Putamen is an important component in the neurobiology of neurodegenerative diseases. This page provides detailed information about its structure, function, and role in disease processes.
The putamen is the largest nucleus of the [basal ganglia[/brain-regions/basal-ganglia and forms the lateral component of the dorsal [striatum[/brain-regions/striatum, together with the [caudate nucleus[/cell-types/caudate-nucleus. Separated from the
caudate by the internal capsule (except at their anterior connection in the fundus striati) and bounded laterally by the external capsule and claustrum, the putamen serves as the
primary input station for motor and sensorimotor information entering the basal ganglia circuit. It receives somatotopically organized projections from the primary [motor cortex[/brain-regions/motor-cortex,
premotor [cortex[/brain-regions/cortex, supplementary motor area, and somatosensory [cortex[/brain-regions/cortex, as well as dense dopaminergic innervation from the [substantia
nigra[/cell-types/substantia-nigra pars compacta (SNpc).[1]
The putamen is of central importance in the pathophysiology of [Parkinson's disease[/diseases/parkinsons, where it is the earliest and most severely affected striatal structure due to preferential
loss of dopaminergic projections from the ventrolateral tier of the SNpc. Posterior dorsal putamen shows the greatest [dopamine[/entities/dopamine depletion (up to 80% at symptom onset), making it
the critical site of the motor circuit dysfunction that produces bradykinesia, rigidity, and tremor.[2] The putamen is also heavily affected in [Huntington's disease[/mechanisms/huntington-pathway, [multiple system atrophy[/diseases/msa,
and other [basal ganglia[/brain-regions/basal-ganglia disorders.
¶ Location and Boundaries
The putamen occupies a lens-shaped (lenticular) position deep within the cerebral hemisphere:
- Medial boundary: External medullary lamina of the [globus pallidus[/brain-regions/globus-pallidus, with which the putamen forms the lenticular (lentiform) nucleus
- Lateral boundary: External capsule, [claustrum[/cell-types/claustrum, and extreme capsule
- Superior boundary: White matter of the corona radiata
- Inferior boundary: Anterior commissure, [nucleus accumbens[/cell-types/nucleus-accumbens (ventral [striatum)
- Anterior: Connected to the [caudate nucleus[/cell-types/caudate-nucleus head via cell bridges traversing the anterior limb of the internal capsule
- Posterior: Narrows and is bordered by the posterior limb of the internal capsule
The putamen measures approximately 5 cm in length along its anterior–posterior axis in the adult human brain and has a volume of roughly 4–6
cm³ per hemisphere, as measured by high-resolution structural MRI.[3]
Like the [caudate nucleus[/cell-types/caudate-nucleus, the putamen is composed predominantly of:
- [Medium spiny neurons[/cell-types/medium-spiny-neurons (MSNs): ~95% of all putaminal [neurons[/entities/neurons. D1-expressing MSNs project directly to the globus pallidus internus (GPi)/substantia nigra pars reticulata (SNr) via the direct pathway (facilitating movement), while D2-expressing MSNs project to the globus pallidus externus (GPe) via the indirect pathway (inhibiting movement). The balance between these pathways is fundamentally disrupted in [Parkinson's disease[/diseases/parkinsons due to [dopamine[/entities/dopamine depletion
- Cholinergic interneurons: Large aspiny [neurons[/entities/neurons (~1–2%) that release [acetylcholine[/entities/acetylcholine and modulate MSN excitability. These tonically active [neurons[/entities/neurons (TANs) pause their firing during reward-related and salient stimuli, contributing to reinforcement learning signals. They are relatively spared in early neurodegeneration
- GABAergic interneurons: [Parvalbumin-positive[/cell-types/pv-interneurons fast-spiking interneurons, [somatostatin-positive[/cell-types/sst-interneurons interneurons, and calretinin-positive interneurons that shape the temporal precision of MSN output
The putamen, like the rest of the [striatum[/brain-regions/striatum, is organized into two biochemically and functionally distinct compartments:
- Striosomes (also called patches): Account for ~15% of striatal volume. Enriched in μ-opioid receptors, substance P, dopamine D1 receptors, and calretinin. Striosomes receive input primarily from limbic cortical areas ([orbitofrontal cortex], [insular cortex[/brain-regions/insular-cortex, [amygdala) and project to dopaminergic [neurons[/entities/neurons in the SNpc, forming a feedback loop that regulates [dopamine[/entities/dopamine release.[4]
- Matrix: The larger compartment (~85% of striatal volume). Enriched in calbindin, somatostatin, dopamine D2 receptors, and cholinergic markers. The matrix receives input from sensorimotor and associative cortices and projects to the GPi/GPe and SNr, forming the output channels of the classical basal ganglia motor circuit.
