent inaccuracies in this method are readily acknowledged,largely on the basis of between-case comparison, and unavoidableinaccuracies in the attempted precise transformation of the datafrom an actual transverse section of the pons to an idealizedversion. Combined anterograde tracer experiments in the same animalwould be required to confirm these conclusions.
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Therefore, it would appear from our observations that the PFC pontine projections have certain central defining features asfollows: (1) The prefrontal projections are derived from the dorsolateral,dorsomedial, and frontopolar PFC regions, but not from the orbitofrontaland adjacent ventrolateral cortices. (2) There is a consistentprojection on the paramedian pontine nucleus and the medial partof the peripeduncular nucleus. (3) There is a variable degreeof projection on the dorsomedial, median, ventral, and lateralnuclei and the NRTP. (4) There are no prefrontal projections tothe dorsal, dorsolateral, and extreme dorsolateral pontine nuclei,and there is relative sparing of the intrapeduncular pontine nucleus.It should be noted, however, that projections to a region withinthe dorsolateral pons have been reported to arise from the frontaleye field located more caudally within the arcuate concavity (Astruc,1971; Künzle and Akert, 1977; Stanton et al., 1988; Shook etal., 1990). In our study, only the rostral, sulcal part of area8 was studied, because the pontine projections from these otherareas have already been established. (5) It appears that the prefrontopontinepathways are further refined for each architectonic area by thedifferential rostro-caudal extent of each projection and by variationsin pontine nuclear connectivity at each transverse level.

DISCUSSION
The PFC has repeatedly been shown in both humans and nonhuman primates to be an essential component of the normal integrationof higher-order behavior including attention, motivation, planning,and judgment. On the basis of behavioral studies, different functionalattributes have been ascribed to orbital, medial, periprincipalis,and periarcuate prefrontal regions. This multiplicity of functionalprocesses is matched by a connectional heterogeneity such thateach of the prefrontal subdivisions has a different set of connectionswith cortical as well as with subcortical structures (Milner,1964; Fuster, 1980; Barbas and Mesulam, 1985; Pandya and Yeterian,1991; Cavada and Goldman-Rakic, 1989; Boussaoud et al., 1991;Eblen and Graybiel, 1995). The present study demonstrates thatthis connectional heterogeneity of the PFC exists also in thecorticopontine pathway. Pontine projections are derived from thedorsolateral and medial prefrontal convexities; that is, fromareas 8Ad, 8B, 9 (lateral and medial), 10, 9/46d, 9/46v, and 32.These areas are important for the spatial attributes of memory,as well as executive functions such as initiative, planning, execution,and verification of willed actions and thoughts (Luria, 1966;Eslinger and Damasio, 1985; Goldman-Rakic and Friedman, 1991;Shallice and Burgess, 1991; Petrides, 1995). In addition, projectionsare derived from area 45B, which is thought to be homologous withthe language area of humans (Petrides and Pandya, 1994).

In contrast, there is a lack of pontine input from the ventrolateral and orbitofrontal cortices including areas 11, 47/12,14, and 9/46v. Our study did not specifically examine the pontineprojections from all subdivisions of the ventral PFC, but thisconclusion is supported further by reference to earlier findings(Nyby and Jansen, 1951; Brodal, 1978; Glickstein et al., 1985).These prefrontal regions have been shown to subserve object memoryand recognition and aspects of autonomic and emotional responseinhibition (Iversen and Mishkin, 1970; Rosvold, 1972; Bachevalierand Mishkin, 1986). This lack of pontine input from the ventrolateraland orbitofrontal cortices may at first glance be seen as problematicfor the hypothesis that the cerebellum contributes to the modulationof affect and emotional states (Snider, 1950; Heath, 1977; Bermanet al., 1978; Watson, 1978; Schmahmann, 1991, 1996). There is,however, a pontine projection from rostral cingulate area 32 asdescribed here and also reported by Vilensky and Van Hoesen (1981).In addition, pontine projections are derived from the intermediateand caudal sectors of the cingulate cortex (Vilensky and Van Hoesen,1981) and from the hypothalamus (Aas and Brodal, 1988), posteriorparahippocampal gyrus (Schmahmann and Pandya, 1993), and medialmammillary bodies (Aas and Brodal, 1988). Taken together withprevious demonstrations of connections between the cerebellumand the septal nuclei, hippocampus, and amygdala (Anand et al.,1959; Harper and Heath, 1973; Snider and Maiti, 1976), it is thereforeapparent that the pontocerebellar system indeed receives a sizableinput from limbic-related cortices.

