Identification of cerebrospinal fluid pharmacodynamic biomarkers and molecular correlates of brain activity in a Phase 2 clinical trial of the Alzheimer's disease drug candidate CT1812.

INTRODUCTION

CT1812 (zervimesine) is an orally dosed modulator of the sigma-2 receptor (S2R) currently in clinical development for the treatment of Alzheimer's disease (AD). CT1812 has been shown in preclinical and early clinical trials to selectively prevent and displace binding of amyloid beta oligomers from their synaptic receptors and has improved cognitive function in animal models of AD.

METHODS

SEQUEL (NCT04735536) is a completed Phase 2, randomized, placebo-controlled 4-week crossover trial in adults with mild-to-moderate AD that investigated the effect of CT1812 on safety, synaptic function using quantitative electroencephalography (qEEG), and biomarkers. CT1812 improved established qEEG markers of spontaneous brain activity, suggesting improved neuronal and synaptic function. In the present study, cerebrospinal fluid (CSF)-based tandem mass tag mass spectrometry (TMT-MS) was performed on participant samples to investigate proteomic effects and identify potential biomarkers of CT1812.

RESULTS

Biomarkers found through proteomics analyses to be significantly differentially abundant in CT1812- versus placebo-treated participants supported pathway engagement and proof of mechanism for CT1812. Impacted proteins support a role for CT1812 at synapses, in vesicle trafficking, and in lipoprotein biology. Biomarkers correlated with the previously reported improvements in qEEG-based functional connectivity (inferred through alpha band Amplitude Envelope Correlations) with CT1812 treatment were also identified and may be potential early surrogate biomarkers of efficacy for CT1812. The processes and functions supported by biomarkers were congruent with those previously revealed in CSF proteomics analyses from phase 1 and 2 AD clinical trials with CT1812.

DISCUSSION

After 1 month of treatment, the identification of biomarkers supporting pathway engagement, the replication of biomarker findings from prior trials, and the discovery of molecular correlates of improved functional connectivity with CT1812 treatment bolster support for and expound upon the mechanism of action for CT1812 in displacing Aβ oligomers at neuronal synapses, as well as underscores the CT1812 relevance to AD.

HIGHLIGHTS

Exploratory proteomics identified candidate CSF biomarkers of CT1812 in SEQUEL.Molecular correlates of functional brain connectivity (qEEG) were identified.Proteins impacted by 1 month CT1812 treatment support target engagement.Pharmacodynamic changes found in synapse, immune, vesicle, and lipoprotein biologies.SEQUEL proteomics findings replicated previous trial findings with CT1812.