Priorities in Parkinson's disease research.

The loss of dopaminergic neurons in the substantia nigra pars compacta leads to the characteristic motor symptoms of Parkinson's disease: bradykinesia, rigidity and resting tremors. Although these symptoms can be improved using currently available dopamine replacement strategies, there is still a need to improve current strategies of treating these symptoms, together with a need to alleviate non-motor symptoms of the disease. Moreover, treatments that provide neuroprotection and/or disease-modifying effects remain an urgent unmet clinical need. This Review describes the most promising biological targets and therapeutic agents that are currently being assessed to address these treatment goals. Progress will rely on understanding genetic mutations or susceptibility factors that lead to Parkinson's disease, better translation between preclinical animal models and clinical research, and improving the design of future clinical trials.

Hypothalamic involvement in Huntington's disease: an in vivo PET study.

Recent studies have shown alterations in metabolism, sleep and circadian rhythms as well as in several neuropeptides derived from the hypothalamic-pituitary axis in Huntington's disease patients; however, the pathology underlying these abnormalities is not known. Our aim was to assess in vivo D(2) receptor's loss/dysfunction and increases in microglial activation in the hypothalamus of symptomatic Huntington's disease patients and premanifest Huntington's disease gene carriers using PET with (11)C-raclopride (RAC), a specific D(2) receptor ligand and (11)C-(R)-PK11195 (PK), a marker of microglial activation. We have studied 9 symptomatic Huntington's disease patients (age = 46.8 +/- 4.7 years; mean +/- SD) and 10 premanifest Huntington's disease gene carriers (age = 41.9 +/- 8.2 years; mean +/- SD). RAC and PK findings for these subjects were compared with those of a group of normal controls (RAC, n = 9; PK, n = 10). In the symptomatic Huntington's disease group, we found a significant decrease (P = 0.0012) in mean hypothalamic RAC binding potential (BP) and a significant increase in mean hypothalamic PK BP (P = 0.0008). Similarly, a significant decrease (P = 0.0143) in mean hypothalamic RAC BP and a significant increase in mean hypothalamic PK BP (P = 0.0057) were observed in the premanifest Huntington's disease group. Hypothalamic RAC and PK BP values correlated with each other in combined Huntington's disease groups (r = -0.6180, P = 0.0048) but not with striatal RAC and PK BP values. Our data demonstrate, for the first time, significant D(2) receptor loss and microglia activation in the hypothalamus of Huntington's disease. These pathological changes occur very early in the course of the disease and may partly explain the development of commonly reported symptoms in Huntington's disease including progressive weight loss, alterations in sexual behaviour and disturbances in the wake-sleep cycle.

Evidence of dopamine dysfunction in the hypothalamus of patients with Parkinson's disease: an in vivo 11C-raclopride PET study.

A mild to moderate reduction in dopamine, noradrenaline and serotonin levels alongside a progressive loss of hypocretin cells and melanin hormone concentrating cells has been reported in the hypothalamus of PD at postmortem. Hypothalamic uptake of (18)F-dopa PET, an in vivo marker of dysfunction of monoaminergic neurons, is also significantly reduced in these patients. These data indicate a general impairment of hypothalamic function in PD. Dopamine receptors play an important role in the regulation of hypothalamic pathways. To date, possible changes in hypothalamic D(2) receptor availability have not been investigated in PD. The objective in this study was to assess dopamine D(2) receptor availability in hypothalamus of patients with idiopathic Parkinson's disease (PD) using positron emission tomography (PET) with (11)C-raclopride (RAC). We evaluated D(2) binding in RAC PET images of 14 PD patients using both region of interest (ROI) analysis and a voxel based approach. ROIs for the hypothalamus were traced on the subject's MRI co-registered to the PET image. (11)C-raclopride binding potentials (BP) for hypothalamus were obtained by applying ROIs onto parametric images. Findings were compared with those of 9 normal controls. We found a significant reduction in the mean hypothalamic RAC BP of the PD patients compared with the normal controls (0.2714+/-0.06 vs. 0.3861+/-0.04; mean+/-SD; p=0.0005). ROI results were confirmed with statistical parametric mapping (SPM). Individual hypothalamic BP values of PD patients did not correlate with age, disease duration, disease severity and levodopa equivalent dose. It remains to be ascertained whether the reductions in hypothalamic D(2) receptor availability seen in PD are disease related, the results of chronic exposure to levodopa or both. Our results provide further evidence of dopaminergic dysfunction in the hypothalamus in PD, and this may contribute to the development of sleep, endocrine and autonomic disorders.

Increased dopamine tone during meditation-induced change of consciousness.

This is the first in vivo demonstration of an association between endogenous neurotransmitter release and conscious experience. Using 11C-raclopride PET we demonstrated increased endogenous dopamine release in the ventral striatum during Yoga Nidra meditation. Yoga Nidra is characterized by a depressed level of desire for action, associated with decreased blood flow in prefrontal, cerebellar and subcortical regions, structures thought to be organized in open loops subserving executive control. In the striatum, dopamine modulates excitatory glutamatergic synapses of the projections from the frontal cortex to striatal neurons, which in turn project back to the frontal cortex via the pallidum and ventral thalamus. The present study was designed to investigate whether endogenous dopamine release increases during loss of executive control in meditation. Participants underwent two 11C-raclopride PET scans: one while attending to speech with eyes closed, and one during active meditation. The tracer competes with endogenous dopamine for access to dopamine D2 receptors predominantly found in the basal ganglia. During meditation, 11C-raclopride binding in ventral striatum decreased by 7.9%. This corresponds to a 65% increase in endogenous dopamine release. The reduced raclopride binding correlated significantly with a concomitant increase in EEG theta activity, a characteristic feature of meditation. All participants reported a decreased desire for action during meditation, along with heightened sensory imagery. The level of gratification and the depth of relaxation did not differ between the attention and meditation conditions. Here we show increased striatal dopamine release during meditation associated with the experience of reduced readiness for action. It is suggested that being in the conscious state of meditation causes a suppression of cortico-striatal glutamatergic transmission. To our knowledge this is the first time in vivo evidence has been provided for regulation of conscious states at a synaptic level.