The dichotomy in the PFC projections to the pons is reminiscent of the spatial (where) versus object (what) dichotomy (Ungerleiderand Mishkin, 1982; Desimone and Ungerleider, 1989) apparent inthe corticopontine projections from other association areas. Projectionsto pons arise from cortical areas that constitute the dorsal visualstream and that are concerned with events in the periphery ofthe visual field. This includes the dorsal prelunate, posteriorparietal, superior temporal, and posterior parahippocampal regions,which are interconnected with the dorsolateral and dorsomedialprefrontal cortices. On the other hand, cerebral areas that formpart of the ventral stream have no, or very few, pontine efferents.This includes the inferotemporal and ventral prelunate regionsthat have connections with the ventrolateral prefrontal regionand with the orbitofrontal convexity (Brodal, 1978; Wiesendangeret al., 1979; Glickstein et al., 1980, 1985; Galletti et al.,1982; May and Anderson, 1986; Tusa and Ungerleider, 1988; Schmahmannand Pandya, 1989, 1991, 1993; Fries, 1990; Pandya and Yeterian,1991). These anatomic connections of the feedforward limb of thecerebrocerebellar circuit were the basis of our earlier hypothesis(Schmahmann and Pandya, 1993) that the cerebellum is concernedwith the visual-spatial attributes of an object including itslocation and direction of motion, and it is involved in the memoryof those attributes. This hypothesis holds, conversely, that thecerebellum does not appear to participate in discriminative objectanalysis to any appreciable degree. The pattern of projectionsto the pons from the PFC are consistent with this hypothesis,although behavioral and physiological studies will be necessaryto verify these anatomically derived conclusions.

The finding that the PFC projects to the pons conforms to the general organizing principle that interconnected cortical areasshare common subcortical projections (Yeterian and Van Hoesen,1978). These prefrontal areas are interconnected with posteriorparietal, superior temporal, and parahippocampal regions (Cavadaand Goldman-Rakic, 1989; Pandya and Yeterian, 1991) that themselveshave pontine efferents (Nyby and Jansen, 1951; Brodal, 1978; Wiesendangeret al., 1979; Glickstein et al., 1985; May and Andersen, 1986;Tusa and Ungerleider, 1988; Schmahmann and Pandya, 1989, 1991,1993). The converse is also true. The absence of pontine efferentsfrom the orbitofrontal and adjacent ventrolateral cortices inthis study is harmonious with findings from other studies showingthat the orbitofrontal cortex is interconnected with the rostraltemporal cortex, the rostral lower bank of the superior temporalsulcus, and the inferior temporal gyrus (Pandya and Yeterian,1991), none of which have projections to the pons (Nyby and Jansen,1951; Brodal, 1978; Glickstein et al., 1985; Schmahmann and Pandya,1991, 1993).

The results of our investigation confirm and extend earlier reports that the paramedian and medial parts of the peripeduncularpontine nuclei seem to be the essential components in the prefrontopontineconnection. This stands in contrast to the finding that posteriorparietal, superior temporal, parahippocampal, and parastriatecortices have more laterally placed pontine projections, as shownpreviously using similar experimental methodology (Glicksteinet al., 1980; Galletti et al., 1982; May and Andersen, 1986; Schmahmannand Pandya, 1989, 1991, 1993; Fries, 1990). In addition, it appearsthat each prefrontal cortical area has a unique complement ofpontine nuclei with which it is connected. This is evident whenthe cases are compared with each other (Figs. 3, 4, 5, 6, 7, 8,9, 10, 11, 12, 13, 14, 15) and as summarized in Figures 16 and 17. Thisfinding of topographic organization within the basilar pons isreminiscent of the conclusion derived from a study of thalamicprojections to the parietal lobe; namely, that each cortical areais matched by a unique constellation of neuronal groups distributedthroughout a characteristic set of thalamic nuclei (Schmahmannand Pandya, 1990).

