Characterisation of Sr 2+ mobility in osteoporotic rat bone marrow by cryo-ToF-SIMS and cryo-OrbiSIMS.
Christine KernReem JamousThaqif El KhassawnaMarcus RohnkePublished in: The Analyst (2022)
Strontium (Sr 2+ ) ions are an effective therapeutic agent for the healing of osteoporotic bone fractures and are therefore used, for example, in form of strontium-modified bone cements. In order to reduce animal testing in further implant materials development in the future, a simulation of the Sr 2+ release and transport in bone would be helpful. For such a simulation, knowledge of the experimental parameters for Sr 2+ mobility in different compartments of bone (mineralised bone, bone marrow) is essential. In a previous study, we developed an experimental protocol for transport studies in bovine bone marrow by time-of-flight secondary ion mass spectrometry (ToF-SIMS). In the current proof-of-concept study, we investigated Sr 2+ diffusion for the first time in bone marrow of rat bone sections. Additionally, orbitrap secondary ion mass spectrometry (OrbiSIMS) was applied for unambiguous signal identification of lipids and fatty acid species in rat bone marrow. Detailed 2D and 3D mass spectrometric imaging analyses, depth profiling as well as OrbiSIMS spectrometric analysis revealed faster Sr 2+ diffusion in rat bone marrow areas with low intensity of lipid and fatty acid signals than in areas with higher lipid/fatty acid content. These results could be confirmed by histological staining and additional analysis of Sr 2+ diffusion into pure fat sections.
Keyphrases
- bone marrow
- fatty acid
- mass spectrometry
- bone mineral density
- mesenchymal stem cells
- high resolution
- soft tissue
- liquid chromatography
- postmenopausal women
- oxidative stress
- bone loss
- bone regeneration
- adipose tissue
- high performance liquid chromatography
- body composition
- gas chromatography
- randomized controlled trial
- healthcare
- ms ms
- optical coherence tomography
- current status
- tandem mass spectrometry
- photodynamic therapy
- single molecule