Press release

A Risky Business: Why Do Some Parkinson’s Disease Treatments Affect Decision Making?

Pramipexole Hyperactivates the External Globus Pallidus and Impairs Decision-Making in a Mouse Model of Parkinson’s Diseasea region of the brain linked to impaired decision-making skills seen in patients receiving Parkinson’s disease treatment

Parkinson’s disease, a debilitating nervous system disorder, is treated with medications that sometimes cause impaired decision-making and poor impulse control. Now, researchers from Fujita Health University in Japan have identified a structure in the brain called the external globus pallidus which may be responsible for this side effect, paving the way for new treatments.

Parkinson’s disease (PD), also known simply as Parkinson’s, is a disorder of the nervous system that affects millions of people worldwide. The nerve cell damage associated with Parkinson’s can cause tremors, slowed movements, problems with balance, and many other symptoms which worsen gradually over time. Although there is no cure, there are medications available that can treat PD symptoms. Some of these medications, however, have previously unexplained side effects – including impaired decision-making that leads to potentially harmful behaviors such as pathological gambling, binge eating and compulsive shopping.

Now, in a study published online on 14 August 2024 in the International Journal of Molecular Sciences, researchers at Fujita Health University in Japan, led by Assistant Professor Hisayoshi Kubota from the Division of Behavioral Neuropharmacology, International Center for Brain Science (ICBS), Fujita Health University, have investigated the mechanism by which a drug called pramipexole or PPX impairs the decision-making process in mice with Parkinson’s disease. The research was co-authored by Professor Taku Nagai from the Division of Behavioral Neuropharmacology, International Center for Brain Science (ICBS), and Professor Hirohisa Watanabe from the Department of Neurology, School of Medicine, both at Fujita Health University.

To take a closer look at the findings of this study, we first need to understand how PPX works to alleviate PD symptoms. PD mainly results from a loss of nerve cells or neurons that produce a compound called dopamine. Some neurons are dependent on dopamine for their regular functioning – they have structures called ‘dopamine receptors’ which can be thought of as locks which can then be activated using dopamine as the ‘key’. Drugs like PPX can imitate the function of dopamine and bind to these receptors instead, especially in patients with PD who lack dopamine-producing neurons.

To study the effects of PPX on PD, the researchers injected the brains of mice with a toxin called 6-hydroxydopamine (or 6-OHDA). 6-OHDA damages neurons in a very similar manner to that observed in the brains of patients with PD. The mice were treated with PPX and then subjected to a touchscreen-based ‘gambling task’ to test their decision-making skills. Interestingly, these mice picked the high-risk/high-reward option much more often – they opted for a disadvantageous outcome where they received a large reward (of strawberry milkshake), which also comes with an increased risk of a large punishment by exposure to flashing lights.

But which part of the brain is responsible for this behavior? Investigating the brains of mice treated with PPX revealed that a region deep inside the brain called the external globus pallidus (GPe) was hyperactivated, or showed a much higher level of neuron activity. The researchers then chemically inhibited the neurons in the GPe, which actually reduced disadvantageous risk-taking activity in the mice. This proved that hyperactivation of the GPe was indeed responsible for poor decision-making in the mice treated with PPX.

This study has huge implications for treating patients with Parkinson’s disease. “Our findings could lead to the development of new medications or interventions that specifically target the external globus pallidus,” explains Dr. Kubota. ‘This would help to prevent or reduce decision-making impairments in Parkinson's disease patients.’

Besides helping medical professionals develop better treatments for Parkinson’s disease, these findings can also help improve awareness among affected patients, their families, as well as the general public. Dr. Kubota, explains that “Investigating how Parkinson's disease medications affect decision-making will help the public to better understand the complexity of the disease and its treatment.” He also says “This will benefit patients, their families and carers, and motivate them to consider early care and preventive strategies.”

These findings shed new light on the complex processes in the brain that aid our everyday decision-making skills, and promise to improve quality of life for patients affected by Parkinson’s disease. Maybe we can take away some important lessons from this study as well, and think twice before we indulge in poor decision-making in our daily lives!

 

Image title
: A study shows how some Parkinson’s treatments can affect decision making
Image caption: Mice with Parkinson’s Disease and treated with pramipexole show poor decision-making skills in a gambling task, as seen on the left. This is caused by increased activity in the external globus pallidus of the brain.
Image credit: Hisayoshi Kubota from Fujita Health University
License type: CC BY 4.0
Usage restrictions: Cannot be reused without prior permission

Reference

Title of original paper

Pramipexole Hyperactivates the External Globus Pallidus and Impairs Decision-Making in a Mouse Model of Parkinson’s Disease

Journal

International Journal of Molecular Sciences

DOI

10.3390/ijms25168849

About Assistant Professor Hisayoshi Kubota

Hisayoshi Kubota is an Assistant professor at the Division of Behavioral Neuropharmacology in the International Center for Brain Science (ICBS), Fujita Health University, and he is the primary author of this paper. With 20+ publications in the field, his current research interests include identifying the neural circuits involved in behavioral addictions and elucidating the pathological mechanisms of psychiatric disorders, focusing on risk genes.