Abstract
We propose a novel pharmacological fMRI (phMRI) method for objectively quantifying disease severity in Parkinson disease (PD). It is based on the clinical observation that the benefit from a dose of levodopa wears off more quickly as PD progresses. Biologically this has been thought to represent decreased buffering capacity for dopamine as nigrostriatal cells die. Buffering capacity has been modeled based on clinical effects, but clinical measurements are influenced by confounding factors. The new method proposes to measure the effect objectively based on the timing of the known response of several brain regions to exogenous levodopa. Such responses are robust and can be quantified using perfusion MRI. Here we present simulation studies based on published clinical dose-response data and an intravenous levodopa infusion. Standard pharmacokinetic-pharmacodynamic methods were used to model the response. Then the effect site rate constant ke was estimated from simulated response data plus Gaussian noise. Predicted time – effect curves sampled at times consistent with phMRI differ substantially based on clinical severity. Estimated ke from noisy input data was recovered with good accuracy. These simulation results support the feasibility of levodopa phMRI hysteresis mapping to measure the severity of dopamine denervation objectively and simultaneously in all brain regions with a robust imaging response to exogenous levodopa.
Highlights
IntroductionParkinson disease (PD) is characterized by progressive death of cells projecting from the substantia nigra to the striatum
The intensity and duration of the effect after injection appear to correlate with the degree of akinesia, the action of L-DOPA lasting longer the less pronounced the akinesia.—Hirschmann and Mayer [1].Parkinson disease (PD) is characterized by progressive death of cells projecting from the substantia nigra to the striatum
We show, using simulated data based on published results in human PD patients, that quantifying dopamine buffering capacity ke is likely to be feasible with existing technology
Summary
Parkinson disease (PD) is characterized by progressive death of cells projecting from the substantia nigra to the striatum. One of the most important unmet needs in PD is to find objective, quantitative in vivo biomarkers of disease severity. Biomarkers of nigrostriatal denervation are sought for several important reasons, including as surrogate markers of disease progression in treatment trials [2, 3]. Putative imaging biomarkers of disease progression include striatal. Dopamine Buffering Capacity Imaging [18F]fluorodopa PET or [123I]ioflupane SPECT. These techniques do not accurately quantify nigrostriatal cell loss [4]. Presynaptic dopaminergic imaging of the midbrain does [5]; alternative methods would be welcome
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