How dopamine modulates brain circuits of motivation in a behavioral addiction model
· Medical Xpressedited by Gaby Clark, reviewed by Andrew Zinin
Gaby Clark
Scientific Editor
Meet our editorial team
Behind our editorial process
Andrew Zinin
Lead Editor
Meet our editorial team
Behind our editorial process Editors' notes
This article has been reviewed according to Science X's editorial process and policies. Editors have highlighted the following attributes while ensuring the content's credibility:
fact-checked
peer-reviewed publication
trusted source
proofread
The GIST Add as preferred source
Researchers at Kanazawa University identified dopamine-driven neural mechanisms of motivation in a mouse model of behavioral addiction, offering insights into treatment.
Assistant Professor Naoya Nishitani and Professor Katsuyuki Kaneda of Kanazawa University have identified how dopamine-driven neural mechanisms regulate motivation in a mouse model of behavioral addiction. The findings, published in Neuropsychopharmacology, provide new insights into brain circuits underlying abnormal motivation and may inform treatments for behavioral and psychiatric disorders.
Motivation to seek rewards is a fundamental behavioral principle seen across species. However, excessive motivation toward rewards can result in addictive behaviors such as substance use disorder and pathological overeating. In recent years, behavioral addictions related to specific activities—such as internet use, gambling and video gaming—have become a growing social concern. However, because laboratory animals like rodents do not naturally engage in these behaviors, it has been challenging to develop appropriate animal models that replicate behavioral addiction, leaving the underlying neural mechanisms poorly understood.
Previous studies have demonstrated that "wheel running" is highly rewarding for rodents and shares behavioral and neural features with drug addiction models. As such, wheel running is considered a natural reward that can induce strong motivation, similar to addictive drugs.
The medial nucleus accumbens (mNAc), a central brain region involved in reward processing, receives dense dopaminergic input and plays a role in motivation toward both addictive drugs and food. Motivation is generally divided into two components: "reward seeking" and "reward consumption," each thought to be governed by distinct neural circuits. Traditional methods, however, have been inadequate for isolating these two components in the context of wheel running, and their neural bases have remained unclear.
In this study, the researchers developed a novel operant task using wheel running as a reward to investigate the neural basis of motivation for specific behaviors. In this task, mice gained access to 1 minute of wheel running by inserting their nose into a hole (nose poke). The number of nose pokes served as a measure of "reward seeking," while the duration of wheel running per minute served as an indicator of "reward consumption."
Pharmacological experiments revealed that dopaminergic neurotransmission via dopamine D1 and D2 receptors in the mNAc is essential for "reward seeking," while D1 receptors also play a role in "reward consumption."
Using fiber photometry, the researchers monitored real-time neural activity in the mNAc during task performance. In tasks requiring 10 nose pokes to earn 1 minute of wheel running, mNAc activity decreased before the first nose poke—indicating the onset of "reward seeking"—and increased after the 10th nose poke, once the reward was obtained
Fiber photometry recordings of dopamine release in the mNAc showed increases both before the first and after the 10th nose poke. These results suggest that dopamine release increases before "reward seeking" and again after the reward is acquired, while mNAc neural activity decreases during "reward seeking" and increases upon reward delivery.
Finally, using D1 or D2 receptor antagonists, the researchers examined how dopamine signaling relates to changes in neural activity. Mice treated with a D1 receptor antagonist did not exhibit the reduction in mNAc activity before the first nose poke.
Taken together, these findings suggest that increased dopamine release, followed by D1 receptor-mediated suppression of neural activity in the mNAc, plays a crucial role in driving the expression of motivated behavior toward wheel running.
This study demonstrates that wheel running in mice can serve as a model for behavioral addiction and clarifies the neural mechanisms underlying motivation for specific behaviors. Future research focusing on the mechanisms driving changes in neural activity may provide deeper insight into psychiatric disorders characterized by abnormal motivation toward natural rewards, such as major depressive disorder and behavioral addictions.
Publication details
Naoya Nishitani et al, Medial nucleus accumbens dopamine receptors modulate motivation for wheel running in male mice, Neuropsychopharmacology (2025). DOI: 10.1038/s41386-025-02136-w
Journal information: Neuropsychopharmacology
Clinical categories
PsychiatryNeurology Provided by Kanazawa University Who's behind this story?
Gaby Clark
MA in English, copy editor since 2021 with experience in higher education and health content. Dedicated to trustworthy science news. Full profile →
Andrew Zinin
Master's in physics with research experience. Long-time science news enthusiast. Plays key role in Science X's editorial success. Full profile →
Citation: How dopamine modulates brain circuits of motivation in a behavioral addiction model (2026, June 20) retrieved 20 June 2026 from https://medicalxpress.com/news/2026-06-dopamine-modulates-brain-circuits-behavioral.html This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.