The activity profile of pramipexole at various sites has been characterized as follows: While pramipexole is used clinically (see below), its D3-preferring receptor binding profile has made it a popular tool compound for preclinical research. For example, pramipexole has been used (in combination with D2- and or D3-preferring antagonists) to discover the role of D3 receptor function in rodent models and tasks for neuropsychiatric disorders. Of note, it appears that pramipexole, in addition to having effects on dopamine D3 receptors, may also affect mitochondrial function via a mechanism that remains less understood. A pharmacological approach to separate dopaminergic from non-dopaminergic (e.g. mitochondrial) effects of pramipexole has been to study the effects of the
R-
stereoisomer of pramipexole (which has much lower affinity to the dopamine receptors when compared to the
S-isomer) side by side with the effects of the
S-isomer. This property can be characterised using
dopaminergic activity equivalent (a relative measure comparing doses of different doses of stereoisomers in mg). Parkinson's disease is a
neurodegenerative disease affecting the
substantia nigra, a component of the
basal ganglia. The substantia nigra has a high quantity of
dopaminergic neurons, which are
nerve cells that
release the
neurotransmitter known as
dopamine. When dopamine is released, it may activate
dopamine receptors in the
striatum, which is another component of the basal ganglia. When neurons of the substantia nigra deteriorate in Parkinson's disease, the striatum no longer properly receives dopamine signals. As a result, the basal ganglia can no longer regulate body movement effectively and motor function becomes impaired. By acting as an agonist for the D2, D3, and D4 dopamine receptors, pramipexole may directly stimulate the underfunctioning dopamine receptors in the
striatum, thereby restoring the dopamine signals needed for proper functioning of the basal ganglia. Pramipexole can increase
growth hormone indirectly through its inhibition of
somatostatin. Pramipexole has also been shown to be protective against dopaminergic-related
methamphetamine neurotoxicity. Immediate-release pramipexole displays a Tmax of approximately 2 hours and 3 hours if taken with a high-fat meal. Extended-release pramipexole displays a Tmax of ~6 hours and ~8 hours if taken with food. The AUC of pramipexole remains unaltered regardless of food presence. Steady-state is achieved within 3 days and 5 days for the IR and ER formulations, respectively. Pramipexole is eliminated via the renal organic cation transporter as an unchanged drug showing no signs of any metabolism. Pramipexole has been shown to inhibit CYP2D6 with a Ki of 30μM which is significantly higher than the maximum approved dosage of 4.5mg/day thus any enzyme-mediated drug interactions are not clinically relevant. It comes in strengths of 0.125mg, 0.25mg, 0.5mg, 1mg, and 1.5mg instant release; the extended-release comes in 0.375mg, 0.75mg, 1.5mg, 2.25mg, 3mg, 3.75mg, and 4.5mg. The instant release is meant to be dosed three times daily for Parkinson's and once two hours before bedtime for restless leg syndrome. The extended-release is not approved for restless leg syndrome. It is not metabolized, with >90% of the dose excreted unchanged via
SCL22A2/OCT2. Therefore, inhibitors of the renal organic cation transporter system (e.g.,
cimetidine ) will increase the
area under the curve\infty by 50% and increase the
t1/2 by 40%. ==Chemistry==