Pharmaceutics, Vol. 17, Pages 1112: Neurotoxicological Evaluation of Intrathecal Citrate Excipients: Calcium Homeostasis Disruption and Safety Implications in CNS Drug Delivery

Pharmaceutics doi: 10.3390/pharmaceutics17091112

Authors:
Jue Wang
Yuan Zhang
Qing He
Ying Du
Xia Zhang
Xinru Tan
Xinting Zhou
Susu Tang
Baoming Ning
Rui Yang
Xia Zhao
Dejiang Tan
Huimin Sun
Jiasheng Tu

Background/Objectives: Intrathecal drug delivery is essential for treating CNS disorders, but the safety of commonly used excipients such as citric acid/sodium citrate (SC) remains unclear. This study aims to systematically evaluate the potential neuropharmacological effects of repeated intrathecal SC administration. Methods: Multimodal approaches were applied across murine and lagomorph models. Doses ranged from 1.833–14.664 μg/g in mice and 0.104–3.290 mg/rabbit. Behavioral, neurophysiological, and fiber photometry analyses were conducted to assess sensorimotor function, cortical activity, and calcium dynamics. Results: SC induced dose-dependent sensorimotor deficits, including hypolocomotion (45.7% reduced distance, p < 0.001) and impaired coordination (latency reduction 48.3–64.1%, p < 0.001). Mortality increased with dosage and repeated exposure. Neurophysiological data revealed biphasic cortical modulation: acute c-Fos suppression followed by delayed hyperactivity. Fiber photometry confirmed calcium chelation-mediated attenuation and subsequent potentiation of Ca2+ signals. Rabbits exhibited similar neurological symptoms, correlating with transient CSF calcium/magnesium depletion, though no structural neural damage was observed. Conclusions: These results provide the first comprehensive evidence that SC buffers can significantly disrupt neuronal calcium homeostasis and induce functional impairments upon intrathecal delivery. The findings emphasize the need for reassessing excipient safety in CNS-targeted formulations.

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Jue Wang www.mdpi.com