Cosmic‐Ray Radiation Effects on Ibuprofen Tablet Formulation Inside and Outside of the International Space Station

This study examines the cosmic radiation stability of medicines for space missions. In the space-developed tablets, ibuprofen was formulated in a mixture of six “moon simulants” as excipients. The study was supported by two space experiments. Results show that ibuprofen decomposed when exposed to the harsh space environment. The findings confirm the importance of designing space-compatible medicines for long-term missions.

Abstract

In extreme environments people will have different needs for medicine(s), making it crucial to understand how such environments affect drug efficacy. Ibuprofen, commonly used in tablet formulation on Earth, could fail in space despite standard pharmaceutical packaging. We introduce the concept of ‘space medicines’, where solid-dosage forms protect the pharmaceutical from accelerated degradation in spaceflight. We simulate dose(s) in International Space Station (ISS) through radionuclide and photon experiments, and establish the impact of alpha, beta and gamma rays. We demonstrate that tablet formulation protects from impact of alpha and beta rays; however, gamma rays decompose ibuprofen even when ‘masked’. We systematically analyse 19 tablet compositions inside and outside the ISS to determine the effect of compositional changes in the tablet matrix. We confirm that the iron oxide-shielded tablets show minimal degradation (〈10%) inside the ISS, compared to moderate reductions (〉10%) for other formulations, with one exception. The tablets exhibited significantly greater ibuprofen degradation (〉 30-50%) outside ISS, due to harsh conditions. Significantly, we found that flavour have shielding potential by scavenging free radicals. We conclude that ibuprofen efficacy is adversely affected in space, and these effects are expected to worsen on missions to deeper space destinations.