Summary: Researchers have developed D-PSCAN, a novel imaging technique that enables high-resolution, minimally invasive observation of the brainstem’s nucleus tractus solitarii (NTS) in living animals. The NTS, a vital relay for signals from organs via the vagus nerve, plays a key role in emotion regulation and overall mental health.
Using D-PSCAN, scientists visualized how the NTS responds to vagus nerve stimulation and natural signals like the gut hormone cholecystokinin. This breakthrough could help optimize treatments like vagus nerve stimulation for depression and broaden our understanding of brain-body interactions.
Key Facts:
- New Deep-Brain Imaging: D-PSCAN enables minimally invasive, high-resolution imaging of the NTS in living animals.
- Brain-Body Communication: The NTS integrates organ signals and plays a vital role in emotion regulation and mental health.
- Therapeutic Potential: Findings could optimize vagus nerve stimulation and inform treatments for neuropsychiatric disorders.
Source: NINS
The communication between the brain and bodily organs is fundamental to emotion regulation and overall mental health.
The nucleus tractus solitarii (NTS) in the brainstem is a critical hub structure mediating this interaction via the vagus nerve. Despite its importance, the NTS’s deep location has historically posed challenges for observation in living animals.
In a study recently published in Cell Reports Methods (April 4, 2025), the research team has developed the live NTS imaging method (named “D-PSCAN”, or Double-Prism-based brainStem imaging under Cerebellar Architecture and Neural circuits).
This novel deep-brain imaging technique enables high-resolution, minimally invasive visualization of the NTS neural activity in living mice.
New Minimally Invasive Technique Unveiled.
The D-PSCAN method is based on the double microprism assembly carefully and systematically implanted between the cerebellum and brainstem, preserving cerebellar function while providing a broad and detailed view of the NTS.
“One major challenge in studying the NTS is its deep location beneath the cerebellum, which has made observation in living animals difficult.” explains lead author Masakazu Agetsuma.
“Previously, some approaches involved removing the cerebellum to access the NTS, but this posed a major limitation: the cerebellum, major motor coordination center, has also been recognized as important for emotional regulation. Therefore, a method to observe the NTS while preserving cerebellar function has been needed.”
Detailed activity of the NTS can now be observed.
The research team evaluated the D-PSCAN method by investigating the NTS’s response to the electrical stimulation of the vagus nerve, which conveys signals from internal organs to the NTS.
They observed the specific thresholds of vagus nerve stimulation (VNS) intensity required to elicit neural responses in the NTS.
They also observed that varying stimulation parameters causes distinct patterns of neural activation, including sensitization or, conversely, inhibitory effects.
Vagus nerve stimulation (VNS) has been clinically used for drug-resistant epilepsy and is currently under investigation as a treatment for depression and other psychiatric and neurological disorders.
Therefore, these results highlight the potential of the D-PSCAN method for gaining valuable insights into optimizing VNS parameters for therapeutic applications.
To further investigate NTS function under more physiological conditions than electrical stimulation, the research team applied the D-PSCAN method to examine its response to the gut hormone cholecystokinin, which is naturally released after feeding.
As a result, they successfully detected NTS neural activity evoked by cholecystokinin.
Future prospects
“The brain-body interaction plays a critical role in emotion regulation, and gaining a deeper understanding of this function is expected to contribute both to the treatment of neuropsychiatric disorders and to the advancement of mental health and well-being.” says Agetsuma.
“The D-PSCAN can offer a new approach to elucidate brain–body–mind interactions, and represents a valuable research tool for basic neuroscience to clinical applications.”
The implications of this research extend beyond the study of emotion regulation. The NTS receives input from various organs, including the heart and gut, and is involved in diverse functions such as appetite regulation, energy metabolism, and gut microbiota.
The in vivo NTS imaging technique developed in this study, D-PSCAN, is expected to be widely applied across these research areas.
About this neuroscience research news
Author: Hayao KIMURA
Source: NINS
Contact: Hayao KIMURA – NINS
Image: The image is credited to Neuroscience News
Original Research: Open access.
“Minimally invasive, wide-field two-photon imaging of the brainstem at cellular resolution” by Masakazu Agetsuma et al. Cell Reports Methods
Abstract
Minimally invasive, wide-field two-photon imaging of the brainstem at cellular resolution
The nucleus tractus solitarii (NTS), a brainstem structure, is proposed as a critical gateway for regulating emotions through brain-viscera communication and for therapies based on vagus nerve stimulation (VNS). However, how the NTS processes signals from various organs remains unclear.
Investigating this has been challenging due to the NTS’s deep location beneath the cerebellum and its being surrounded by brainstem regions critical to vital functions, which makes direct observation difficult.
To address this issue, we developed an in vivo two-photon imaging method using a double-prism-based optical interface, allowing minimally invasive observation while keeping the surrounding regions mostly intact.
