Controlled Hydrogen Sulfide Delivery to Enhance Cell Survival in Bone Tissue Engineering

ABSTRACT

The increased local concentration of calcium ions (Ca²⁺) and phosphate (P_i), a natural body process for bone healing and remodeling, as well as local delivery of these ions as signaling molecules by synthetic bone graft substitutes, may lead to cytotoxic ion levels that can result in Ca²⁺/ P_i mitochondria overload, oxidative stress, and cell death. In this research, the effect of H₂S as a cytoprotective signaling molecule to increase the tolerance of mesenchymal stem cells (MSCs) in the presence of cytotoxic level of Ca²⁺/P_i was evaluated. Different concentrations of sodium hydrogen sulfide (NaSH), a fast-releasing H₂S donor, were exposed to cells in order to evaluate the influence of H₂S on MSC proliferation. The results suggested that a range of NaSH (i.e., 0.25 - 4 mM NaSH) was non-cytotoxic and could improve cell proliferation and differentiation in the presence of cytotoxic levels of Ca²⁺ (32 mM) and/or P_i (16 mM). To controllably deliver H₂S over time, a novel donor molecule in thioglutamic acid (GluSH) was synthesized and evaluated for its H₂S release profile. Excitingly, GluSH successfully maintained cytoprotective level of H₂S over 7 days. Furthermore, MSCs exposed to cytotoxic Ca²⁺/P_i concentrations in the presence of GluSH were able to thrive and differentiate into osteoblasts. These findings suggest that the incorporation of a sustained H₂S donor such as GluSH into CaP-based bone substitutes can facilitate considerable cytoprotection making it an attractive option for complex bone regenerative engineering applications.