Basal ganglia and cerebellar interconnectivity within the human thalamus

Basal ganglia and the cerebellum are part of a densely interconnected network. While both subcortical structures process information in basically segregated loops that primarily interact in the neocortex, direct subcortical interaction has been recently confirmed by neuroanatomical studies using vir...

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Veröffentlicht in:	Brain Structure and Function 2017-01, Vol.222 (1), p.381-392
Hauptverfasser:	Pelzer, Esther A., Melzer, Corina, Timmermann, Lars, von Cramon, D. Yves, Tittgemeyer, Marc
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Sprache:	eng
Schlagworte:	Adult Basal Ganglia - anatomy & histology Biomedical and Life Sciences Biomedicine Brain research Cell Biology Cerebellum - anatomy & histology Diffusion Magnetic Resonance Imaging Female Globus Pallidus - anatomy & histology Humans Male Neural Pathways - anatomy & histology Neurology Neurosciences NMR Nuclear magnetic resonance Original Original Article Thalamus - anatomy & histology Young Adult
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creator	Pelzer, Esther A. Melzer, Corina Timmermann, Lars von Cramon, D. Yves Tittgemeyer, Marc
description	Basal ganglia and the cerebellum are part of a densely interconnected network. While both subcortical structures process information in basically segregated loops that primarily interact in the neocortex, direct subcortical interaction has been recently confirmed by neuroanatomical studies using viral transneuronal tracers in non-human primate brains. The thalamus is thought to be the main relay station of both projection systems. Yet, our understanding of subcortical basal ganglia and cerebellar interconnectivity within the human thalamus is rather sparse, primarily due to limitation in the acquisition of in vivo tracing. Consequently, we strive to characterize projections of both systems and their potential overlap within the human thalamus by diffusion MRI and tractography. Our analysis revealed a decreasing anterior-to-posterior gradient for pallido-thalamic connections in: (1) the ventral-anterior thalamus, (2) the intralaminar nuclei, and (3) midline regions. Conversely, we found a decreasing posterior-to-anterior gradient for dentato-thalamic projections predominantly in: (1) the ventral-lateral and posterior nucleus; (2) dorsal parts of the intralaminar nuclei and the subparafascicular nucleus, and (3) the medioventral and lateral mediodorsal nucleus. A considerable overlap of connectivity pattern was apparent in intralaminar nuclei and midline regions. Notably, pallidal and cerebellar projections were both hemispherically lateralized to the left thalamus. While strikingly consistent with findings from transneuronal studies in non-human primates as well as with pre-existing anatomical studies on developmentally expressed markers or pathological human brains, our assessment provides distinctive connectional fingerprints that illustrate the anatomical substrate of integrated functional networks between basal ganglia and the cerebellum. Thereby, our findings furnish useful implications for cerebellar contributions to the clinical symptomatology of movement disorders.
doi_str_mv	10.1007/s00429-016-1223-z
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Our analysis revealed a decreasing anterior-to-posterior gradient for pallido-thalamic connections in: (1) the ventral-anterior thalamus, (2) the intralaminar nuclei, and (3) midline regions. Conversely, we found a decreasing posterior-to-anterior gradient for dentato-thalamic projections predominantly in: (1) the ventral-lateral and posterior nucleus; (2) dorsal parts of the intralaminar nuclei and the subparafascicular nucleus, and (3) the medioventral and lateral mediodorsal nucleus. A considerable overlap of connectivity pattern was apparent in intralaminar nuclei and midline regions. Notably, pallidal and cerebellar projections were both hemispherically lateralized to the left thalamus. 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While strikingly consistent with findings from transneuronal studies in non-human primates as well as with pre-existing anatomical studies on developmentally expressed markers or pathological human brains, our assessment provides distinctive connectional fingerprints that illustrate the anatomical substrate of integrated functional networks between basal ganglia and the cerebellum. 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Yves</au><au>Tittgemeyer, Marc</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Basal ganglia and cerebellar interconnectivity within the human thalamus</atitle><jtitle>Brain Structure and Function</jtitle><stitle>Brain Struct Funct</stitle><addtitle>Brain Struct Funct</addtitle><date>2017-01-01</date><risdate>2017</risdate><volume>222</volume><issue>1</issue><spage>381</spage><epage>392</epage><pages>381-392</pages><issn>1863-2653</issn><eissn>1863-2661</eissn><eissn>0340-2061</eissn><abstract>Basal ganglia and the cerebellum are part of a densely interconnected network. While both subcortical structures process information in basically segregated loops that primarily interact in the neocortex, direct subcortical interaction has been recently confirmed by neuroanatomical studies using viral transneuronal tracers in non-human primate brains. The thalamus is thought to be the main relay station of both projection systems. 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subjects	Adult Basal Ganglia - anatomy & histology Biomedical and Life Sciences Biomedicine Brain research Cell Biology Cerebellum - anatomy & histology Diffusion Magnetic Resonance Imaging Female Globus Pallidus - anatomy & histology Humans Male Neural Pathways - anatomy & histology Neurology Neurosciences NMR Nuclear magnetic resonance Original Original Article Thalamus - anatomy & histology Young Adult
title	Basal ganglia and cerebellar interconnectivity within the human thalamus
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