In MPTP-treated primate models of [Parkinson's disease[/diseases/parkinsons, dopaminergic markers are more severely depleted in the matrix compartment of the posterior putamen, with relative
preservation of striosomal dopamine, suggesting compartment-specific vulnerability that may contribute to the preferential motor deficits
seen in PD.[5] In depression, recent
research has shown putaminal volume reductions accompanied by a shift from matrix-like to striosome-like structural connectivity
patterns.[6]
The putamen maintains a precise somatotopic organization that reflects its cortical inputs:
- Dorsal posterior putamen: Leg/trunk representation; receives input from supplementary motor area
- Dorsal middle putamen: Arm/hand representation; receives input from primary motor and premotor [cortex[/brain-regions/cortex
- Ventral putamen: Face/orofacial representation
- Anterior putamen: Associative/cognitive territory; receives input from prefrontal areas
This somatotopy is preserved in the output pathways through the [globus pallidus[/brain-regions/globus-pallidus and [thalamus[/brain-regions/thalamus, and is clinically relevant: the characteristic arm-dominant symptoms of early PD reflect the preferential dopamine depletion in the dorsal middle putamen.
The putamen receives its blood supply primarily from the lateral lenticulostriate arteries, branches of the middle cerebral artery (MCA). These end-arteries are particularly vulnerable to hypertensive damage, making the putamen the most common site of hypertensive intracerebral hemorrhage (accounting for ~35% of all spontaneous ICH). Lacunar infarcts from small vessel disease are also common in this region, contributing to vascular cognitive impairment and [vascular parkinsonism].
The putamen is the primary striatal structure involved in motor function. It processes motor commands through two parallel circuits:
- Direct pathway (D1-MSN → GPi/SNr → thalamus → cortex): Facilitates desired movements by disinhibiting thalamo-cortical projections
- Indirect pathway (D2-MSN → GPe → STN → GPi/SNr → thalamus → cortex): Suppresses unwanted movements by increasing inhibition of thalamo-cortical projections
[dopamine[/entities/dopamine from the [substantia nigra[/brain-regions/substantia-nigra differentially modulates these pathways: it excites D1-MSNs (facilitating movement) and inhibits
D2-MSNs (reducing movement suppression). The net effect of dopamine is to promote voluntary movement. Loss of putaminal dopamine in
[Parkinson's disease[/diseases/parkinsons leads to under-activation of the direct pathway and over-activation of the indirect pathway, producing the
characteristic motor poverty (bradykinesia) and rigidity.[7]
A third circuit, the hyperdirect pathway ([cortex[/brain-regions/cortex → subthalamic nucleus → GPi), bypasses the putamen entirely and provides rapid suppression of competing motor programs, important for action cancellation and impulse control.
The putamen is essential for stimulus-response learning (habit formation). While the [caudate nucleus[/cell-types/caudate-nucleus mediates goal-directed, flexible
behavior, the putamen stores well-learned motor programs that are executed automatically. This caudate-to-putamen shift during skill
acquisition represents a transition from deliberate to automatic motor control.[8]
A 2024 study demonstrated that motor learning is directly modulated by dopamine availability in the sensorimotor putamen: individuals with
higher baseline putaminal dopamine capacity showed faster and more complete transitions from effortful to automatic motor execution.[9] This finding has implications for
understanding why PD patients struggle to acquire and automate new motor skills.
In [Parkinson's disease[/diseases/parkinsons, disruption of putaminal circuits forces patients to rely on frontal lobe-mediated conscious motor control, explaining why dual-tasking is particularly difficult and why well-learned motor sequences (e.g., walking, handwriting) deteriorate.
¶ Reward Processing and Reinforcement Learning
Although the ventral [striatum[/brain-regions/striatum ([nucleus accumbens) is most commonly associated with reward, the dorsal putamen plays a distinct role in action-reward contingency learning.
