A Novel Sensory Wave (P25) in Myelin Oligodendrocyte Glycoprotein-induced Experimental Autoimmune Encephalomyelitis Murine Model.

Myelin oligodendrocyte glycoprotein (MOG)-induced experimental autoimmune encephalomyelitis (EAE) is a murine model for multiple sclerosis. This model is characterized by chronic and progressive demyelination, leading to impairment of motor function and paralysis. While the outcomes of the disease, including impaired motor function and immunological changes, are well-characterized, little is known about the impact of EAE on the electrophysiology of the motor and sensory systems. In this study, we assessed evoked potentials as a quantitative marker for in vivo monitoring of nervous system damage. Motor-evoked potentials (MEPs) and sensory-evoked potentials (SEPs) were first standardized in naïve C57BL mice and studied thoroughly in EAE mice. The duration of MEPs and the number of connotative potentials increased significantly alongside an increase in temporal SEP amplitudes. Moreover, a new SEP wave was identified in naïve animals, which significantly increased in MOG-induced EAE animals with no or mild symptoms (clinical score 0-2, 0-5 scale). This wave occurred ∼25 milliseconds poststimulation, thus named p25. P25 was correlated with increased vocalization and was also reduced in amplitude following treatment with morphine. As the EAE score progressed (clinical score 3-4, 0-5 scale), the amplitude of MEPs and SEPs decreased drastically. Our results demonstrate that desynchronized neural motor activity, along with hypersensitivity in the early stages of EAE, leads to a complete loss of motor and sensory functions in the late stages of the disease. The findings also suggest an increase in p25 amplitude before motor deficits appear, indicating SEP as a predictive marker for disease progression. PERSPECTIVE: This article assesses p25, a new sensory electrophysiology wave that correlates with pain-related behavior in MOG-induced EAE mice and appears prior to the clinical symptoms. Motor electrophysiology correlates with traditional motor behavior scoring and histology.

An injectable oleogel-based bupivacaine formulation for prolonged non-opioid post-operative analgesia.

Opioid-based medications remain the mainstay of post-operative pain management, even though they are associated with a plethora of adverse effects including addiction, nausea, constipation, cognitive impairment, respiratory depression, and accidental death due to overdose. Local anesthetics are effective at controlling the intense pain after surgery but their short duration of effect limits their clinical utility in post-operative pain management. In this manuscript, an optimized injectable oleogel-based formulation of bupivacaine for multi-day post-operative pain management was characterized on the benchtop and assessed in two clinically-relevant porcine post-operative pain models. Benchtop characterization verified the optimized oleogel-based bupivacaine formulation design, demonstrating a homogenous stable oleogel with sufficient injectability due to shear-thinning properties, high drug loading capacity and first-order drug release kinetics over 5 days. In vivo assessment in two pig post-operative pain models demonstrated that the oleogel-based bupivacaine formulation can provide statistically significant multi-day analgesia in two routes of administration: local instillation directly into a surgical site and ultrasound-guided peripheral nerve block injection. Pharmacokinetic assessment of ALX005 found that Cmax values were not statistically different from the bupivacaine HCl control, with no clinical signs of local anesthetic systemic toxicity observed, when administering up to 2.7 and 8.1 times the control dose of bupivacaine HCl. This study demonstrates the pre-clinical safety and efficacy of an injectable oleogel-based bupivacaine formulation and explores its utility as a single-administration long-acting local anesthetic product for post-operative pain management that can be used in both local and regional anesthetic applications.