In summary, there are sizable and highly ordered inputs to the basilar pons from the prefrontal cortices. These afferents,which are then relayed to the cerebellum, are consistent withthe notion that the cerebellum is an integral node in the distributedcortical-subcortical neural circuitry subserving cognitive operations.It remains to be determined, however, precisely how these prefrontopontineterminations are translated into the pontocerebellar projection.The precise topographic mapping of the associative corticopontineprojections derived from the present study and from our earlierobservations facilitate such future investigations.

FOOTNOTES

Received July 12, 1996; revised Oct. 10, 1996; accepted Oct. 16, 1996.

This work was supported in part by the Veterans Administration, Edith Nourse Rogers Memorial Veterans Hospital (Bedford, MA),National Institutes of Health Grant 16841, and the Milton Fundof Harvard University. We thank Mr. Andrew Doolittle and Ms. AmyHurwitz for technical assistance, and we thank Ms. Marygrace Nealfor secretarial assistance.

Correspondence should addressed to Dr. Jeremy D. Schmahmann, Department of Neurology, Burnham 823, Massachusetts General Hospital,Fruit Street, Boston, MA 02114.

REFERENCES

Aas J-E, Brodal P (1988) Demonstration of topographically organized projections from the hypothalamus to the pontine nuclei: an experimental study in the cat. J Comp Neurol 268:313-328 . [Web of Science][Medline]
Anand BK, Malhotra CL, Singh B, Dua S (1959) Cerebellar projections to the limbic system. J Neurophysiol 22:451-458. [Free Full Text]
Astruc J (1971) Corticofugal connections of area 8 (frontal eye field) in Macaca mulatta. Brain Res 33:241-256 . [Web of Science][Medline]
Bachevalier JB, Mishkin M (1986) Visual recognition impairment follows ventromedial but not dorsolateral prefrontal lesions in monkeys. Behav Brain Res 20:249-261. [Web of Science][Medline]
Barbas H, Mesulam M-M (1985) Cortical afferent input to the principalis region of the rhesus monkey. Neuroscience 15:619-637 . [Web of Science][Medline]
Barbas H, Pandya DN (1989) Architecture and intrinsic connections of the prefrontal cortex in the rhesus monkey. J Comp Neurol 286:353-375 . [Web of Science][Medline]
Bauman ML, Kemper TL (1994) Neuroanatomic observations of the brain in autism. In: The neurobiology of autism (Bauman ML, Kemper TL, eds), pp 119-145. Baltimore: Johns Hopkins UP.
Berman AF, Berman D, Prescott JW (1978) The effect of cerebellar lesions on emotional behavior in the rhesus monkey. In: The cerebellum, epilepsy and behavior (Cooper IS, Riklan M, Snider RS, eds), pp 277-284. New York: Plenum.
Botez MI, Botez T, Elie R, Attig E (1989) Role of the cerebellum in complex human behavior. Ital J Neurol Sci 10:291-300 . [Web of Science][Medline]
Boussaoud D, Desimone R, Ungerleider LG (1991) Visual topography of area TEO in the macaque. J Comp Neurol 306:554-575 . [Web of Science][Medline]
Brodal P (1978) The corticopontine projection in the rhesus monkey. Origin and principles of organization. Brain 101:251-283 . [Free Full Text]
Brodal P (1980) The cortical projection to the nucleus reticularis tegmenti pontis in the rhesus monkey. Exp Brain Res 38:19-27 . [Web of Science][Medline]
Brodmann K (1909) In: Vergleichende Lokalisationslehre der Grosshirnrinde in inhren Prinzipien dargestellt auf Grund des Zellenbaues. Leipzig: Barth.
Cavada C, Goldman-Rakic PS (1989) Posterior parietal cortex in rhesus monkey. I. Parcellation of areas based on distinctive limbic and sensory corticocortical connections. J Comp Neurol 287:393-421 . [Web of Science][Medline]
Cooper IS, Amin L, Gilman S, Waltz JM (1974) The effect of chronic stimulation of cerebellar cortex on epilepsy in man. In: The cerebellum, epilepsy and behavior (Cooper IS, Riklan M, Snider RS, eds), pp 119-172. New York: Plenum.
Cowan WM, Gottlieb DI, Hendrickson AE, Price JL, Woolsey TA (1972) The autoradiographic demonstration of axonal connections in the central nervous system. Brain Res 37:21-51 . [Web of Science][Medline]
Desimone R, Ungerleider LG (1989) Neural mechanisms of visual processing in monkeys. In: Handbook of neuropsychology, Vol 2 (Boller F, Grafman J, eds), pp 267-299. Amsterdam: Elsevier.
Devito JL, Smith OA (1964) Subcortical projections of the prefrontal lobe of the monkey. J Comp Neurol 123:413-419.