Putaminal activity correlates with stimulus-action-dependent reward prediction — the learned association between specific motor actions and their outcomes — while the [caudate
nucleus[/cell-types/caudate-nucleus tracks reward prediction errors (the discrepancy between expected and received reward).[10] This division underlies the
putamen's
role in habit formation: as behaviors become habitual, reward processing shifts from caudate to putamen circuits.
The putamen integrates sensory feedback with motor commands to fine-tune movement execution. It receives proprioceptive, tactile, and visual information from somatosensory and [parietal cortex], which it combines with motor plans from frontal [cortex[/brain-regions/cortex to enable smooth, coordinated movement.
- Volumetric MRI: Putamen volume decreases with normal aging (~0.5% per year after age 60), but accelerated atrophy is observed in neurodegenerative conditions. In PD, putaminal atrophy correlates with motor severity and may serve as a progression biomarker. In [Huntington's disease[/mechanisms/huntington-pathway, putaminal atrophy is detectable up to 3 years before clinical onset.[11]
- Quantitative MRI: Multiparametric quantitative MRI (T1, T2*, proton density, and magnetization transfer) reveals putaminal microstructural changes in PD, including increased iron content and altered tissue composition, even in early-stage disease. These microstructural gradients along the anterior–posterior axis of the putamen correspond to the known dopaminergic denervation pattern.[12]
- Diffusion MRI: Diffusion tensor imaging shows changes in putaminal free water content in PD, reflecting neuronal loss and gliosis.
- DAT-SPECT: Dopamine transporter single-photon emission computed tomography (DaTscan) reveals reduced putaminal uptake as the most sensitive clinical imaging marker for PD diagnosis. The characteristic pattern is asymmetric reduction in posterior putaminal tracer binding, contralateral to the more affected side. DAT binding in the posterior putamen correlates with striatal dopamine levels and motor symptom severity.
- [18F]-DOPA PET: Fluorodopa PET quantifies presynaptic dopaminergic function and shows posterior putaminal reductions paralleling DAT-SPECT findings.
- fMRI: Resting-state functional connectivity between the putamen and supplementary motor area (SMA) is enhanced in PD, interpreted as a compensatory mechanism to maintain motor function despite dopamine depletion.[13] Task-based fMRI shows reduced putaminal activation during motor sequence execution in PD, normalizing after [levodopa[/treatments/levodopa administration.
Graph theory analysis of resting-state fMRI has identified the putamen as one of the brain regions most affected by normal aging, showing
altered functional connectivity patterns with cortical motor and prefrontal areas. These changes may underlie age-related declines in motor
performance, processing speed, and habit learning capacity.[14]
The putamen is the epicenter of dopaminergic denervation in [Parkinson's disease[/diseases/parkinsons and the primary driver of motor symptoms:
- Gradient of depletion: Post-mortem studies show that putaminal dopamine is depleted by 70–80% by the time motor symptoms emerge, following a posterior-to-anterior and dorsal-to-ventral gradient within the putamen. The posterior dorsal putamen (motor territory) is most affected; anterior ventral putamen (cognitive/limbic territory) is relatively spared early on. This gradient is more severe than in the [caudate nucleus[/cell-types/caudate-nucleus, where depletion reaches only ~40% at symptom onset.[2][15]
- Matrix-preferential degeneration: Within the striosome-matrix compartments, dopaminergic terminals in the matrix are more severely depleted than those in striosomes, particularly in the posterior putamen. This has implications for understanding why motor symptoms predominate over emotional/motivational symptoms in early PD.[5]
- DAT imaging: DAT-SPECT and [18F]-DOPA PET reveal reduced putaminal uptake as the most sensitive imaging marker for PD diagnosis, typically showing asymmetric loss contralateral to the clinically more affected side
- Compensatory mechanisms: The remaining dopaminergic terminals in the putamen upregulate dopamine synthesis and release (increased dopamine turnover), contributing to the long presymptomatic phase. As these compensatory mechanisms fail, motor symptoms emerge
