Impact of Exogenous Ketones on Sleep Disruption in Vulnerable Populations (KETO-SLEEP 1)

Sleep is a vulnerable period during which blunted respiratory drive and low airway muscle tone can cause dangerous breathing disorders. Obstructive sleep apnea (OSA) describes the intermittent collapse of the upper airway that induces O2 desaturations and arousals from sleep, placing patients at risk for cardiovascular disease, stroke, and death. In some obese patients, sleep causes carbon dioxide (CO2) accumulation progressing to daytime hypercapnia, a condition called obesity hypoventilation syndrome (OHS). Continuous positive airway pressure (CPAP) treats OSA and OHS, but is poorly tolerated, and may not fully correct sleep dysfunction.

Changes in metabolism may help to control OSA or OHS. The investigators recently published results from the Ketogenic Diet for OHS clinical trial (KETOHS, NCT04108819) showing that a 2-week ketogenic diet (high fat, low carbohydrate) for patients with OSA and OHS lowered reduced CO2, serum bicarbonate (HCO3), respiratory quotient, nocturnal hypoxemia(2). KD also significantly improved OSA. After participants resumed their prior diet, CO2 returned to baseline. The mechanisms by which KD improves sleep in this population could be related to reduced CO2 production (through fat oxidation), lowering of body weight, or direct effects of ketone bodies on sleep and breathing.

It is difficult to adhere long-term to KD, and there are multiple effects of this diet that make it challenging to understand mechanistic impacts on respiration. The investigators hypothesize that increasing ketone levels in the body, without having to adhere to a ketogenic diet, may be another method to improve breathing during sleep. Indeed, some drugs affecting acid-base status (e.g. acetazolamide or sulthiame) improve OSA, presumably through increasing and stabilizing respiratory drive. In this pilot study, the investigators will examine the pharmacokinetics, tolerability, and impacts of ingesting exogenous ketones (which are commercially available products) on sleep and breathing.

The specific ketone product to be tested for its impact on sleep and breathing is 1,3 butanediol (1,3BD) in a commercially available formulation called "Ketone IQ". 1,3BD is generally recognized as safe (GRAS approved) by the FDA. 1,3BD is converted by liver metabolism into the ketone body beta-hydroxybutyrate (BHB) and has been utilized in multiple studies.

This project will be conducted in two studies, KETO-SLEEP 1 (KS1), and KETO-SLEEP 2 (KS2).

KETO-SLEEP 1: Examine the pharmacokinetics, tolerability, and sleep impacts of ingesting exogenous ketones (EK) before sleep (n=20, 10 men, 10 women). KS1 will lay the foundation for KS2 and other studies that administer exogenous ketones at bedtime, through dose-finding and assessment of tolerability. Patients with moderate-severe OSA (apnea-hypopnea index (AHI) >15)) adherent to CPAP will ingest EK or placebo 30 minutes before sleep. They will measure capillary BHB levels before ingestion and at 1, 3, 5, hours post-ingestion as well as upon awakening. CPAP use will be maintained on all nights and sleep architecture will be monitored with portable EEG. Questionnaires will solicit feedback about EK palatability, GI side effects, and sleep quality. Two doses (20 g and 40 g) of Ketone-IQ will be tested each for two nights, with one night used to measure BHB levels and separate night to allow for uninterrupted sleep.

[KETO-SLEEP 2: Examine the preliminary efficacy of ingesting exogenous ketones before sleep on OSA (n=20, 10 men, 10 women). KS2 will examine the respiratory effects of exogenous ketones taken before sleep. Patients with known OSA will be asked to temporarily discontinue CPAP, a technique used in our laboratory to temporarily elicit OSA(10). To account for night-to-night variability in OSA severity the investigators will use portable sleep monitoring to collect sleep and respiratory data two nights under each condition. The dose of Ketone-IQ to be administered each night will vary from 20 to 40 g, depending upon results of KS-1.