Dolan RJ, Bench CJ, Scott RG, Friston KJ, Frackowiak RSJ (1992) Regional cerebral blood flow abnormalities in depressed patients with cognitive impairment. J Neurol Neurosurg Psychiatry 55:768-773 . [Abstract/Free Full Text]
Dow RS (1974) Some novel concepts of cerebellar physiology. Mt Sinai J Med 41:103-119 . [Medline]
Dow RS, Moruzzi G (1958) In: The physiology and pathology of the cerebellum. Minneapolis: University of Minnesota.
Eblen F, Graybiel AM (1995) Highly restricted origin of prefrontal cortical inputs to striosomes in the macaque monkey. J Neurosci 15:5999-6013 . [Abstract]
Eslinger PJ, Damasio AR (1985) Severe disturbance of higher cognition after frontal lobe ablation: patient EVR. Neurology 35:1731-1741 . [Abstract/Free Full Text]
Ferrier D, Turner WA (1898) An experimental research upon cerebrocortical afferent and efferent tracts. Proc Trans R Soc Lond [B] 62:1-3.
Fiez JA, Petersen SE, Cheney MK, Raichle ME (1992) Impaired non-motor learning and error detection associated with cerebellar damage. Brain 115:155-178 . [Abstract/Free Full Text]
Fries W (1990) Pontine projection from striate and prestriate visual cortex in the macaque monkey: an anterograde study. Vis Neurosci 4:205-216 . [Web of Science][Medline]
Fuster JM (1980) In: The prefrontal cortex: anatomy, physiology and neuropsychology of the frontal lobe. New York: Raven.
Galletti C, Maioli MG, Squatrito S, Battaglini PP (1982) Corticopontine projections from the visual area of the superior temporal sulcus in the macaque monkey. Arch Ital Biol 120:411-417 . [Web of Science][Medline]
Glickstein M, Cohen JL, Dixon B, Gibson A, Hollins M, LaBossiere E, Robinson F (1980) Corticopontine visual projections in macaque monkeys. J Comp Neurol 190:209-229 . [Web of Science][Medline]
Glickstein M, May JG, Mercier BE (1985) Corticopontine projection in the macaque: the distribution of labeled cortical cells after large injections of horseradish peroxidase in the pontine nuclei. J Comp Neurol 235:343-359 . [Web of Science][Medline]
Goldman-Rakic PS (1988) Topography of cognition: parallel distributed networks in primate association cortex. Annu Rev Neurosci 11:137-156 . [Web of Science][Medline]
Goldman-Rakic PS, Friedman HR (1991) The circuitry of working memory revealed by anatomy and metabolic imaging. In: Frontal lobe function and dysfunction (Levin HS, Eisenberg HM, Benton AL, eds), pp 72-91. New York: Oxford UP.
Grafman J, Litvan I, Massaquoi S, Stewart M, Sirigu A, Hallett M (1992) Cognitive planning deficit in patients with cerebellar atrophy. Neurology 42:1493-1496 . [Abstract/Free Full Text]
Harper JW, Heath RG (1973) Anatomic connections of the fastigial nucleus to the rostral forebrain in the cat. Exp Neurol 39:285-292 . [Web of Science][Medline]
Hartmann-von Monakow K, Akert K, Künzle H (1981) Projection of precentral, premotor and prefrontal cortex to the basilar pontine grey and to nucleus reticularis tegmenti pontis in the monkey (Macaca fascicularis). Arch Suisse Neurol Neurochir Psychiatr 129:189-208.
Heath RG (1977) Modulation of emotion with a brain pacemaker. J Nerv Ment Dis 165:300-317 . [Web of Science][Medline]
Ito M (1993) Movement and thought. Identical control mechanisms by the cerebellum. Trends Neurosci 16:448-450 . [Web of Science][Medline]
Iversen SD, Mishkin M (1970) Perseverative interference in monkeys following selective lesions of the inferior prefrontal convexity. Exp Brain Res 11:376-386 . [Web of Science][Medline]
Jenkins IH, Brooks DJ, Nixon PD, Frackowiak RSJ, Passingham RE (1994) Motor sequence learning: a study with positron emission tomography. J Neurosci 14:3775-3790 . [Abstract]
Kievit J, Kuypers HGJM (1977) Organization of the thalamocortical connections to the frontal lobe in the rhesus monkey. Exp Brain Res 29:299-322 . [Web of Science][Medline]
Kim SG, Ugurbil K, Strick PL (1994) Activation of a cerebellar output nucleus during cognitive processing. Science 265:949-951 . [Abstract/Free Full Text]
Künzle H, Akert K (1977) Efferent connections of cortical area 8 (frontal eye field) in Macaca fascicularis. A reinvestigation using the autoradiographic technique. J Comp Neurol 173:147-164 . [Web of Science][Medline]
Künzle H (1978) An autoradiographic analysis of the efferent connections from premotor and adjacent prefrontal regions (areas 6 and 9) in Macaca fascicularis. Brain Behav Evol 15:185-234 . [Web of Science][Medline]