- Therapeutic target: The putamen is the primary target for [levodopa[/treatments/levodopa therapy. Exogenous [dopamine[/entities/dopamine restores putaminal dopaminergic tone, rebalancing direct/indirect pathway activity. [COMT inhibitors[/treatments/comt-inhibitors, [MAO-B inhibitors[/treatments/mao-b-inhibitors, and [dopamine agonists[/treatments/dopamine-agonists all aim to enhance putaminal dopamine signaling. [Gene therapy[/treatments/gene-therapy approaches delivering aromatic L-amino acid decarboxylase (AADC) directly to the putamen via stereotactic injection are in clinical trials, with promising Phase II results showing sustained improvement in [18F]-DOPA uptake and motor scores
In [Huntington's disease[/mechanisms/huntington-pathway, the putamen undergoes severe neurodegeneration alongside the [caudate nucleus[/cell-types/caudate-nucleus:
- [Medium spiny neurons[/cell-types/medium-spiny-neurons of the indirect pathway (D2-expressing, enkephalin-positive) are lost first, contributing to early hyperkinetic chorea (loss of movement suppression)
- Later, direct pathway MSNs (D1-expressing, substance P-positive) are also lost, leading to the rigid-akinetic phenotype of advanced HD
- Putamen atrophy becomes significant approximately 3 years before estimated disease onset, later than [caudate nucleus[/cell-types/caudate-nucleus atrophy, but putaminal atrophy rate accelerates as onset approaches[11]
- The mutant [huntingtin protein[/proteins/htt-protein (mHTT) forms intranuclear inclusions preferentially in MSNs, with striosome MSNs appearing to be more vulnerable than matrix MSNs in early disease stages
In [MSA[/diseases/msa-P (parkinsonian subtype), the putamen is severely affected by [alpha-synuclein[/proteins/alpha-synuclein glial cytoplasmic inclusions (GCIs) in
[oligodendrocytes[/entities/oligodendrocytes, leading to putaminal degeneration and atrophy. MRI shows the characteristic "putaminal rim sign" — a hyperintense
rim on T2-weighted imaging representing gliosis at the putaminal border — and putaminal atrophy, which can help distinguish MSA-P from PD.
Longitudinal multi-center studies report annual putaminal atrophy rates of 4.2–8.2% in MSA, significantly exceeding rates in PD and healthy
controls.[16]
In [Progressive Supranuclear Palsy (PSP)[/diseases/progressive-supranuclear-palsy, the putamen shows tau[/astrocytes] and neurofibrillary [tangles](/astrocytes] and neurofibrillary tangles) along with midbrain atrophy. Putaminal involvement contributes to axial rigidity and levodopa-unresponsive parkinsonism that characterize PSP.
[Corticobasal Degeneration (CBD)[/diseases/corticobasal-degeneration features asymmetric putaminal atrophy contralateral to the affected limbs. [Tau[/entities/tau-protein-positive astrocytic plaques and ballooned [neurons[/entities/neurons are found in the putamen, contributing to the distinctive asymmetric akinetic-rigid syndrome with cortical features (apraxia, alien limb).
- [Vascular Dementia[/diseases/vascular-dementia: Lacunar infarcts in the putamen cause contralateral hemiparesis and may contribute to vascular parkinsonism. The putamen is the most common site of hypertensive basal ganglia hemorrhage
- [Wilson's Disease[/diseases/wilson-disease: Copper deposition in the putamen causes the characteristic "face of the giant panda" sign on MRI and contributes to dystonia and parkinsonism
- [NBIA[/diseases/nbia: Iron accumulation in the putamen and [globus pallidus[/brain-regions/globus-pallidus causes the "eye of the tiger" sign in pantothenate kinase-associated neurodegeneration (PKAN)
- [Chronic traumatic encephalopathy (CTE)[/diseases/cte: Repetitive head trauma can lead to tau] pathology in the putamen, contributing to motor and behavioral symptoms
While the subthalamic nucleus (STN) and GPi are the standard targets for [deep brain stimulation[/treatments/deep-brain-stimulation in PD,
the putamen is indirectly modulated by DBS. STN-DBS normalizes the pathologically increased activity of the indirect pathway, effectively
restoring putaminal output balance. Neuroimaging studies show that effective DBS modulates functional connectivity involving the putamen,
[precuneus], and orbitofrontal [cortex[/brain-regions/cortex.[17]
Direct infusion of viral vectors (AAV2-AADC, AAV2-GDNF) into the putamen via stereotactic neurosurgery represents a promising approach for PD. By delivering dopamine-synthesizing enzymes or [neurotrophic factors[/mechanisms/neurotrophic-factors directly to the denervated putamen, these therapies aim to restore local dopaminergic function. Phase I/II trials of AAV2-AADC delivered to the putamen have shown sustained improvement in motor symptoms and increased [18F]-DOPA uptake at the injection sites.
