Temporal assessment of behavior in Parkinson's visual hallucinations via a multidimensional analysis strategy
Summary
Visual hallucination (VH) is a common nonmotor symptom of Parkinson's disease (PD). However, the lack of reliable animal models and quantitative assessment tools poses significant challenges for mechanism and intervention research in this area. Here, we developed a novel PD-related visual hallucination (PDVH) model by administering benzhexol hydrochloride, which can induce hallucinatory phenotypes in PD model mice. On the basis of this model, we used a multidimensional behavioral analysis
Content
# Temporal assessment of behavior in Parkinson's visual hallucinations via a multidimensional analysis strategy
*Published: 2026 Apr 22*
Visual hallucination (VH) is a common nonmotor symptom of Parkinson's disease
(PD). However, the lack of reliable animal models and quantitative assessment
tools poses significant challenges for mechanism and intervention research in
this area. Here, we developed a novel PD-related visual hallucination (PDVH)
model by administering benzhexol hydrochloride, which can induce hallucinatory
phenotypes in PD model mice. On the basis of this model, we used a
multidimensional behavioral analysis framework to identify a
hallucination-related hunching state (HHS) that is strongly associated with
hallucinatory episodes. This state is characterized by a sustained hunching
posture accompanied by prolonged staring and embedded head twitching. By
constructing a spontaneous behavior transition map, we found that the emergence
of spontaneous behaviors is highly dependent on the immediately preceding state,
revealing that the core hallucinatory features are structured and predictable at
the level of spontaneous behavior. The relative fractions and transition
probabilities of staring and head twitching allow high-throughput identification
of PDVH mice and reflect temporal dynamics of the hallucination process. Our
findings demonstrate that this approach enables high spatiotemporal resolution
acquisition and analysis of behaviors associated with PDVH, offering a robust
experimental framework for investigating PDVH mechanisms at the circuit level
and developing targeted therapeutic strategies.
DOI: 10.1038/s41392-026-02651-2