Novel intranasal treatment for anxiety disorders using amiloride, an acid-sensing ion channel antagonist: Pharmacokinetic modeling and simulation.

OBJECTIVE: To develop a physiologically based pharmacokinetic (PBPK) model for amiloride, an acid-sensing ion channel (ASIC) antagonist, and to simulate its pharmacokinetics in plasma and the central nervous system following intranasal administration in a virtual human population. MATERIALS AND METHODS: We first developed a PBPK model of amiloride after oral administration and optimized the model using data from five clinical studies. Next, we added a nasal compartment to the amiloride oral PBPK model and parameterized using data from previous clinical studies. We simulated amiloride's pharmacokinetics in plasma, brain, and cerebrospinal fluid (CSF) after intranasal administration of amiloride at various doses in a virtual human population. RESULTS: The target amiloride concentration in the central nervous system required for maximal ASIC inhibition was achieved with a 75-mg intranasal amiloride dose. However, this finding is based on simulations performed using a mathematical model and needs to be further validated with appropriate clinical data. CONCLUSION: The nasal PBPK model of amiloride could be used to design future clinical studies and allow for successful clinical translation of intranasal amiloride formulation.

Acid Sensing Ion Channel 1a (ASIC1a) Mediates Activity-induced Pain by Modulation of Heteromeric ASIC Channel Kinetics.

Chronic muscle pain is acutely worsened by exercise. Acid sensing ion channels (ASIC) are heteromeric channels expressed in muscle sensory neurons that detect decreases in pH. We have previously shown ASIC3 is important in activity-induced hyperalgesia. However, ASICs form heteromers with ASIC1a being a key component in sensory neurons. Therefore, we studied the role of ASIC1a in mice using behavioral pharmacology and genetic deletion in a model of activity-induced hyperalgesia. We found ASIC1a-/- mice developed mechanical hyperalgesia similar to wild-type mice, but antagonism of ASIC1a, with psalmotoxin, prevented development of mechanical hyperalgesia in wild-type mice, but not in ASIC1a-/- mice. To explain this discrepancy, we then performed electrophysiology studies of ASICs and examined the effects of psalmotoxin on ASIC heteromers. We expressed ASIC1a, 2 and 3 heteromers or ASIC1 and 3 heteromers in CHO cells, and examined the effects of psalmotoxin on pH sensitivity. Psalmotoxin significantly altered the properties of ASIC hetomeric channels. Specifically, in ASIC1a/2/3 heteromers, psalmotoxin slowed the kinetics of desensitization, slowed the recovery from desensitization, and inhibited pH-dependent steady-state desensitization, but had no effect on pH-evoked current amplitudes. We found a different pattern in ASIC1a/3 heteromers. There was a significant leftward shift in the pH dose response of steady-state desensitization and decrease in pH-evoked current amplitudes. These results suggest that blockade of ASIC1a modulates the kinetics of heteromeric ASICs to prevent development of activity-induced hyperalgesia. These data suggest ASIC1a is a key subunit in heteromeric ASICs and may be a pharmacological target for treatment of musculoskeletal pain.