A Novel Agnostic Respiratory Stimulant as a Treatment for Apnea of Prematurity: A Proof-of-Concept Study.

AIM/OBJECTIVE: ENA-001 is a novel selective antagonist of large-conductance BK (big potassium) channels located in the carotid bodies, where they act as chemoreceptors that sense low arterial oxygen levels and establish a feedback loop to brainstem nuclei responsible for initiating spontaneous breathing and maintaining adequate oxygen to tissues. ENA-001 attenuates respiratory depression induced by a variety of chemical agents, essentially "agnostic" to the precipitating drug (e.g., opioid(s), benzodiazepine, alcohol, or propofol). But it had not been tested against respiratory depression resulting from a physiological cause, such as apnea of prematurity (AOP). This proof-of-principle study used a well-described animal model (premature lamb) to test the effectiveness of ENA-001 in the setting of an under-developed respiratory control system, similar to that in human AOP.

MATERIALS AND METHODS

A set of twin lambs was delivered prematurely via caesarian section at 135 ± 2 d gestational age (GA). An arterial catheter was connected to a transducer for pressure monitoring and a venous catheter was connected to a pump for continuous infusion of 5% dextrose in water (D5W). Lambs were to receive four mechanical breaths for lung recruitment and then started on continuous positive airway pressure (CPAP). After a stabilization period of 15 minutes, the protocol called for the first lamb to be started on continuous infusion of ENA-001, with ascending dose hourly (0.4, 1.1, 2.0, 12.0 mg/kg/hr), while the second lamb was to serve as a sham (D5W) control. At least 10 representative breaths free of artifact from motion or atypical breaths were recorded using a pulmonary function system designed for neonatal research. To maintain a stable plane of anesthesia, repeat doses of fentanyl (1 µg IM) were given as needed based on blood pressure response to stimulation.

RESULTS

Two male lambs were delivered. Unexpectedly, neither lamb exhibited a drive for spontaneous breathing. Each required manual ventilation, with a complete absence of spontaneous effort. Despite the poor prognosis owing to the absence of ventilatory effort, continuous infusion of the first dose of ENA-001 was started 20 minutes after birth. The test animal continued to require manual ventilation, which was continued for an additional 10 minutes. An intravenous (IV) bolus of ENA-001 was given. Nearly instantaneously following the delivery of the IV bolus, the lamb began breathing spontaneously and did not require manual intervention for the remainder of the study. The sham animal was delivered approximately an hour following the test animal. As with the test animal, the sham animal lacked spontaneous breathing efforts. A decision was made to manually ventilate for 30 minutes to match the course for the test animal. At the 30-minute time point, an IV bolus infusion of ENA-001 was delivered. Nearly instantaneously following the delivery of the IV bolus, the lamb began breathing spontaneously. After several minutes, the spontaneous breathing efforts abated, and manual ventilation was resumed. The animal was then sacrificed for tissue harvest.

CONCLUSION

These results suggest that ENA-001 might be an effective therapy, alone or as a co-medication, for the treatment of AOP. They further suggest that ENA-001 might have broader applications in situations of neurological ventilatory insufficiency.