Research on solute transport behaviors in the lacunar-canalicular system using numerical simulation in microgravity

Abstract

BackgroundThe lack of mass transfer in microgravity might be the underlying cause of disuse osteoporosis in astronauts after long-term space flights. The osteons are cylindrical structures and are the main structural units of the diaphysis in long bones. MethodsA multi-scale 3D fluid-solid coupled finite element model of osteon with a two-stage pore structure was developed using COMSOL software in order to investigate solute transport behaviors in the lacunar-canalicular system (LCS) induced by physiological strain loading. Certain small molecules that are necessary as solutes in tissue fluid for osteocyte metabolism were simplified to micro-particles. A comparative analysis of solute transport behaviors in the LCS induced by physiological strain loading was conducted with a frequency of 0.2–2.5 Hz in microgravity and the Earth's gravitational fields. ResultsThe average velocity of solute transport in lacunae in microgravity was 2–3 orders of magnitude lower than in Earth's gravitational field. The number of particles that represented solute transport quantity in the middle and deep lacunae increased steadily with a load frequency within the Earth's gravitational field. However, it differed based on the load frequency in microgravity, with the number of particles increasing with frequencies in the range of 0.2–0.5 Hz and 0.8–2 Hz, and decreasing with frequencies in the range of 0.5–0.8 Hz. ConclusionsA moving load with appropriate frequency could promote solute transport to the middle and deep lacunae, effectively preventing apoptosis of deep osteocytes due to a lack of nutrients. The results of this study provided theoretical guidance for preventing bone loss in astronauts during long-term space flights.