Kuypers HGJM, Lawrence DG (1967) Cortical projections to the red nucleus and the brainstem in the rhesus monkey. Brain Res 4:151-188. [Medline]
Leichnetz GR, Astruc J (1976) The efferent projections of the medial prefrontal cortex in the squirrel monkey (Saimiri sciureus). Brain Res 109:455-472 . [Web of Science][Medline]
Leichnetz GR, Smith DJ, Spencer RF (1984) Cortical projections to the paramedian and basilar pons in the monkey. J Comp Neurol 228:388-408 . [Web of Science][Medline]
Leiner HC, Leiner AL, Dow RS (1986) Does the cerebellum contribute to mental skills? Behav Neurosci 100:443-454 . [Web of Science][Medline]
Leiner HC, Leiner AL, Dow RS (1993) Cognitive and language functions of the human cerebellum. Trends Neurosci 16:444-454 . [Web of Science][Medline]
Levin PM (1936) The efferent fibers of the frontal lobe of the monkey, Macaca mulatta. J Comp Neurol 63:369-419. [Web of Science]
Luria AR (1966) In: Higher cortical functions in man. New York: Basic Books.
May JG, Andersen RA (1986) Different patterns of corticopontine projections from separate cortical fields within the inferior parietal lobule and dorsal prelunate gyrus of the macaque. Exp Brain Res 63:265-278 . [Web of Science][Medline]
Mesulam M-M (1981) A cortical network for directed attention and unilateral neglect. Ann Neurol 10:309-325 . [Web of Science][Medline]
Mettler FA (1935) Corticofugal fiber connections of the cortex of the Macaca mulatta. The frontal region. J Comp Neurol 61:509-542. [Web of Science]
Mettler FA (1947) Extracortical connections of the primate frontal cerebral cortex. II. Corticofugal connections. J Comp Neurol 86:119-166. [Web of Science]
Middleton FA, Strick PL (1994) Anatomical evidence for cerebellar and basal ganglia involvement in higher cognitive function. Science 266:458-451 . [Abstract/Free Full Text]
Milner B (1964) Some effects of frontal lobectomy in man. In: The frontal granular cortex and behavior (Warren JM, Akert K, eds), pp 313-334. New York: McGraw Hill.
Nyby O, Jansen J (1951) An experimental investigation of the corticopontine projection in Macaca mulatta. Skrifter utgitt av det Norske Vedenskapsakademie; Mat Naturv Klasse 3:1-47.
Pandya DN, Yeterian EH (1991) Prefrontal cortex in relation to other cortical areas in rhesus monkey: architecture and connections. Prog Brain Res 85:63-94.
Parsons LM, Fox PT, Downs JH, Glass T, Hirsch TB, Martin CC, Jerabek PA, Lancaster JL (1995) Use of implicit motor imagery for visual shape discrimination as revealed by PET. Nature 375:54 . [Medline]
Petersen SE, Fox PT, Posner MI, Mintum MA, Raichle ME (1989) Positron emission tomographic studies of the processing of single words. J Cognit Neurosci 1:153-170.
Petrides M (1995) Impairments on nonspatial self-ordered and externally ordered working memory tasks after lesions of the mid-dorsal part of the lateral frontal cortex in the monkey. J Neurosci 15:359-375 . [Abstract]
Petrides M, Pandya DN (1994) Comparative architectonic analysis of the human and the macaque frontal cortex. In: Handbook of neuropyschology, Vol 9 (Boller F, Grafman J, eds), pp 17-57. Amsterdam: Elsevier.
Posner MI, Petersen SE, Fox PT, Raichle ME (1988) Localization of cognitive operations in the human brain. Science 240:1627-1631 . [Abstract/Free Full Text]
Reis DJ, Doba N, Nathan MA (1973) Predatory attack, grooming and consummatory behaviors evoked by electrical stimulation of cat cerebellar nuclei. Science 182:845-847 . [Abstract/Free Full Text]
Rosvold H E H E (1972) The frontal lobe system: cortical-subcortical interrelationships. Acta Neurobiol Exp (Warsz) 32:439-460. [Medline]
Rutishauser F (1899) Experimenteller Beitrage zur Stabkranzfaserung im Frontalhirn des Affen. Monatschrifte Psychiatr Neurol 5:161-179.
Ryding E, Decety J, Sjoholm H, Sternberg G, Ingvar D (1993) Motor imagery activates the cerebellum regionally. Cognit Brain Res 1:94-99 . [Medline]
Sasaki K, Jinnai K, Gemba H, Hashimoto S, Mizuno N (1979) Projection of the cerebellar dentate nucleus onto the frontal association cortex in monkeys. Exp Brain Res 37:193-198 . [Web of Science][Medline]
Schmahmann JD (1991) An emerging concept: the cerebellar contribution to higher function. Arch Neurol 48:1178-1187 . [Abstract/Free Full Text]
Schmahmann JD (1996) From movement to thought. Anatomic substrates of the cerebellar contribution to cognitive processing. Hum Brain Mapp, in press.
