Cancer neuroscience: signaling pathways and new therapeutic strategies for cancer
Summary
From a neuroscience perspective, cancer neuroscience has emerged as a subfield of cancer research. Presumable mechanisms underlying cancer-related neuronal activity (termed neurosciences) include the induction and modulation of signaling pathways that govern cell fate determination and emotional responses (anxiety and stress), such as structural molecules (synaptic structures and current transduction) and secretory substances (neurotransmitters, cytokines, hormones and neuropeptides). In t
Content
# Cancer neuroscience: signaling pathways and new therapeutic strategies for cancer
*Published: 2026 Feb 23*
From a neuroscience perspective, cancer neuroscience has emerged as a subfield
of cancer research. Presumable mechanisms underlying cancer-related neuronal
activity (termed neurosciences) include the induction and modulation of
signaling pathways that govern cell fate determination and emotional responses
(anxiety and stress), such as structural molecules (synaptic structures and
current transduction) and secretory substances (neurotransmitters, cytokines,
hormones and neuropeptides). In the past 3 years, these neuronal activities,
which can either promote cancer growth or be hijacked by cancer cells to support
tumor survival and invasion, have been widely demonstrated to be closely related
to cancer progression. The molecular mechanisms are also being refined. Despite
their great promise, translating neuroscientific discoveries into clinically
actionable strategies for cancer diagnosis, prognosis, and treatment remains a
formidable task. In this comprehensive review, we attempt to provide a full
account of the intersection between neuroscience and cancer research. From the
perspective of cancer neuroscience, we fully discuss the potential signaling
molecules and their regulatory mechanisms, as well as targets and emerging
therapeutic strategies that control tumor progression via multiomics approaches.
Overall, cancer neuroscience may have unprecedented potential for understanding
neuronal functions and cancer development, ultimately offering the significantly
improved cancer treatment.
DOI: 10.1038/s41392-025-02364-y