Amyloidopathy, Cholinopathy, Dopamine Responsiveness and Freezing of Gait in PD

Overview

Early stage Parkinson disease (PD) is characterized by a 'honeymoon' phase in terms of responsiveness of motor symptoms, including gait, to dopaminergic pharmacotherapy. Advancing PD is associated with disabling axial motor complications, such as freezing of gait (FoG), with decreased or even refractory dopamine responsiveness in over 50% of patients. The management of dopamine resistant gait problems represents the most important unmet need in PD. This study will related detailed motor testing to brain PET imaging to see if certain molecules (or lack thereof) involved with neurologic transmission in the brain are involved with FoG.

Early stage Parkinson disease (PD) is characterized by a 'honeymoon' phase in terms of responsiveness of motor symptoms, including gait, to dopaminergic pharmacotherapy. Advancing PD is associated with disabling axial motor complications, such as freezing of gait (FoG), with decreased or even refractory dopamine responsiveness in over 50% of patients. The management of dopamine resistant gait problems represents the most important unmet need in PD. At present, there is no biomarker of FoG in patients with PD as there is a lack of mechanistic understanding of dopamine nonresponsiveness of FoG. The investigators have previously identified cholinergic denervation as a prominent factor related to both falls and gait slowing in PD. The investigators recently identified that cortical -amyloid deposition not only associates with cognitive decline but also with postural instability and gait difficulties in PD. In this proposal, the investigators present preliminary data suggesting that FoG is associated with either cholinopathy, amyloidopathy or both in PD. The investigators propose to test the novel hypothesis that comorbid amyloidopathy may be a possible mechanistic factor underlying the poor response of FoG to dopaminergic therapy in advancing PD. In contrast, isolated cholinopathy would be expected to be associated with preserved dopamine responsiveness of FoG. For this purpose, the investigators propose to perform detailed motor, including FoG, testing in PD patients "on" and "off" their dopaminergic medications and relate this to dopaminergic 11C-dihydrotetrabenazine (DTBZ), vesicular acetylcholine transporter 18F-fluoroethoxybenzovesamicol (FEOBV) and -amyloid 11C-labeled Pittsburgh Compound-B (PIB) brain PET imaging in PD subjects with and without FoG. Furthermore, based on recent clinical observations that serotoninergic drugs, like the popular anti-depressant selective serotonin reuptake inhibitor (SSRI) drugs, are associated with significantly lower build- up of -amyloid plaques in the elderly population, and based on the investigators' subsequent observation of an intriguing inverse relationship between -amyloid plaque deposition and striatal serotoninergic terminal in PD, the investigators propose to perform an exploratory sub-study to test a new hypothesis that PD subjects with FoG will exhibit not only higher striatal -amyloid but also lower striatal serotoninergic innervation (as determined by 11C-DASB serotonin PET imaging) compared to PD subjects without FoG. If confirmed, positive findings in this study would allow the identification of different PD subgroups ('personalized medicine'), such as presence amyloidopathy or cholinopathy, to select patients for targeted pharmacotherapies to potentially prevent the development of FoG (anti-amyloid, such as serotoninergic drugs) or manage its clinical manifestation (cholinergic augmentation therapy) in order to preserve and maintain a good quality of life in individuals with PD.