Schmahmann JD, Pandya DN (1987) Posterior parietal projections to the basis pontis in rhesus monkey: possible anatomical substrate for the cerebellar modulation of complex behavior? Neurology 37[Suppl 1]:291.
Schmahmann JD, Pandya DN (1989) Anatomical investigation of projec-tions to the basis pontis from posterior parietal association cortices in rhesus monkey. J Comp Neurol 289:53-73 . [Web of Science][Medline]
Schmahmann JD, Pandya DN (1990) Anatomical investigation of projections from thalamus to the posterior parietal association cortices in rhesus monkey. J Comp Neurol 295:299-326 . [Web of Science][Medline]
Schmahmann JD, Pandya DN (1991) Projections to the basis pontis from the superior temporal sulcus and superior temporal region in the rhesus monkey. J Comp Neurol 308:224-248 . [Web of Science][Medline]
Schmahmann JD, Pandya DN (1993) Prelunate, occipitotemporal, and parahippocampal projections to the basis pontis in rhesus monkey. J Comp Neurol 337:94-112 . [Web of Science][Medline]
Schmahmann JD, Pandya DN (1994) Trajectories of the prefrontal, pre-motor, and precentral corticopontine fiber systems in the rhesus monkey. Soc Neurosci Abstr 20:985.
Schmahmann JD, Pandya DN (1995) Prefrontal cortex projections to the basilar pons: implications for the cerebellar contribution to higher function. Neurosci Lett 199:1-4. [Web of Science][Medline]
Shallice T, Burgess P (1991) Higher-order cognitive impairments and frontal lobe lesions in man. In: Frontal lobe function and dysfunction (Levin HS, Eisenberg HM, Benton AL, eds), pp 125-138. New York: Oxford UP.
Sherman J, Schmahmann JD (1995) The spectrum of neuropsychological manifestations in patients with cerebellar pathology. Hum Brain Mapp [Suppl] 1:361.
Shook L, Schlag-Rey M, Schlag J (1990) Primate supplementary eye field. I. Comparative aspects of mesencephalic and pontine connections. J Comp Neurol 301:618-642. [Web of Science][Medline]
Silveri MC, Leggio MG, Molinari M (1994) The cerebellum contributes to linguistic production: a case of agrammatic speech following a right cerebellar lesion. Neurology 44:2047-2050 . [Abstract/Free Full Text]
Snider RS (1950) Recent contributions to the anatomy and physiology of the cerebellum. Arch Neurol Psychol 64:196-219.
Snider RS, Maiti A (1976) Cerebellar contribution to the Papez circuit. J Neurosci Res 2:133-146 . [Web of Science][Medline]
Stanton GB (1980) Topographical organization of ascending cerebellar projections from the dentate and interposed nuclei in Macaca mulatta: an anterograde degeneration study. J Comp Neurol 190:699-731 . [Web of Science][Medline]
Stanton GB, Goldberg ME, Bruce CJ (1988) Frontal eye field efferents in the macaque monkey. II. Topography of terminal fields in midbrain and pons. J Comp Neurol 271:493-506 . [Web of Science][Medline]
Sunderland S (1940) The projection of the cerebral cortex on the pons and cerebellum in the macaque monkey. J Anat 74:201-226. [Web of Science][Medline]
Tusa RJ, Ungerleider LG (1988) Fiber pathways of cortical areas mediating smooth pursuit eye movements in monkeys. Ann Neurol 23:174-183 . [Web of Science][Medline]
Ungerleider LG, Mishkin M (1982) Two cortical visual systems. In: Analysis of visual behavior (Ingle DJ, Goodale MA, Mansfield RJW, eds), pp 549-586. Cambridge, MA: MIT.
Vilensky JA, Van Hoesen GW (1981) Corticopontine projections from the cingulate cortex in the rhesus monkey. Brain Res 205:391-395 . [Web of Science][Medline]
von Bonin G, Bailey P (1947) In: The neocortex of Macaca Mulatta. Urbana, IL: University of Illinois.
Walker AE (1940) A cytoarchitectural study of the prefrontal area of the macaque monkey. J Comp Neurol 73:59-86. [Web of Science]
Watson PJ (1978) Nonmotor functions of the cerebellum. Psychol Bull 85:944-967 . [Web of Science][Medline]
Wiesendanger R, Wiesendanger M, Ruegg DG (1979) An anatomical investigation of the corticopontine projection in the primate (Macaca fascicularis and Saimiri sciureus). II. The projection from frontal and parietal association areas. Neuroscience 4:747-765 . [Web of Science][Medline]
Yeterian EH, Pandya DN (1991) Prefrontostriatal connections in relation to cortical architectonic organization in rhesus monkeys. J Comp Neurol 312:43-67 . [Web of Science][Medline]
Yeterian EH, Van Hoesen GW (1978) Cortico-striate projections in the rhesus monkey: the organization of certain cortico-caudate connections. Brain Res 139:43-63 . [Web of Science][Medline]