Virtually all dopaminergic therapies for PD exert their primary therapeutic effect by modulating putaminal dopamine signaling:
- [Levodopa[/treatments/levodopa: Converted to dopamine by remaining putaminal terminals and non-dopaminergic cells
- [Dopamine agonists[/treatments/dopamine-agonists: Directly stimulate D1/D2 receptors on putaminal MSNs
- [MAO-B inhibitors[/treatments/mao-b-inhibitors: Reduce dopamine breakdown within the putaminal synaptic cleft
- [COMT inhibitors[/treatments/comt-inhibitors: Prolong levodopa availability for conversion to dopamine in the putamen
This section links to atlas resources relevant to this brain region.
The study of Putamen has evolved significantly over the past decades. Research in this area has revealed important insights into the underlying mechanisms of neurodegeneration and continues to drive therapeutic development.
Historical context and key discoveries in this field have shaped our current understanding and will continue to guide future research directions.
- [Alexander GE, DeLong MR, Strick PL. Parallel organization of functionally segregated circuits linking basal ganglia and cortex. Annu Rev Neurosci. 1986;9:357-381. DOI
- [Kish SJ, Shannak K, Hornykiewicz O. Uneven pattern of dopamine loss in the striatum of patients with idiopathic Parkinson's Disease. N Engl J Med. 1988;318(14):876-880. DOI
- [Raz N, Rodrigue KM, Kennedy KM, et al. Differential aging of the human striatum: longitudinal evidence. AJNR Am J Neuroradiol. 2003;24(9):1849-1856. PubMed))
- [Crittenden JR, Graybiel AM. Basal ganglia disorders associated with imbalances in the striatal striosome and matrix compartments. Front Neuroanat. 2011;5:59. DOI
- [Iravani MM, Syed E, Jackson MJ, et al. Differential vulnerability of primate caudate-putamen and striosome-matrix dopamine systems to the neurotoxic effects of MPTP. Proc Natl Acad Sci. 1992;89(2):743-747. PubMed))
- [Baumgartner C, et al. Depression-associated reductions in putaminal volume are accompanied by a shift from matrix-like to striosome-like structural connectivity. Front Psychiatry. 2025;16:1647240. DOI
- [DeLong MR. Primate models of movement disorders of basal ganglia origin. Trends Neurosci. 1990;13(7):281-285. DOI
- [Lehéricy S, Benali H, Van de Moortele PF, et al. Distinct basal ganglia territories are engaged in early and advanced motor sequence learning. Proc Natl Acad Sci. 2005;102(35):12566-12571. DOI
- [Johansson V, et al. Motor learning is modulated by dopamine availability in the sensorimotor putamen. Brain Commun. 2024;6(6):fcae409. DOI
- [Haruno M, Kawato M. Different neural correlates of reward expectation and reward expectation error in the putamen and caudate nucleus during stimulus-action-reward association learning. J Neurophysiol. 2006;95(2):948-959. DOI
- [Aylward EH, Nopoulos PC, Ross CA, et al. Longitudinal change in regional brain volumes in prodromal Huntington's Disease. J Neurol Neurosurg Psychiatry. 2011;82(4):405-410. DOI
- [Piaggio N, et al. Multiparametric quantitative MRI uncovers putamen microstructural changes in Parkinson's Disease. npj Parkinsons Dis. 2025;11:20. DOI
- [Wu T, Wang L, Hallett M, et al. Enhanced functional connectivity between putamen and supplementary motor area in Parkinson's Disease patients. PLoS One. 2013;8(3):e59717. DOI
- [Ghanbari M, et al. Age-related changes in human brain functional connectivity using graph theory and machine learning techniques in resting-state fMRI data. GeroScience. 2024;46:5473-5499. DOI
- [Hornykiewicz O. Dopaminergic deficiency is more pronounced in putamen than in nucleus caudatus in Parkinson's Disease. Mol Chem Neuropathol. 1998;34(2-3]:101-111. DOI
- [Jellinger KA. The role of neuro-imaging in Multiple System Atrophy. J Neural Transm. 2025. DOI
- [Herrington TM, Cheng JJ, Eskandar EN. Mechanisms of deep brain stimulation. J Neurophysiol. 2016;115(1):19-38. DOI