The Role of Orexin in Human Panic Disorder

Orexins

Hypocretins (orexins), a more recently identified class of pro-arousal neuropeptides, are synthesized by neurons in the lateral and posterior hypothalamus The main described orexins, orexin A (ORX A) and orexin B (ORX B), are both cleaved from a common precursor peptide, prepro-orexin. Orexin A, a 33 amino-acid residue peptide, appears to be conserved across many mammalian species. Orexin B contains 28 amino acids. Orexins promote a variety of behaviors including alertness, vigilance, locomotion, fight-flight responses, and feeding. The physiological effects of the orexins are mediated via 2 G-protein coupled receptors, ORX1 and ORX2. Orexin A binds with greater affinity to the ORX1 receptor, while orexin A and B bind with similar affinity to the ORX2 receptor.

Orexins and Animal Fear Models

Orexins have been implicated in anxiogenesis in some animal fear models. For example, central (icv) injection of orexin A in mice induced anxiety-like responses in the light-dark exploration test and elevated plus maze.

Using an established, γ-aminobutyric acid (GABA)-deficit, rodent model of panic-vulnerability, the investigators' Indiana University preclinical anxiety collaborators provoked a panic-like response in rodents with an anxiogenic sodium lactate (NaLac) infusion, which response was blunted following either site-specific orexin (ORX) gene silencing or systemic pretreatment with an ORX1 antagonist.

In addition, ORX neurons (peptidergic neurons in the lateral hypothalamus) were shown, in turn, to stimulate discrete efferent sites within an emotional network (e.g., bed nucleus of the stria terminalis) to elicit specific behavioral components of the panic-response following sodium lactate. Taken together, these results support the concept that ORX hypersecretion or ORX neuronal overactivity could also be present in human panic disorder (PD).

Orexins' Emerging Role in Human Anxiogenesis / Panicogenesis

Similar to the NaLac model animals, humans with PD have been reported to have cortical and subcortical GABA deficits. If these GABA deficits also extend to impairment of GABAergic inhibition of dorsomedial hypothalamus (DMH) ORX neurons in PD patients, as predicted by the NaLac animal model, they may result in ORX hypersecretion, increased sympathetic activation, and panicogenesis.

There have been few clinical studies of ORX metabolism or function in human anxiety populations. However, recently generated human pilot data in the principal investigator's (PI's) lab, studying the effects of a well-documented anxiogenic stimulus (35% CO2 inhalation) on behavioral, physiological, and biochemical (plasma ORX A; assayed by a standard radioimmunoassays [RIA] kit) measures, in 1 PD patient and 2 healthy volunteers. In this paradigm, the PD patient had a mild panic episode associated with marked early elevations in plasma ORX levels, relative to the volunteers who had minimal anxiety, consistent with a role for ORX in the initiation or elaboration of the human panic response.

It was also demonstrated that, in contrast to human subjects without any axis I psychiatric disorder or with depression alone without panic, only subjects who had high panic scores but no depression had significantly elevated ORX levels in the cerebrospinal fluid (CSF).

The ORX hyperactivity hypothesis of panic that has been evinced from this work is highly innovative, and promises to broaden the understanding of the neurobiology of human panic disorder, as well as provide new treatment directions.

While there are limitations with using plasma ORX A as a measure of central nervous system (CNS) ORX function, one research group has recently published human data indicating that resting state CSF and plasma ORX A levels are highly correlated.

Accordingly, the central hypothesis of this translational human pilot project, and a more definitive project based on it, is as follows: PD is a human anxiety disorder associated with specific cortical and subcortical GABA deficits that result in disruption of normal inhibitory regulation of pro-arousal ORX neurons. This disruption promotes excessive ORX release, sympathetic activation, and vulnerability to spontaneous or chemically induced panic. Pretreatment with an ORX1 receptor antagonist prior to chemical challenge is therefore expected to block the evoked panic response.

Rationale for the Use of CO2 Inhalation

The 35% CO2 challenge is well documented in the literature as being reliable, safe, and easy to administer. The procedure has acceptable test-retest reliability, and may be used to monitor improvement in clinical status following the administration of antipanic medications.

Approximately 70% of PD patients will have a panic attack in response to this challenge, which closely resembles a real-life panic. Therefore, in addition to resting/baseline measurement of plasma ORX A, CO2-evoked levels of plasma ORX A in PD patients will also be examined, and these responses will be correlated with other behavioral and physiological parameters recorded during the CO2 test. The PI has had considerable experience using PD challenge paradigms in clinical research contexts, and he is very familiar with the application of the 35% CO2 challenge.

Project Aims and Expected Results

The project is a study that gathers pilot data relating to the role of orexin in human panic disorder. The effect sizes generated from this pilot work will permit planning and powering of a larger-scale study. It is anticipated that the study will be completed over the course of one year.

Specific Aim 1 will be to provide a preliminary demonstration that acute administration of the first-in-class, FDA-approved insomnia agent, suvorexant, a mixed ORX1/2 receptor antagonist, will block 35% CO2-induced panic symptoms in PD patients, via amelioration of central ORX neuronal hyperactivity (as reflected in blunted plasma ORX responses to CO2 challenge).

To address Specific Aim 1, a prospective, parallel-group, repeated-measures design will be used to compare behavioral, physiological, and biochemical (plasma ORX) responses in 2 independent, unmedicated groups of PD outpatients (n=6 in each group) at baseline/resting state and after panic provocation due to brief (1 minute) inhalation of a 35% CO2 / 65% O2 gas mixture. PD patients will be randomized, in a double-blind manner, to receive either a single, oral dose of the mixed ORX1/2 receptor antagonist, suvorexant (10 mg dose), or identical placebo, 120 minutes before CO2 challenge.

Expected results: It is expected that, compared to placebo, suvorexant pretreatment will blunt behavioral, physiological, and biochemical (plasma ORX) responses to 35% CO2 in PD, due to suppression of CNS ORX hyperactivity. The effect sizes generated from the pilot work will permit planning and powering of a larger-scale study, to definitively address Specific Aim 1.