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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text] [PDF]

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[Abstract] [PDF]

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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text]

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[Abstract] [Full Text] [PDF]

M. Steinlin, S. Imfeld, P. Zulauf, E. Boltshauser, K.-O. Lovblad, A. R. Luthy, W. Perrig, and F. Kaufmann
Neuropsychological long-term sequelae after posterior fossa tumour resection during childhood
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[Abstract] [Full Text] [PDF]

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Am J Psychiatry, June 1, 2003; 160(6): 1110 - 1116.
[Abstract] [Full Text] [PDF]

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Anatomical correlates of dyslexia: frontal and cerebellar findings
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[Abstract] [Full Text] [PDF]

A. Bischoff-Grethe, R. B. Ivry, and S. T. Grafton
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[Abstract] [Full Text] [PDF]

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Pathological laughter and crying: A link to the cerebellum
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[Abstract] [Full Text] [PDF]

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[Abstract] [Full Text] [PDF]

D. Riva and C. Giorgi
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[Abstract] [Full Text] [PDF]

R. A. Carper and E. Courchesne
Inverse correlation between frontal lobe and cerebellum sizes in children with autism
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[Abstract] [Full Text] [PDF]

K. Burk, C. Globas, S. Bosch, S. Graber, M. Abele, A. Brice, J. Dichgans, I. Daum, and T. Klockgether
Cognitive deficits in spinocerebellar ataxia 2
Brain, April 1, 1999; 122(4): 769 - 777.
[Abstract] [Full Text] [PDF]

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Lobular Patterns of Cerebellar Activation in Verbal Working-Memory and Finger-Tapping Tasks as Revealed by Functional MRI
J. Neurosci., December 15, 1997; 17(24): 9675 - 9685.
[Abstract] [Full Text] [PDF]

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