Adult-born dentate granule cell excitability depends on the interaction of neuron age, ontogenetic age and experience.

Early during their maturation, adult-born dentate granule cells (aDGCs) are particularly excitable, but eventually develop the electrophysiologically quiet properties of mature cells. However, the stability versus plasticity of this quiet state across time and experience remains unresolved. By birthdating two populations of aDGCs across different animal ages, we found for 10-month-old rats the expected reduction in excitability across cells aged 4-12 weeks, as determined by Egr1 immunoreactivity. Unexpectedly, cells 35 weeks old (after genesis at an animal age of 2 months) were as excitable as 4-week-old cells, in the dorsal hippocampus. This high level of excitability at maturity was specific for cells born in animals 2 months of age, as cells born later in life did not show this effect. Importantly, excitability states were not fixed once maturity was gained, but were enhanced by enriched environment exposure or LTP induction, indicating that any maturational decrease in excitability can be compensated by experience. These data reveal the importance of the animal's age for aDGC excitability, and emphasize their prolonged capability for plasticity during adulthood.

A chitosan/dextran-based hydrogel as a delivery vehicle of human bone-marrow derived mesenchymal stem cells.

A chitosan/dextran-based (CD) injectable, surgical hydrogel has been developed and shown to be an effective post-operative aid in prevention of scar tissue formation in vivo. The CD hydrogel's effectiveness in a surgical setting prompted an investigation into its capacity as a potential delivery vehicle for bone marrow derived mesenchymal stem cells (BM-MSCs) for regenerative wound healing applications. By housing BM-MSCs within a biocompatible, injectable, hydrogel matrix, viability and protection in cultivation, as well as direct delivery to the damaged site in the host tissue may be achieved. In vitro BM-MSC cell viability in the presence of CD hydrogel was determined by LIVE/DEAD® fluoresence staining. Flow cytometry studies revealed expression of a conventional BM-MSC surface marker profile. A colony forming cell assay showed a slight statistically significant decrease in the number of colonies grown in CD hydrogel as compared to control cells. In addition, BM-MSCs in the CD hydrogel were able to successfully differentiate into adipocytes and osteocytes. In summary, the CD hydrogel supports MSC growth and differentiation; and therefore, may be used as a potential stem cell delivery vehicle for regenerative medicine and tissue engineering applications.